[Title 40 CFR ]
[Code of Federal Regulations (annual edition) - July 1, 2006 Edition]
[From the U.S. Government Printing Office]
[[Page i]]
40
Part 63 (Sec. Sec. 63.1440 to 63.6175)
Revised as of July 1, 2006
Protection of Environment
________________________
Containing a codification of documents of general
applicability and future effect
As of July 1, 2006
With Ancillaries
Published by
Office of the Federal Register
National Archives and Records
Administration
A Special Edition of the Federal Register
[[Page ii]]
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[[Page iii]]
Table of Contents
Page
Explanation................................................. v
Title 40:
Chapter I--Environmental Protection Agency
(Continued) 3
Finding Aids:
Material Approved for Incorporation by Reference........ 1061
Table of CFR Titles and Chapters........................ 1065
Alphabetical List of Agencies Appearing in the CFR...... 1083
List of CFR Sections Affected........................... 1093
[[Page iv]]
----------------------------
Cite this Code: CFR
To cite the regulations in
this volume use title,
part and section number.
Thus, 40 CFR 63.1440
refers to title 40, part
63, section 1440.
----------------------------
[[Page v]]
EXPLANATION
The Code of Federal Regulations is a codification of the general and
permanent rules published in the Federal Register by the Executive
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Each volume of the Code is revised at least once each calendar year
and issued on a quarterly basis approximately as follows:
Title 1 through Title 16.................................as of January 1
Title 17 through Title 27..................................as of April 1
Title 28 through Title 41...................................as of July 1
Title 42 through Title 50................................as of October 1
The appropriate revision date is printed on the cover of each
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[[Page vi]]
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(b) The matter incorporated is in fact available to the extent
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(c) The incorporating document is drafted and submitted for
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Properly approved incorporations by reference in this volume are
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What if the material incorporated by reference cannot be found? If
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[[Page vii]]
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Director,
Office of the Federal Register.
July 1, 2006.
[[Page ix]]
THIS TITLE
Title 40--Protection of Environment is composed of thirty-one
volumes. The parts in these volumes are arranged in the following order:
parts 1-49, parts 50-51, part 52 (52.01-52.1018), part 52 (52.1019-End),
parts 53-59, part 60 (60.1-End), part 60 (Appendices), parts 61-62, part
63 (63.1-63.599), part 63 (63.600-63.1199), part 63 (63.1200-63.1439),
part 63 (63.1440-63.6175), part 63 (63.6580-63.8830), part 63 (63.8980-
End) parts 64-71, parts 72-80, parts 81-85, part 86 (86.1-86.599-99)
part 86 (86.600-1-End), parts 87-99, parts 100-135, parts 136-149, parts
150-189, parts 190-259, parts 260-265, parts 266-299, parts 300-399,
parts 400-424, parts 425-699, parts 700-789, and part 790 to End. The
contents of these volumes represent all current regulations codified
under this title of the CFR as of July 1, 2006.
Chapter I--Environmental Protection Agency appears in all thirty-one
volumes. An alphabetical Listing of Pesticide Chemicals Index appears in
parts 150-189. Regulations issued by the Council on Environmental
Quality appear in the volume containing part 790 to End. The OMB control
numbers for title 40 appear in Sec. 9.1 of this chapter.
For this volume, Robert J. Sheehan was Chief Editor. The Code of
Federal Regulations publication program is under the direction of
Frances D. McDonald, assisted by Alomha S. Morris.
[[Page 1]]
TITLE 40--PROTECTION OF ENVIRONMENT
(This book contains part 63)
--------------------------------------------------------------------
Part
chapter i--Environmental Protection Agency (Continued)...... 63
[[Page 3]]
CHAPTER I--ENVIRONMENTAL PROTECTION AGENCY (CONTINUED)
--------------------------------------------------------------------
Editorial Note: Nomenclature changes to chapter I appear at 65 FR
47324, 47325, Aug. 2, 2000.
SUBCHAPTER C--AIR PROGRAMS (CONTINUED)
Part Page
63 National emission standards for hazardous
air pollutants for source categories.... 5
[[Page 5]]
SUBCHAPTER C_AIR PROGRAMS (CONTINUED)
PART 63_NATIONAL EMISSION STANDARDS FOR HAZARDOUS AIR POLLUTANTS FOR
SOURCE CATEGORIES--Table of Contents
Subpart QQQ_National Emission Standards for Hazardous Air Pollutants for
Primary Copper Smelting
What This Subpart Covers
Sec.
63.1440 What is the purpose of this subpart?
63.1441 Am I subject to this subpart?
63.1442 What parts of my plant does this subpart cover?
63.1443 When do I have to comply with this subpart?
Emission Limitations and Work Practice Standards
63.1444 What emissions limitations and work practice standards must I
meet for my copper concentrate dryers, smelting furnaces, slag
cleaning vessels, and copper converter departments?
63.1445 What work practice standards must I meet for my fugitive dust
sources?
63.1446 What alternative emission limitation may I meet for my combined
gas streams?
Operation and Maintenance Requirements
63.1447 What are my operation and maintenance requirements?
General Compliance Requirements
63.1448 What are my general requirements for complying with this
subpart?
Initial Compliance Requirements
63.1449 By what date must I conduct performance tests or other initial
compliance demonstrations?
63.1450 What test methods and other procedures must I use to demonstrate
initial compliance with the emission limitations?
63.1451 How do I demonstrate initial compliance with the emission
limitations, work practice standards, and operation and
maintenance requirements that apply to me?
Continuous Compliance Requirements
63.1452 What are my monitoring requirements?
63.1453 How do I demonstrate continuous compliance with the emission
limitations, work practice standards, and operations and
maintenance requirements that apply to me?
Notifications, Reports and Records
63.1454 What notifications must I submit and when?
63.1455 What reports must I submit and when?
63.1456 What records must I keep and how long must I keep my records?
Other Requirements and Information
63.1457 What part of the General Provisions apply to me?
63.1458 Who implements and enforces this subpart?
63.1459 What definitions apply to this subpart?
Table 1 to Subpart QQQ of Part 63--Applicability of General Provisions
to Subpart QQQ.
Figure 1 to Subpart QQQ of Part 63--Data Summary Sheet for Determination
of Average Opacity.
Subpart RRR_National Emission Standards for Hazardous Air Pollutants for
Secondary Aluminum Production
General
63.1500 Applicability.
63.1501 Dates.
63.1502 Incorporation by reference.
63.1503 Definitions.
63.1504 [Reserved]
Emission Standards and Operating Requirements
63.1505 Emission standards for affected sources and emission nits.
63.1506 Operating requirements.
63.1507-63.1509 [Reserved]
Monitoring and Compliance Provisions
63.1510 Monitoring requirements.
63.1511 Performance test/compliance demonstration general requirements.
63.1512 Performance test/compliance demonstration requirements and
procedures.
63.1513 Equations for determining compliance.
63.1514 [Reserved]
Notifications, Reports, And Records
63.1515 Notifications.
63.1516 Reports.
63.1517 Records.
Other
63.1518 Applicability of general provisions.
63.1519 Implementation and enforcement.
[[Page 6]]
63.1520 [Reserved]
Table 1 to Subpart RRR of Part 63--Emission Standards for New and
Existing Affected Sources
Table 2 to Subpart RRR of Part 63--Summary of Operating Requirements for
New and Existing Affected Sources and Emission Units
Table 3 to Subpart RRR of Part 63mdash;Summary of Monitoring
Requirements for New and Existing Affected Sources and
Emission Units
Appendix A to Subpart RRR of Part 63--General Provisions Applicability
to Subpart RRR
Subpart SSS [Reserved]
Subpart TTT_National Emission Standards for Hazardous Air Pollutants for
Primary Lead Smelting
63.1541 Applicability.
63.1542 Definitions.
63.1543 Standards for process and process fugitive sources.
63.1544 Standards for fugitive dust sources.
63.1545 Compliance dates.
63.1546 Test methods.
63.1547 Monitoring requirements.
63.1548 Notification requirements.
63.1549 Recordkeeping and reporting requirements.
63.1550 Implementation and enforcement.
Subpart UUU_National Emission Standards for Hazardous Air Pollutants for
Petroleum Refineries: Catalytic Cracking Units, Catalytic Reforming
Units, and Sulfur Recovery Units
What This Subpart Covers
63.1560 What is the purpose of this subpart?
63.1561 Am I subject to this subpart?
63.1562 What parts of my plant are covered by this subpart?
63.1563 When do I have to comply with this subpart?
Catalytic Cracking Units, Catalytic Reforming Units, Sulfur Recovery
Units, and Bypass Lines
63.1564 What are my requirements for metal HAP emissions from catalytic
cracking units?
63.1565 What are my requirements for organic HAP emissions from
catalytic cracking units?
63.1566 What are my requirements for organic HAP emissions from
catalytic reforming units?
63.1567 What are my requirements for inorganic HAP emissions from
catalytic reforming units?
63.1568 What are my requirements for HAP emissions from sulfur recovery
units?
63.1569 What are my requirements for HAP emissions from bypass lines?
General Compliance Requirements
63.1570 What are my general requirements for complying with this
subpart?
63.1571 How and when must I conduct a performance test or other initial
compliance demonstration?
63.1572 What are my monitoring installation, operation, and maintenance
requirements?
63.1573 What are my monitoring alternatives?
Notifications, Reports, and Records
63.1574 What notifications must I submit and when?
63.1575 What reports must I submit and when?
63.1576 What records must I keep, in what form, and for how long?
Other Requirements and Information
63.1577 What parts of the General Provisions apply to me?
63.1578 Who implements and enforces this subpart?
63.1579 What definitions apply to this subpart?
Table 1 to Subpart UUU of Part 63--Metal HAP Emission Limits for
Catalytic Cracking Units
Table 2 to Subpart UUU of Part 63--Operating Limits for Metal HAP
Emissions from Catalytic Cracking Units
Table 3 to Subpart UUU of Part 63--Continuous Monitoring Systems for
Metal HAP Emissions from Catalytic Cracking Units
Table 4 to Subpart UUU of Part 63--Requirements for Performance Tests
for Metal HAP Emissions from Catalytic Cracking Units Not
Subject to the New Source Performance Standard (NSPS) for
Particulate Matter (PM)
Table 5 to Subpart UUU of Part 63--Initial Compliance with Metal HAP
Emission Limits for Catalytic Cracking Units
Table 6 to Subpart UUU of Part 63--Continuous Compliance with Metal HAP
Emission Limits for Catalytic Cracking Units
Table 7 to Subpart UUU of Part 63--Continuous Compliance with Operating
Limits for Metal HAP Emissions from Catalytic Cracking Units
Table 8 to Subpart UUU of Part 63--Organic HAP Emission Limits for
Catalytic Cracking Units
Table 9 to Subpart UUU of Part 63--Operating Limits for Organic HAP
Emissions from Catalytic Cracking Units
[[Page 7]]
Table 10 to Subpart UUU of Part 63--Continuous Monitoring Systems for
Organic HAP Emissions from Catalytic Cracking Units
Table 11 to Subpart UUU of Part 63--Requirements for Performance Tests
for Organic HAP Emissions from Catalytic Cracking Units Not
Subject to the New Source Performance Standard (NSPS) for
Carbon Monoxide (CO)
Table 12 to Subpart UUU of Part 63--Initial Compliance with Organic HAP
Emission Limits for Catalytic Cracking Units
Table 13 to Subpart UUU of Part 63--Continuous Compliance with Organic
HAP Emission Limits for Catalytic Cracking Units
Table 14 to Subpart UUU of Part 63--Continuous Compliance with Operating
Limits for Organic HAP Emissions from Catalytic Cracking Units
Table 15 to Subpart UUU of Part 63--Organic HAP Emission Limits for
Catalytic Reforming Units
Table 16 to Subpart UUU of Part 63--Operating Limits for Organic HAP
Emissions from Catalytic Reforming Units
Table 17 to Subpart UUU of Part 63--Continuous Monitoring Systems for
Organic HAP Emissions from Catalytic Reforming Units
Table 18 to Subpart UUU of Part 63--Requirements for Performance Tests
for Organic HAP Emissions from Catalytic Reforming Units
Table 19 to Subpart UUU of Part 63--Initial Compliance with Organic HAP
Emission Limits for Catalytic Reforming Units
Table 20 to Subpart UUU of Part 63--Continuous Compliance with Organic
HAP Emission Limits for Catalytic Reforming Units
Table 21 to Subpart UUU of Part 63--Continuous Compliance with Operating
Limits for Organic HAP Emissions from Catalytic Reforming
Units
Table 22 to Subpart UUU of Part 63--Inorganic HAP Emission Limits for
Catalytic Reforming Units
Table 23 to Subpart UUU of Part 63--Operating Limits for Inorganic HAP
Emission Limitations for Catalytic Reforming Units
Table 24 to Subpart UUU of Part 63--Continuous Monitoring Systems for
Inorganic HAP Emissions from Catalytic Reforming Units
Table 25 to Subpart UUU of Part 63--Requirements for Performance Tests
for Inorganic HAP Emissions from Catalytic Reforming Units
Table 26 to Subpart UUU of Part 63--Initial Compliance with Inorganic
HAP Emission Limits for Catalytic Reforming Units
Table 27 to Subpart UUU of Part 63--Continuous Compliance with Inorganic
HAP Emission Limits for Catalytic Reforming Units
Table 28 to Subpart UUU of Part 63--Continuous Compliance with Operating
Limits for Inorganic HAP Emissions from Catalytic Reforming
Units
Table 29 to Subpart UUU of Part 63--HAP Emission Limits for Sulfur
Recovery Units
Table 30 to Subpart UUU of Part 63--Operating Limits for HAP Emissions
from Sulfur Recovery Units
Table 31 to Subpart UUU of Part 63--Continuous Monitoring Systems for
HAP Emissions from Sulfur Recovery Units
Table 32 to Subpart UUU of Part 63--Requirements for Performance Tests
for HAP Emissions from Sulfur Recovery Units Not Subject to
the New Source Performance Standards (NSPS) for Sulfur Oxides
Table 33 to Subpart UUU of Part 63--Initial Compliance with HAP Emission
Limits for Sulfur Recovery Units
Table 34 to Subpart UUU of Part 63--Continuous Compliance with HAP
Emission Limits for Sulfur Recovery Units
Table 35 to Subpart UUU of Part 63--Continuous Compliance with Operating
Limits for HAP Emissions from Sulfur Recovery Units
Table 36 to Subpart UUU of Part 63--Work Practice Standards for HAP
Emissions from Bypass Lines
Table 37 to Subpart UUU of Part 63--Requirements for Performance Tests
for Bypass Lines
Table 38 to Subpart UUU of Part 63--Initial Compliance with Work
Practice Standards for HAP Emissions from Bypass Lines
Table 39 to Subpart UUU of Part 63--Continuous Compliance with Work
Practice Standards for HAP Emissions from Bypass Lines
Table 40 to Subpart UUU of Part 63--Requirements for Installation,
Operation, and Maintenance of Continuous Opacity Monitoring
Systems and Continuous Emission Monitoring Systems
Table 41 to Subpart UUU of Part 63--Requirements for Installation,
Operation, and Maintenance of Continuous Parameter Monitoring
Systems
Table 42 to Subpart UUU of Part 63--Additional Information for Initial
Notification of Compliance Status
Table 43 to Subpart UUU of Part 63--Requirements for Reports
Table 44 to Subpart UUU of Part 63--Applicability of NESHAP General
Provisions to Subpart UUU
[[Page 8]]
Appendix A to Subpart UUU of Part 63--Determination of Metal
Concentration on Catalyst Particles (Instrumental Analyzer
Procedure)
Subpart VVV_National Emission Standards for Hazardous Air Pollutants:
Publicly Owned Treatment Works
Applicability
63.1580 Am I subject to this subpart?
63.1581 Does the subpart distinguish between different types of POTW
treatment plants?
Industrial POTW Treatment Plant Description and Requirements
63.1582 What are the characteristics of an industrial POTW treatment
plant?
63.1583 What are the emission points and control requirements for an
industrial POTW treatment plant?
63.1584 When do I have to comply?
63.1585 How does an industrial POTW treatment plant demonstrate
compliance?
Non-industrial POTW Treatment Plant Requirements
63.1586 What are the emission points and control requirements for a non-
industrial POTW treatment plant?
63.1587 When do I have to comply?
63.1588 What inspections must I conduct?
63.1589 What records must I keep?
63.1590 What reports must I submit?
General Requirements
63.1591 What are my notification requirements?
63.1592 Which General Provisions apply to my POTW treatment plant?
63.1593 How will the EPA determine if I am in compliance with this
subpart?
63.1594 Who enforces this subpart?
63.1595 List of definitions.
Table 1 to Subpart VVV of Part 63--Applicability of 40 CFR Part 63
General Provisions to Subpart VVV
Subpart WWW [Reserved]
Subpart XXX_National Emission Standards for Hazardous Air Pollutants for
Ferroalloys Production: Ferromanganese and Silicomanganese
63.1620-63.1649 [Reserved]
63.1650 Applicability and compliance dates.
63.1651 Definitions.
63.1652 Emission standards.
63.1653 Opacity standards.
63.1654 Operational and work practice standards.
63.1655 Maintenance requirements.
63.1656 Performance testing, test methods, and compliance
demonstrations.
63.1657 Monitoring requirements.
63.1658 Notification requirements.
63.1659 Reporting requirements.
63.1660 Recordkeeping requirements.
63.1661 Implementation and enforcement.
63.1662-63.1679 [Reserved]
Subpart AAAA_National Emission Standards for Hazardous Air Pollutants:
Municipal Solid Waste Landfills
What This Subpart Covers
63.1930 What is the purpose of this subpart?
63.1935 Am I subject to this subpart?
63.1940 What is the affected source of this subpart?
63.1945 When do I have to comply with this subpart?
63.1947 When do I have to comply with this subpart if I own or operate a
bioreactor?
63.1950 When am I no longer required to comply with this subpart?
63.1952 When am I no longer required to comply with the requirements of
this subpart if I own or operate a bioreactor?
Standards
63.1955 What requirements must I meet?
General and Continuing Compliance Requirements
63.1960 How is compliance determined?
63.1965 What is a deviation?
63.1975 How do I calculate the 3-hour block average used to demonstrate
compliance?
Notifications, Reports and Records
63.1980 What records and reports must I keep and submit?
Other Requirements and Information
63.1985 Who enforces this subpart?
63.1990 What definitions apply to this subpart?
Table 1 of Subpart AAAA of Part 63--Applicability of NESHAP General
Provisions to Subpart AAAA
Subpart CCCC_National Emission Standards for Hazardous Air Pollutants:
Manufacturing of Nutritional Yeast
What This Subpart Covers
63.2130 What is the purpose of this subpart?
63.2131 Am I subject to this subpart?
63.2132 What parts of my plant does this subpart cover?
63.2133 When do I have to comply with this subpart?
[[Page 9]]
Emission Limitations
63.2140 What emission limitations must I meet?
General Compliance Requirements
63.2150 What are my general requirements for complying with this
subpart?
Testing and Initial Compliance Requirements
63.2160 By what date must I conduct an initial compliance demonstration?
63.2161 What performance tests and other procedures must I use if I
monitor brew ethanol?
63.2162 When must I conduct subsequent performance tests?
63.2163 If I monitor fermenter exhaust, what are my monitoring
installation, operation, and maintenance requirements?
63.2164 If I monitor brew ethanol, what are my monitoring installation,
operation, and maintenance requirements?
63.2165 How do I demonstrate initial compliance with the emission
limitations if I monitor fermenter exhaust?
63.2166 How do I demonstrate initial compliance with the emission
limitations if I monitor brew ethanol?
Continuous Compliance Requirements
63.2170 How do I monitor and collect data to demonstrate continuous
compliance?
63.2171 How do I demonstrate continuous compliance with the emission
limitations?
Notifications, Reports, And Records
63.2180 What notifications must I submit and when?
63.2181 What reports must I submit and when?
63.2182 What records must I keep?
63.2183 In what form and how long must I keep my records?
Other Requirements And Information
63.2190 What parts of the General Provisions apply to me?
63.2191 Who implements and enforces this subpart?
63.2192 What definitions apply to this subpart?
Table 1 to Subpart CCCC of Part 63--Emission Limitations
Table 2 to Subpart CCCC of Part 63--Requirements for Performance Tests
(Brew Ethanol Monitoring Only)
Table 3 to Subpart CCCC of Part 63--Initial Compliance With Emission
Limitations
Table 4 to Subpart CCCC of Part 63--Continuous Compliance with Emission
Limitations
Table 5 to Subpart CCCC of Part 63--Requirements for Reports
Table 6 to Subpart CCCC of Part 63--Applicability of General Provisions
to Subpart CCCC
Subpart DDDD_National Emission Standards for Hazardous Air Pollutants:
Plywood and Composite Wood Products
What This Subpart Covers
63.2230 What is the purpose of this subpart?
63.2231 Does this subpart apply to me?
63.2232 What parts of my plant does this subpart cover?
63.2233 When do I have to comply with this subpart?
Compliance Options, Operating Requirements, and Work Practice
Requirements
63.2240 What are the compliance options and operating requirements and
how must I meet them?
63.2241 What are the work practice requirements and how must I meet
them?
General Compliance Requirements
63.2250 What are the general requirements?
63.2251 What are the requirements for the routine control device
maintenance exemption?
63.2252 What are the requirements for process units that have no control
or work practice requirements?
Initial Compliance Requirements
63.2260 How do I demonstrate initial compliance with the compliance
options, operating requirements, and work practice
requirements?
63.2261 By what date must I conduct performance tests or other initial
compliance demonstrations?
63.2262 How do I conduct performance tests and establish operating
requirements?
63.2263 Initial compliance demonstration for a dry rotary dryer.
63.2264 Initial compliance demonstration for a hardwood veneer dryer.
63.2265 Initial compliance demonstration for a softwood veneer dryer.
63.2266 Initial compliance demonstration for a veneer redryer.
63.2267 Initial compliance demonstration for a reconstituted wood
product press or board cooler.
63.2268 Initial compliance demonstration for a wet control device.
63.2269 What are my monitoring installation, operation, and maintenance
requirements?
[[Page 10]]
Continuous Compliance Requirements
63.2270 How do I monitor and collect data to demonstrate continuous
compliance?
63.2271 How do I demonstrate continuous compliance with the compliance
options, operating requirements, and work practice
requirements?
Notifications, Reports, and Records
63.2280 What notifications must I submit and when?
63.2281 What reports must I submit and when?
63.2282 What records must I keep?
63.2283 In what form and how long must I keep my records?
Other Requirements and Information
63.2290 What parts of the General Provisions apply to me?
63.2291 Who implements and enforces this subpart?
63.2292 What definitions apply to this subpart?
Table 1A to Subpart DDDD of Part 63--Production-Based Compliance Options
Table 1B to Subpart DDDD of Part 63--Add-On Control Systems Compliance
Options
Table 2 to Subpart DDDD of Part 63--Operating Requirements
Table 3 to Subpart DDDD of Part 63--Work Practice Requirements
Table 4 to Subpart DDDD of Part 63--Requirements for Performance Tests
Table 5 to Subpart DDDD of Part 63--Performance Testing and Initial
Compliance Demonstrations for the Compliance Options and
Operating Requirements
Table 6 to Subpart DDDD of Part 63--Initial Compliance Demonstrations
for Work Practice Requirements
Table 7 to Subpart DDDD of Part 63--Continuous Compliance With the
Compliance Options and Operating Requirements
Table 8 to Subpart DDDD of Part 63--Continuous Compliance With the Work
Practice Requirements
Table 9 to Subpart DDDD of Part 63--Requirements for Reports
Table 10 to Subpart DDDD of Part 63--Applicability of General Provisions
to Subpart DDDD
Appendix A to Subpart DDDD of Part 63--Alternative Procedure To
Determine Capture Efficiency From Enclosures Around Hot
Presses in the Plywood and Composite Wood Products Industry
Using Sulfur Hexafluoride Tracer Gas
Appendix B to Subpart DDDD of Part 63--Methodology and Criteria for
Demonstrating That An Affected Source is Part of the Low-risk
Subcategory of Plywood and Composite Wood Products
Manufacturing Affected Sources
Appendix C to Subpart DDDD of Part 63--Considerations for a Small-Scale
Kiln Emission Testing Program
Subpart EEEE_National Emission Standards for Hazardous Air Pollutants:
Organic Liquids Distribution (Non-Gasoline)
What This Subpart Covers
63.2330 What is the purpose of this subpart?
63.2334 Am I subject to this subpart?
63.2338 What parts of my plant does this subpart cover?
63.2342 When do I have to comply with this subpart?
Emission Limitations, Operating Limits, and Work Practice Standards
63.2346 What emission limitations, operating limits, and work practice
standards must I meet?
General Compliance Requirements
63.2350 What are my general requirements for complying with this
subpart?
Testing and Initial Compliance Requirements
63.2354 What performance tests, design evaluations, and performance
evaluations must I conduct?
63.2358 By what date must I conduct performance tests or other initial
compliance demonstrations?
63.2362 When must I conduct subsequent performance tests?
63.2366 What are my monitoring installation, operation, and maintenance
requirements?
63.2370 How do I demonstrate initial compliance with the emission
limitations, operating limits, and work practice standards?
Continuous Compliance Requirements
63.2374 When do I monitor and collect data to demonstrate continuous
compliance and how do I use the collected data?
63.2378 How do I demonstrate continuous compliance with the emission
limitations, operating limits, and work practice standards?
Notifications, Reports, and Records
63.2382 What notifications must I submit and when and what information
should be submitted?
63.2386 What reports must I submit and when and what information is to
be submitted in each?
63.2390 What records must I keep?
63.2394 In what form and how long must I keep my records?
[[Page 11]]
Other Requirements and Information
63.2396 What compliance options do I have if part of my plant is subject
to both this subpart and another subpart?
63.2398 What parts of the General Provisions apply to me?
63.2402 Who implements and enforces this subpart?
63.2406 What definitions apply to this subpart?
Table 1 to Subpart EEEE of Part 63--Organic Hazardous Air Pollutants
Table 2 to Subpart EEEE of Part 63--Emission Limits
Table 3 to Subpart EEEE of Part 63--Operating Limits--High Throughput
Transfer Racks
Table 4 to Subpart EEEE of Part 63--Work Practice Standards
Table 5 to Subpart EEEE of Part 63--Requirements for Performance Tests
and Design Evaluations
Table 6 to Subpart EEEE of Part 63--Initial Compliance with Emission
Limits
Table 7 to Subpart EEEE of Part 63--Initial Compliance with Work
Practice Standards
Table 8 to Subpart EEEE of Part 63--Continuous Compliance with Emission
Limits
Table 9 to Subpart EEEE of Part 63--Continuous Compliance with Operating
Limits--High Throughput Transfer Racks
Table 10 to Subpart EEEE of Part 63--Continuous Compliance with Work
Practice Standards
Table 11 to Subpart EEEE of Part 63--Requirements for Reports
Table 12 to Subpart EEEE of Part 63--Applicability of General Provisions
to Subpart EEEE
Subpart FFFF_National Emission Standards for Hazardous Air Pollutants:
Miscellaneous Organic Chemical Manufacturing
What This Subpart Covers
63.2430 What is the purpose of this subpart?
63.2435 Am I subject to the requirements in this subpart?
63.2440 What parts of my plant does this subpart cover?
Compliance Dates
63.2445 When do I have to comply with this subpart?
Emission Limits, Work Practice Standards, and Compliance Requirements
63.2450 What are my general requirements for complying with this
subpart?
63.2455 What requirements must I meet for continuous process vents?
63.2460 What requirements must I meet for batch process vents?
63.2465 What requirements must I meet for process vents that emit
hydrogen halide and halogen HAP or PM HAP?
63.2470 What requirements must I meet for storage tanks?
63.2475 What requirements must I meet for transfer racks?
63.2480 What requirements must I meet for equipment leaks?
63.2485 What requirements must I meet for wastewater streams and liquid
streams in open systems within an MCPU?
63.2490 What requirements must I meet for heat exchange systems?
Alternative Means of Compliance
63.2495 How do I comply with the pollution prevention standard?
63.2500 How do I comply with emissions averaging?
63.2505 How do I comply with the alternative standard?
Notifications, Reports, and Records
63.2515 What notifications must I submit and when?
63.2520 What reports must I submit and when?
63.2525 What records must I keep?
Other Requirements and Information
63.2535 What compliance options do I have if part of my plant is subject
to both this subpart and another subpart?
63.2540 What parts of the General Provisions apply to me?
63.2545 Who implements and enforces this subpart?
63.2550 What definitions apply to this subpart?
Table 1 to Subpart FFFF of Part 63--Emission Limits and Work Practice
Standards for Continuous Process Vents
Table 2 to Subpart FFFF of Part 63--Emission Limits and Work Practice
Standards for Batch Process Vents
Table 3 to Subpart FFFF of Part 63--Emission Limits for Hydrogen Halide
and Halogen HAP Emissions or PM HAP Emissions from Process
Vents
Table 4 to Subpart FFFF of Part 63--Emission Limits for Storage Tanks
Table 5 to Subpart FFFF of Part 63--Emission Limits and Work Practice
Standards for Transfer Racks
Table 6 to Subpart FFFF of Part 63--Requirements for Equipment Leaks
Table 7 to Subpart FFFF of Part 63--Requirements for Wastewater Streams
and Liquid Streams in Open Systems Within an MCPU
Table 8 to Subpart FFFF of Part 63--Partially Soluble Hazardous Air
Pollutants
[[Page 12]]
Table 9 to Subpart FFFF of Part 63--Soluble Hazardous Air Pollutants
Table 10 to Subpart FFFF of Part 63--Requirements for Heat Exchange
Systems
Table 11 to Subpart FFFF of Part 63--Requirements for Reports
Table 12 to Subpart FFFF of Part 63--Applicability of General Provisions
(Subpart A) to Subpart FFFF
Subpart GGGG_National Emission Standards for Hazardous Air Pollutants:
Solvent Extraction for Vegetable Oil Production
What This Subpart Covers
63.2830 What is the purpose of this subpart?
63.2831 Where can I find definitions of key words used in this subpart?
63.2832 Am I subject to this subpart?
63.2833 Is my source categorized as existing or new?
63.2834 When do I have to comply with the standards in this subpart?
Standards
63.2840 What emission requirements must I meet?
Compliance Requirements
63.2850 How do I comply with the hazardous air pollutant emission
standards?
63.2851 What is a plan for demonstrating compliance?
63.2852 What is a startup, shutdown, and malfunction plan?
63.2853 How do I determine the actual solvent loss?
63.2854 How do I determine the weighted average volume fraction of HAP
in the actual solvent loss?
63.2855 How do I determine the quantity of oilseed processed?
Notifications, Reports, and Records
63.2860 What notifications must I submit and when?
63.2861 What reports must I submit and when?
63.2862 What records must I keep?
63.2863 In what form and how long must I keep my records?
Other Requirements and Information
63.2870 What parts of the General Provisions apply to me?
63.2871 Who implements and enforces this subpart?
63.2872 What definitions apply to this subpart?
Subpart HHHH_National Emission Standards for Hazardous Air Pollutants
for Wet-Formed Fiberglass Mat Production
What This Subpart Covers
63.2980 What is the purpose of this subpart?
63.2981 Does this subpart apply to me?
63.2982 What parts of my plant does this subpart cover?
Emission Limitations
63.2983 What emission limits must I meet?
63.2984 What operating limits must I meet?
63.2985 When do I have to comply with these standards?
63.2986 How do I comply with the standards?
Operation, Maintenance, and Monitoring Plan
63.2987 What must my operation, maintenance, and monitoring (OMM) plan
include?
63.2988 [Reserved]
63.2989 How do I change my (OMM) plan?
63.2990 Can I conduct short-term experimental production runs that cause
parameters to deviate from operating limits?
Testing and Initial Compliance Requirements
63.2991 When must I conduct performance tests?
63.2992 How do I conduct a performance test?
63.2993 What test methods must I use in conducting performance tests?
63.2994 How do I verify the performance of monitoring equipment?
63.2995 What equations must I use to determine compliance?
Monitoring Requirements
63.2996 What must I monitor?
63.2997 What are the requirements for monitoring devices?
Notifications, Reports, and Records
63.2998 What records must I maintain?
63.2999 In what form and for how long must I maintain records?
63.3000 What notifications and reports must I submit?
Other Requirements and Information
63.3001 What sections of the general provisions apply to me?
63.3002 Who implements and enforces this subpart?
63.3003 Incorporation by reference.
63.3004 What definitions apply to this subpart?
[[Page 13]]
63.3005-63.3079 [Reserved]
Table 1 to Subpart HHHH of Part 63--Minimum Requirements for Monitoring
and Recordkeeping
Table 2 to Subpart HHHH of Part 63--Applicability of General Provisions
(40 CFR Part 63, Subpart A) to Subpart HHHH
Appendix A to Subpart HHHH of Part 63--Method for Determining Free-
Formaldehyde in Urea-Formaldehyde Resins by Sodium Sulfite
(Iced & Cooled)
Appendix B to Subpart HHHH of Part 63--Method for the Determination of
Loss-on-Ignition
Subpart IIII_National Emission Standards for Hazardous Air Pollutants:
Surface Coating of Automobiles and Light-Duty Trucks
What This Subpart Covers
Sec.
63.3080 What is the purpose of this subpart?
63.3081 Am I subject to this subpart?
63.3082 What parts of my plant does this subpart cover?
63.3083 When do I have to comply with this subpart?
Emission Limitations
63.3090 What emission limits must I meet for a new or reconstructed
affected source?
63.3091 What emission limits must I meet for an existing affected
source?
63.3092 How must I control emissions from my electrodeposition primer
system if I want to comply with the combined primer-surfacer,
topcoat, final repair, glass bonding primer, and glass bonding
adhesive emission limit?
63.3093 What operating limits must I meet?
63.3094 What work practice standards must I meet?
General Compliance Requirements
63.3100 What are my general requirements for complying with this
subpart?
63.3101 What parts of the General Provisions apply to me?
Notifications, Reports, and Records
63.3110 What notifications must I submit?
63.3120 What reports must I submit?
63.3130 What records must I keep?
63.3131 In what form and for how long must I keep my records?
Compliance Requirements for Adhesive, Sealer, and Deadener
63.3150 By what date must I conduct the initial compliance
demonstration?
63.3151 How do I demonstrate initial compliance with the emission
limitations?
63.3152 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Combined Electrodeposition Primer,
Primer-Surfacer, Topcoat, Final Repair, Glass Bonding Primer, and Glass
Bonding Adhesive Emission Limitations
63.3160 By what date must I conduct performance tests and other initial
compliance demonstrations?
63.3161 How do I demonstrate initial compliance?
63.3162 [Reserved]
63.3163 How do I demonstrate continuous compliance with the emission
limitations?
63.3164 What are the general requirements for performance tests?
63.3165 How do I determine the emission capture system efficiency?
63.3166 How do I determine the add-on control device emission
destruction or removal efficiency?
63.3167 How do I establish the add-on control device operating limits
during the performance test?
63.3168 What are the requirements for continuous parameter monitoring
system installation, operation, and maintenance?
Compliance Requirements for the Combined Primer-Surfacer, Topcoat, Final
Repair, Glass Bonding Primer, and Glass Bonding Adhesive Emission
Limitations and the Separate Electrodeposition Primer Emission
Limitations
63.3170 By what date must I conduct performance tests and other initial
compliance demonstrations?
63.3171 How do I demonstrate initial compliance?
63.3172 [Reserved]
63.3173 How do I demonstrate continuous compliance with the emission
limitations?
Other Requirements and Information
63.3175 Who implements and enforces this subpart?
63.3176 What definitions apply to this subpart?
Tables to Subpart IIII of Part 63
Table 1 to Subpart IIII of Part 63. Operating Limits for Capture Systems
and Add-On Control Devices
Table 2 to Subpart IIII of Part 63. Applicability of General Provisions
to Subpart IIII of Part 63
Table 3 to Subpart IIII of Part 63. Default Organic HAP Mass Fraction
for Solvents and Solvent Blends
[[Page 14]]
Table 4 to Subpart IIII of Part 63. Default Organic HAP Mass Fraction
for Petroleum Solvent Groups
Appendix A to Subpart IIII of Part 63--Determination of Capture
Efficiency of Automobile and Light-Duty Truck Spray Booth
Emissions from Solvent-borne Coatings Using Panel Testing
Subpart JJJJ_National Emission Standards for Hazardous Air Pollutants:
Paper and Other Web Coating
What This Subpart Covers
63.3280 What is in this subpart?
63.3290 Does this subpart apply to me?
63.3300 Which of my emission sources are affected by this subpart?
63.3310 What definitions are used in this subpart?
Emission Standards and Compliance Dates
63.3320 What emission standards must I meet?
63.3321 What operating limits must I meet?
63.3330 When must I comply?
General Requirements for Compliance With the Emission Standards and for
Monitoring and Performance Tests
63.3340 What general requirements must I meet to comply with the
standards?
63.3350 If I use a control device to comply with the emission standards
what monitoring must I do?
63.3360 What performance tests must I conduct?
Requirements for Showing Compliance
63.3370 How do I demonstrate compliance with the emission standards?
Notifications, Reports, and Records
63.3400 What notifications and reports must I submit?
63.3410 What records must I keep?
Delegation of Authority
63.3420 What authorities may be delegated to the States?
Table 1 to Subpart JJJJ of Part 63--Operating Limits if Using Add-On
Control Devices and Capture System
Table 2 to Subpart JJJJ of Part 63--Applicability of 40 CFR Part 63
General Provisions to Subpart JJJJ
Subpart KKKK_National Emission Standards for Hazardous Air Pollutants:
Surface Coating of Metal Cans
What This Subpart Covers
63.3480 What is the purpose of this subpart?
63.3481 Am I subject to this subpart?
63.3482 What parts of my plant does this subpart cover?
63.3483 When do I have to comply with this subpart?
Emission Limitations
63.3490 What emission limits must I meet?
63.3491 What are my options for meeting the emission limits?
63.3492 What operating limits must I meet?
63.3493 What work practice standards must I meet?
General Compliance Requirements
63.3500 What are my general requirements for complying with this
subpart?
63.3501 What parts of the General Provisions apply to me?
Notifications, Reports, and Records
63.3510 What notifications must I submit?
63.3511 What reports must I submit?
63.3512 What records must I keep?
63.3513 In what form and for how long must I keep my records?
Compliance Requirements for the Compliant Material Option
63.3520 By what date must I conduct the initial compliance
demonstration?
63.3521 How do I demonstrate initial compliance with the emission
limitations?
63.3522 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate Without Add-On Controls
Option
63.3530 By what date must I conduct the initial compliance
demonstration?
63.3531 How do I demonstrate initial compliance with the emission
limitations?
63.3532 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate With Add-On Controls
Option
63.3540 By what date must I conduct performance tests and other initial
compliance demonstrations?
63.3541 How do I demonstrate initial compliance?
63.3542 How do I demonstrate continuous compliance with the emission
limitations?
63.3543 What are the general requirements for performance tests?
63.3544 How do I determine the emission capture system efficiency?
63.3545 How do I determine the add-on control device emission
destruction or removal efficiency?
63.3546 How do I establish the emission capture system and add-on
control device
[[Page 15]]
operating limits during the performance test?
63.3547 What are the requirements for continuous parameter monitoring
system installation, operation, and maintenance?
Compliance Requirements for the Control Efficiency/Outlet Concentration
Option
63.3550 By what date must I conduct performance tests and other initial
compliance demonstrations?
63.3551 How do I demonstrate initial compliance?
63.3552 How do I demonstrate continuous compliance with the emission
limitations?
63.3553 What are the general requirements for performance tests?
63.3554 How do I determine the emission capture system efficiency?
63.3555 How do I determine the outlet THC emissions and add-on control
device emission destruction or removal efficiency?
63.3556 How do I establish the emission capture system and add-on
control device operating limits during the performance test?
63.3557 What are the requirements for continuous parameter monitoring
system installation, operation, and maintenance?
Other Requirements and Information
63.3560 Who implements and enforces this subpart?
63.3561 What definitions apply to this subpart?
Table 1 to Subpart KKKK of Part 63--Emission Limits for New or
Reconstructed Affected Sources
Table 2 to Subpart KKKK of Part 63--Emission Limits for Existing
Affected Sources
Table 3 to Subpart KKKK of Part 63--Emission Limits for Affected Sources
Using the Control Efficiency/Outlet Concentration Compliance
Option
Table 4 to Subpart KKKK of Part 63--Operating Limits if Using the
Emission Rate with Add-on Controls Option or the Control
Efficiency/Outlet Concentration Compliance Option
Table 5 to Subpart KKKK of Part 63--Applicability of General Provisions
to Subpart KKKK
Table 6 to Subpart KKKK of Part 63--Default Organic HAP Mass Fraction
for Solvents and Solvent Blends
Table 7 to Subpart KKKK of Part 63--Default Organic HAP Mass Fraction
for Petroleum Solvent Groups
Subpart MMMM_National Emission Standards for Hazardous Air Pollutants
for Surface Coating of Miscellaneous Metal Parts and Products
What This Subpart Covers
63.3880 What is the purpose of this subpart?
63.3881 Am I subject to this subpart?
63.3882 What parts of my plant does this subpart cover?
63.3883 When do I have to comply with this subpart?
Emission Limitations
63.3890 What emission limits must I meet?
63.3891 What are my options for meeting the emission limits?
63.3892 What operating limits must I meet?
63.3893 What work practice standards must I meet?
General Compliance Requirements
63.3900 What are my general requirements for complying with this
subpart?
63.3901 What parts of the General Provisions apply to me?
Notifications, Reports, and Records
63.3910 What notifications must I submit?
63.3920 What reports must I submit?
63.3930 What records must I keep?
63.3931 In what form and for how long must I keep my records?
Compliance Requirements for the Compliant Material Option
63.3940 By what date must I conduct the initial compliance
demonstration?
63.3941 How do I demonstrate initial compliance with the emission
limitations?
63.3942 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate Without Add-On Controls
Option
63.3950 By what date must I conduct the initial compliance
demonstration?
63.3951 How do I demonstrate initial compliance with the emission
limitations?
63.3952 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate With Add-On Controls
Option
63.3960 By what date must I conduct performance tests and other initial
compliance demonstrations?
63.3961 How do I demonstrate initial compliance?
[[Page 16]]
63.3962 [Reserved]
63.3963 How do I demonstrate continuous compliance with the emission
limitations?
63.3964 What are the general requirements for performance tests?
63.3965 How do I determine the emission capture system efficiency?
63.3966 How do I determine the add-on control device emission
destruction or removal efficiency?
63.3967 How do I establish the emission capture system and add-on
control device operating limits during the performance test?
63.3968 What are the requirements for continuous parameter monitoring
system installation, operation, and maintenance?
Other Requirements and Information
63.3980 Who implements and enforces this subpart?
63.3981 What definitions apply to this subpart?
Table 1 to Subpart MMMM of Part 63--Operating Limits if Using the
Emission Rate with Add-on Controls Option
Table 2 to Subpart MMMM of Part 63--Applicability of General Provisions
to Subpart MMMM of Part 63
Table 3 to Subpart MMMM of Part 63--Default Organic HAP Mass Fraction
for Solvents and Solvent Blends
Table 4 to Subpart MMMM of Part 63--Default Organic HAP Mass Fraction
for Petroleum Solvent Groups
Appendix A to Subpart MMMM of Part 63--Alternative Capture Efficiency
and Destruction Efficiency Measurement and Capture Efficiency
Monitoring Procedures for Magnet Wire Coating Operations
Subpart NNNN_National Emission Standards for Hazardous Air Pollutants:
Surface Coating of Large Appliances
What This Subpart Covers
63.4080 What is the purpose of this subpart?
63.4081 Am I subject to this subpart?
63.4082 What parts of my plant does this subpart cover?
63.4083 When do I have to comply with this subpart?
Emission Limitations
63.4090 What emission limits must I meet?
63.4091 What are my options for meeting the emission limits?
63.4092 What operating limits must I meet?
63.4093 What work practice standards must I meet?
General Compliance Requirements
63.4100 What are my general requirements for complying with this
subpart?
63.4101 What parts of the General Provisions apply to me?
Notifications, Reports, and Records
63.4110 What notifications must I submit?
63.4120 What reports must I submit?
63.4130 What records must I keep?
63.4131 In what form and for how long must I keep my records?
Compliance Requirements for the Compliant Material Option
63.4140 By what date must I conduct the initial compliance
demonstration?
63.4141 How do I demonstrate initial compliance with the emission
limitations?
63.4142 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate Without Add-On Controls
Option
63.4150 By what date must I conduct the initial compliance
demonstration?
63.4151 How do I demonstrate initial compliance with the emission
limitations?
63.4152 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate With Add-On Controls
Option
63.4160 By what date must I conduct performance tests and other initial
compliance demonstrations?
63.4161 How do I demonstrate initial compliance?
63.4162 [Reserved]
63.4163 How do I demonstrate continuous compliance with the emission
limitations?
63.4164 What are the general requirements for performance tests?
63.4165 How do I determine the emission capture system efficiency?
63.4166 How do I determine the add-on control device emission
destruction or removal efficiency?
63.4167 How do I establish the emission capture system and add-on
control device operating limits during the performance test?
63.4168 What are the requirements for continuous parameter monitoring
system installation, operation, and maintenance?
Other Requirements and Information
63.4180 Who implements and enforces this subpart?
63.4181 What definitions apply to this subpart?
[[Page 17]]
Table 1 to Subpart NNNN of Part 63--Operating Limits if Using the
Emission Rate with Add-on Controls Option
Table 2 to Subpart NNNN of Part 63--Applicability of General Provisions
to Subpart NNNN
Table 3 to Subpart NNNN of Part 63--Default Organic HAP Mass Fraction
for Solvents and Solvent Blends
Table 4 to Subpart NNNN of Part 63--Default Organic Mass Fraction for
Petroleum Solvent Groups
Subpart OOOO_National Emission Standards for Hazardous Air Pollutants:
Printing, Coating, and Dyeing of Fabrics and Other Textiles
What This Subpart Covers
63.4280 What is the purpose of this subpart?
63.4281 Am I subject to this subpart?
63.4282 What parts of my plant does this subpart cover?
63.4283 When do I have to comply with this subpart?
Emission Limitations
63.4290 What emission limits must I meet?
63.4291 What are my options for meeting the emission limits?
63.4292 What operating limits must I meet?
63.4293 What work practice standards must I meet?
General Compliance Requirements
63.4300 What are my general requirements for complying with this
subpart?
63.4301 What parts of the General Provisions apply to me?
Notifications, Reports, and Records
63.4310 What notifications must I submit?
63.4311 What reports must I submit?
63.4312 What records must I keep?
63.4313 In what form and for how long must I keep my records?
Compliance Requirements for the Compliant Material Option
63.4320 By what date must I conduct the initial compliance
demonstration?
63.4321 How do I demonstrate initial compliance with the emission
limitations?
63.4322 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate Without Add-On Controls
Option
63.4330 By what date must I conduct the initial compliance
demonstration?
63.4331 How do I demonstrate initial compliance with the emission
limitations?
63.4332 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate With Add-On Controls
Option
63.4340 By what date must I conduct performance tests and other initial
compliance demonstrations?
63.4341 How do I demonstrate initial compliance?
63.4342 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Organic HAP Overall Control Efficiency
and Oxidizer Outlet Organic HAP Concentration Options
63.4350 By what date must I conduct performance tests and other initial
compliance demonstrations?
63.4351 How do I demonstrate initial compliance?
63.4352 How do I demonstrate continuous compliance with the emission
limitations?
Performance Testing and Monitoring Requirements
63.4360 What are the general requirements for performance tests?
63.4361 How do I determine the emission capture system efficiency?
63.4362 How do I determine the add-on control device emission
destruction or removal efficiency?
63.4363 How do I establish the add-on control device operating limits
during the performance test?
63.4364 What are the requirements for CPMS installation, operation, and
maintenance?
Other Requirements and Information
63.4370 Who implements and enforces this subpart?
63.4371 What definitions apply to this subpart?
Table 1 to Subpart OOOO of Part 63--Emission Limits for New or
Reconstructed and Existing Affected Sources in the Printing,
Coating, and Dyeing of Fabrics and Other Textiles Source
Category
Table 2 to Subpart OOOO of Part 63--Operating Limits if Using Add-On
Control Devices and Capture System
Table 3 to Subpart OOOO of Part 63--Applicability of General Provisions
to Subpart OOOO
Table 4 to Subpart OOOO of Part 63--Default Organic HAP Mass Fraction
for Solvents and Solvent Blends
[[Page 18]]
Table 5 to Subpart OOOO of Part 63--Default Organic HAP Mass Fraction
for Petroleum Solvent Groups
Subpart PPPP_National Emission Standards for Hazardous Air Pollutants
for Surface Coating of Plastic Parts and Products
What This Subpart Covers
63.4480 What is the purpose of this subpart?
63.4481 Am I subject to this subpart?
63.4482 What parts of my plant does this subpart cover?
63.4483 When do I have to comply with this subpart?
Emission Limitations
63.4490 What emission limits must I meet?
63.4491 What are my options for meeting the emission limits?
63.4492 What operating limits must I meet?
63.4493 What work practice standards must I meet?
General Compliance Requirements
63.4500 What are my general requirements for complying with this
subpart?
63.4501 What parts of the General Provisions apply to me?
Notifications, Reports, and Records
63.4510 What notifications must I submit?
63.4520 What reports must I submit?
63.4530 What records must I keep?
63.4531 In what form and for how long must I keep my records?
Compliance Requirements for the Compliant Material Option
63.4540 By what date must I conduct the initial compliance
demonstration?
63.4541 How do I demonstrate initial compliance with the emission
limitations?
63.4542 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate Without Add-On Controls
Option
63.4550 By what date must I conduct the initial compliance
demonstration?
63.4551 How do I demonstrate initial compliance with the emission
limitations?
63.4552 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate With Add-On Controls
Option
63.4560 By what date must I conduct performance tests and other initial
compliance demonstrations?
63.4561 How do I demonstrate initial compliance?
63.4562 [Reserved]
63.4563 How do I demonstrate continuous compliance with the emission
limitations?
63.4564 What are the general requirements for performance tests?
63.4565 How do I determine the emission capture system efficiency?
63.4566 How do I determine the add-on control device emission
destruction or removal efficiency?
63.4567 How do I establish the emission capture system and add-on
control device operating limits during the performance test?
63.4568 What are the requirements for continuous parameter monitoring
system installation, operation, and maintenance?
Other Requirements and Information
63.4580 Who implements and enforces this subpart?
63.4581 What definitions apply to this subpart?
Table 1 to Subpart PPPP--Operating Limits if Using the Emission Rate
with Add-on Controls Option
Table 2 to Subpart PPPP--Applicability of General Provisions to Subpart
PPPP of Part 63
Table 3 to Subpart PPPP--Default Organic HAP Mass Fraction for Solvents
and Solvent Blends
Table 4 to Subpart PPPP--Default Organic HAP Mass Fraction for Petroleum
Solvent Groups
Appendix A to Subpart PPPP--Determination of Weight Volatile Matter
Content and Weight Solids Content of Reactive Adhesives
Subpart QQQQ_National Emission Standards for Hazardous Air Pollutants:
Surface Coating of Wood Building Products
What This Subpart Covers
63.4680 What is the purpose of this subpart?
63.4681 Am I subject to this subpart?
63.4682 What parts of my plant does this subpart cover?
63.4683 When do I have to comply with this subpart?
Emission Limitations
63.4690 What emission limits must I meet?
63.4691 What are my options for meeting the emission limits?
63.4692 What operating limits must I meet?
63.4693 What work practice standards must I meet?
General Compliance Requirements
63.4700 What are my general requirements for complying with this
subpart?
63.4701 What parts of the General Provisions apply to me?
[[Page 19]]
Notifications, Reports, and Records
63.4710 What notifications must I submit?
63.4720 What reports must I submit?
63.4730 What records must I keep?
63.4731 In what form and for how long must I keep my records?
Compliance Requirements for the Compliant Material Option
63.4740 By what date must I conduct the initial compliance
demonstration?
63.4741 How do I demonstrate initial compliance with the emission
limitations?
63.4742 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate Without Add-On Controls
Option
63.4750 By what date must I conduct the initial compliance
demonstration?
63.4751 How do I demonstrate initial compliance with the emission
limitations?
63.4752 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate With Add-On Controls
Option
63.4760 By what date must I conduct performance tests and other initial
compliance demonstrations?
63.4761 How do I demonstrate initial compliance?
63.4762 [Reserved]
63.4763 How do I demonstrate continuous compliance with the emission
limitations?
63.4764 What are the general requirements for performance tests?
63.4765 How do I determine the emission capture system efficiency?
63.4766 How do I determine the add-on control device emission
destruction or removal efficiency?
63.4767 How do I establish the emission capture system and add-on
control device operating limits during the performance test?
63.4768 What are the requirements for continuous parameter monitoring
system installation, operation, and maintenance?
Other Requirements and Information
63.4780 Who implements and enforces this subpart?
63.4781 What definitions apply to this subpart?
Table 1 to Subpart QQQQ of Part 63--Emission Limits for New or
Reconstructed Affected Sources
Table 2 to Subpart QQQQ of Part 63--Emission Limits for Existing
Affected Sources
Table 3 to Subpart QQQQ of Part 63--Operating Limits if Using the
Emission Rate with Add-on Controls Option
Table 4 to Subpart QQQQ of Part 63--Applicability of General Provisions
to Subpart QQQQ of Part 63
Table 5 to Subpart QQQQ of Part 63--Default Organic HAP Mass Fraction
for Solvents and Solvent Blends
Table 6 to Subpart QQQQ of Part 63--Default Organic HAP Mass Fraction
for Petroleum Solvent Groups
Subpart RRRR_National Emission Standards for Hazardous Air Pollutants:
Surface Coating of Metal Furniture
What This Subpart Covers
63.4880 What is the purpose of this subpart?
63.4881 Am I subject to this subpart?
63.4882 What parts of my plant does this subpart cover?
63.4883 When do I have to comply with this subpart?
Emission Limitations
63.4890 What Emission Limits Must I Meet?
63.4891 What are my options for demonstrating compliance with the
emission limits?
63.4892 What operating limits must I meet?
63.4893 What work practice standards must I meet?
General Compliance Requirements
63.4900 What are my general requirements for complying with this
subpart?
63.4901 What parts of the General Provisions apply to me?
Notifications, Reports, and Records
63.4910 What notifications must I submit?
63.4920 What reports must I submit?
63.4930 What records must I keep?
63.4931 In what form and for how long must I keep my records?
Compliance Requirements for the Compliant Material Option
63.4940 By what date must I conduct the initial compliance
demonstration?
63.4941 How do I demonstrate initial compliance with the emission
limitations?
63.4942 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate Without Add-On Controls
Option
63.4950 By what date must I conduct the initial compliance
demonstration?
63.4951 How do I demonstrate initial compliance with the emission
limitations?
[[Page 20]]
63.4952 How do I demonstrate continuous compliance with the emission
limitations?
Compliance Requirements for the Emission Rate With Add-On Controls
Option
63.4960 By what date must I conduct performance tests and other initial
compliance demonstrations?
63.4961 How do I demonstrate initial compliance?
63.4962 How do I demonstrate continuous compliance with the emission
limitations?
63.4963 What are the general requirements for performance tests?
63.4964 How do I determine the emission capture system efficiency?
63.4965 How do I determine the add-on control device emission
destruction or removal efficiency?
63.4966 How do I establish the emission capture system and add-on
control device operating limits during the performance test?
63.4967 What are the requirements for continuous parameter monitoring
system installation, operation, and maintenance?
Other Requirements and Information
63.4980 Who implements and enforces this subpart?
63.4981 What definitions apply to this subpart?
Table 1 to Subpart RRRR of Part 63--Operating Limits if Using the
Emission Rate with Add-on Controls Option
Table 2 to Subpart RRRR of Part 63--Applicability of General Provisions
to Subpart RRRR
Table 3 to Subpart RRRR of Part 63--Default Organic HAP Mass Fraction
for Solvents and Solvent Blends
Table 4 to Subpart RRRR of Part 63--Default Organic HAP Mass Fraction
for Petroleum Solvent Groups
Subpart SSSS_National Emission Standards for Hazardous Air Pollutants:
Surface Coating of Metal Coil
What This Subpart Covers
63.5080 What is in this subpart?
63.5090 Does this subpart apply to me?
63.5100 Which of my emissions sources are affected by this subpart?
63.5110 What special definitions are used in this subpart?
Emission Standards and Compliance Dates
63.5120 What emission standards must I meet?
63.5121 What operating limits must I meet?
63.5130 When must I comply?
General Requirements for Compliance with the Emission Standards and for
Monitoring and Performance Tests
63.5140 What general requirements must I meet to comply with the
standards?
63.5150 If I use a control device to comply with the emission standards,
what monitoring must I do?
63.5160 What performance tests must I complete?
Requirements for Showing Compliance
63.5170 How do I demonstrate compliance with the standards?
Reporting and Recordkeeping
63.5180 What reports must I submit?
63.5190 What records must I maintain?
Delegation of Authority
63.5200 What authorities may be delegated to the States?
63.5201-63.5209 [Reserved]
Table 1 to Subpart SSSS of Part 63--Operating Limits if Using Add-on
Control Devices and Capture System
Table 2 to Subpart SSSS of Part 63--Applicability of General Provisions
to Subpart SSSS
Subpart TTTT_National Emission Standards for Hazardous Air Pollutants
for Leather Finishing Operations
What This Subpart Covers
63.5280 What is the purpose of this subpart?
63.5285 Am I subject to this subpart?
63.5290 What parts of my facility does this subpart cover?
63.5295 When do I have to comply with this subpart?
Standards
63.5305 What emission standards must I meet?
Compliance Requirements
63.5320 How does my affected major source comply with the HAP emission
standards?
63.5325 What is a plan for demonstrating compliance and when must I have
one in place?
63.5330 How do I determine the compliance ratio?
63.5335 How do I determine the actual HAP loss?
63.5340 How do I determine the allowable HAP loss?
63.5345 How do I distinguish between the two upholstery product process
operations?
63.5350 How do I distinguish between the water-resistant/specialty and
nonwater-
[[Page 21]]
resistant leather product process operations?
63.5355 How do I monitor and collect data to demonstrate continuous
compliance?
63.5360 How do I demonstrate continuous compliance with the emission
standards?
Testing and Initial Compliance Requirements
63.5375 When must I conduct a performance test or initial compliance
demonstration?
63.5380 How do I conduct performance tests?
63.5385 How do I measure the quantity of finish applied to the leather?
63.5390 How do I measure the HAP content of a finish?
63.5395 How do I measure the density of a finish?
63.5400 How do I measure the quantity of leather processed?
Notifications, Reports, and Records
63.5415 What notifications must I submit and when?
63.5420 What reports must I submit and when?
63.5425 When must I start recordkeeping to determine my compliance
ratio?
63.5430 What records must I keep?
63.5435 In what form and how long must I keep my records?
Other Requirements and Information
63.5450 What parts of the General Provisions apply to me?
63.5455 Who administers this subpart?
63.5460 What definitions apply to this subpart?
Figure 1 to Subpart TTTT of Part 63--Example Logs for Recording Leather
Finish Use and HAP Content
Table 1 to Subpart TTTT of Part 63--Leather Finishing HAP Emission
Limits for Determining the Allowable HAP Loss
Table 2 to Subpart TTTT of Part 63--Applicability of General Provisions
to Subpart TTTT
Subpart UUUU_National Emission Standards for Hazardous Air Pollutants
for Cellulose Products Manufacturing
What This Subpart Covers
63.5480 What is the purpose of this subpart?
63.5485 Am I subject to this subpart?
63.5490 What parts of my plant does this subpart cover?
63.5495 When do I have to comply with this subpart?
Emission Limits, Operating Limits, and Work Practice Standards
63.5505 What emission limits, operating limits, and work practice
standards must I meet?
General Compliance Requirements
63.5515 What are my general requirements for complying with this
subpart?
Testing and Initial Compliance Requirements
63.5530 How do I demonstrate initial compliance with the emission limits
and work practice standards?
63.5535 What performance tests and other procedures must I use?
63.5540 By what date must I conduct a performance test or other initial
compliance demonstration?
63.5545 What are my monitoring installation, operation, and maintenance
requirements?
Continuous Compliance Requirements
63.5555 How do I demonstrate continuous compliance with the emission
limits, operating limits, and work practice standards?
63.5560 How do I monitor and collect data to demonstrate continuous
compliance?
Notifications, Reports, and Records
63.5575 What notifications must I submit and when?
63.5580 What reports must I submit and when?
63.5585 What records must I keep?
63.5590 In what form and how long must I keep my records?
Other Requirements and Information
63.5595 What compliance options do I have if part of my affected source
is subject to both this subpart and another subpart?
63.5600 What other requirements apply to me?
63.5605 Who implements and enforces this subpart?
63.5610 What definitions apply to this subpart?
Table 1 to Subpart UUUU of Part 63--Emission Limits and Work Practice
Standards
Table 2 to Subpart UUUU of Part 63--Operating Limits
Table 3 to Subpart UUUU of Part 63--Initial Compliance With Emission
Limits and Work Practice Standards
Table 4 to Subpart UUUU of Part 63--Requirements for Performance Tests
Table 5 to Subpart UUUU of Part 63--Continuous Compliance with Emission
Limits and Work Practice Standards
[[Page 22]]
Table 6 to Subpart UUUU of Part 63--Continuous Compliance with Operating
Limits
Table 7 to Subpart UUUU of Part 63--Requirements for Notifications
Table 8 to Subpart UUUU of Part 63--Requirements for Reports
Table 9 to Subpart UUUU of Part 63--Requirements for Recordkeeping
Table 10 to Subpart UUUU of Part 63--Applicability of General Provisions
to Subpart UUUU
Subpart VVVV_National Emission Standards for Hazardous Air Pollutants
for Boat Manufacturing
What the Subpart Covers
63.5680 What is the purpose of this subpart?
63.5683 Does this subpart apply to me?
63.5686 How do I demonstrate that my facility is not a major source?
63.5689 What parts of my facility are covered by this subpart?
63.5692 How do I know if my boat manufacturing facility is a new source
or an existing source?
63.5695 When must I comply with this subpart?
Standards for Open Molding Resin and Gel Coat Operations
63.5698 What emission limit must I meet for open molding resin and gel
coat operations?
63.5701 What are my options for complying with the open molding emission
limit?
63.5704 What are the general requirements for complying with the open
molding emission limit?
63.5707 What is an implementation plan for open molding operations and
when do I need to prepare one?
63.5710 How do I demonstrate compliance using emissions averaging?
63.5713 How do I demonstrate compliance using compliant materials?
63.5714 How do I demonstrate compliance if I use filled resins?
Demonstrating Compliance for Open Molding Operations Controlled by Add-
on Control Devices
63.5715 What operating limits must I meet?
63.5716 When must I conduct a performance test?
63.5719 How do I conduct a performance test?
63.5722 How do I use the performance test data to demonstrate initial
compliance?
63.5725 What are the requirements for monitoring and demonstrating
continuous compliance?
Standards for Closed Molding Resin Operations
63.5728 What standards must I meet for closed molding resin operations?
Standards for Resin and Gel Coat Mixing Operations
63.5731 What standards must I meet for resin and gel coat mixing
operations?
Standards for Resin and Gel Coat Application Equipment Cleaning
Operations
63.5734 What standards must I meet for resin and gel coat application
equipment cleaning operations?
63.5737 How do I demonstrate compliance with the resin and gel coat
application equipment cleaning standards?
Standards for Carpet and Fabric Adhesive Operations
63.5740 What emission limit must I meet for carpet and fabric adhesive
operations?
Standards for Aluminum Recreational Boat Surface Coating Operations
63.5743 What standards must I meet for aluminum recreational boat
surface coating operations?
63.5746 How do I demonstrate compliance with the emission limits for
aluminum wipedown solvents and aluminum coatings?
63.5749 How do I calculate the organic HAP content of aluminum wipedown
solvents?
63.5752 How do I calculate the organic HAP content of aluminum
recreational boat surface coatings?
63.5753 How do I calculate the combined organic HAP content of aluminum
wipedown solvents and aluminum recreational boat surface
coatings?
63.5755 How do I demonstrate compliance with the aluminum recreational
boat surface coating spray gun cleaning work practice
standards?
Methods for Determining Hazardous Air Pollutant Content
63.5758 How do I determine the organic HAP content of materials?
Notifications, Reports, and Records
63.5761 What notifications must I submit and when?
63.5764 What reports must I submit and when?
63.5767 What records must I keep?
63.5770 In what form and for how long must I keep my records?
Other Information You Need To Know
63.5773 What parts of the General Provisions apply to me?
[[Page 23]]
63.5776 Who implements and enforces this subpart?
Definitions
63.5779 What definitions apply to this subpart?
Table 1 to Subpart VVVV of Part 63--Compliance Dates for New and
Existing Boat Manufacturing Facilities
Table 2 to Subpart VVVV of Part 63--Alternative HAP Content Requirements
for Open Molding Resin and Gel Coat Operations
Table 3 to Subpart VVVV of Part 63--MACT Model Point Value Formulas for
Open Molding Operations
Table 4 to Subpart VVVV of Part 63--Operating Limits If Using an Add-on
Control Device for Open Molding Operations
Table 5 to Subpart VVVV of Part 63--Default Organic HAP Contents of
Solvents and Solvent Blends
Table 6 to Subpart VVVV of Part 63--Default Organic HAP Contents of
Petroleum Solvent Groups
Table 7 to Subpart VVVV of Part 63--Applicability and Timing of
Notifications
Table 8 to Subpart VVVV of Part 63--Applicability of General Provisions
(40 CFR Part 63, Subpart A) to Subpart VVVV
Subpart WWWW_National Emissions Standards for Hazardous Air Pollutants:
Reinforced Plastic Composites Production
What This Subpart Covers
63.5780 What is the purpose of this subpart?
63.5785 Am I subject to this subpart?
63.5787 What if I also manufacture fiberglass boats or boat parts?
63.5790 What parts of my plant does this subpart cover?
63.5795 How do I know if my reinforced plastic composites production
facility is a new affected source or an existing affected
source?
Calculating Organic HAP Emissions Factors for Open Molding and
Centrifugal Casting
63.5796 What are the organic HAP emissions factor equations in Table 1
to this subpart and how are they used in this subpart?
63.5797 How do I determine the organic HAP content of my resins and gel
coats?
63.5798 What if I want to use, or I manufacture, an application
technology (new or existing) whose organic HAP emissions
characteristics are not represented by the equations in Table
1 to this subpart?
63.5799 How do I calculate my facility's organic HAP emissions on a tpy
basis for purposes of determining which paragraphs of Sec.
63.5805 apply?
Compliance Dates and Standards
63.5800 When do I have to comply with this subpart?
63.5805 What standards must I meet to comply with this subpart?
Options for Meeting Standards
63.5810 What are my options for meeting the standards for open molding
and centrifugal casting operations at new and existing
sources?
63.5820 What are my options for meeting the standards for continuous
lamination/casting operations?
63.5830 What are my options for meeting the standards for pultrusion
operations subject to the 60 weight percent organic HAP
emissions reductions requirement?
General Compliance Requirements
63.5835 What are my general requirements for complying with this
subpart?
Testing and Initial Compliance Requirements
63.5840 By what date must I conduct a performance test or other initial
compliance demonstration?
63.5845 When must I conduct subsequent performance tests?
63.5850 How do I conduct performance tests, performance evaluations, and
design evaluations?
63.5855 What are my monitor installation and operation requirements?
63.5860 How do I demonstrate initial compliance with the standards?
Emissions Factor, Percent Reduction, and Capture Efficiency Calculation
Procedures for Continuous Lamination/Casting Operations
63.5865 What data must I generate to demonstrate compliance with the
standards for continuous lamination/casting operations?
63.5870 How do I calculate annual uncontrolled and controlled organic
HAP emissions from my wet-out area(s) and from my oven(s) for
continuous lamination/casting operations?
63.5875 How do I determine the capture efficiency of the enclosure on my
wet-out area and the capture efficiency of my oven(s) for
continuous lamination/casting operations?
63.5880 How do I determine how much neat resin plus is applied to the
line and how much neat gel coat plus is applied to the line
for continuous lamination/casting operations?
[[Page 24]]
63.5885 How do I calculate percent reduction to demonstrate compliance
for continuous lamination/casting operations?
63.5890 How do I calculate an organic HAP emissions factor to
demonstrate compliance for continuous lamination/casting
operations?
Continuous Compliance Requirements
63.5895 How do I monitor and collect data to demonstrate continuous
compliance?
63.5900 How do I demonstrate continuous compliance with the standards?
Notifications, Reports, and Records
63.5905 What notifications must I submit and when?
63.5910 What reports must I submit and when?
63.5915 What records must I keep?
63.5920 In what form and how long must I keep my records?
Other Requirements and Information
63.5925 What parts of the General Provisions apply to me?
63.5930 Who implements and enforces this subpart?
63.5935 What definitions apply to this subpart?
Table 1 to Subpart WWWW of Part 63--Equations To Calculate Organic HAP
Emissions Factors for Specific Open Molding and Centrifugal
Casting Process Streams
Table 2 to Subpart WWWW of Part 63--Compliance Dates for New and
Existing Reinforced Plastic Composites Facilities
Table 3 to Subpart WWWW of Part 63--Organic HAP Emissions
Limits for Existing Open Molding Sources, New Open Molding
Sources Emitting Less Than 100 TPY of HAP, and New and
Existing Centrifugal Casting and Continuous Lamination/Casting
Sources That Emit Less Than 100 TPY of HAP
Table 4 to Subpart WWWW of Part 63--Work Practice Standards
Table 5 to Subpart WWWW of Part 63--Alternative Organic HAP Emissions
Limits for Open Molding, Centrifugal Casting, and SMC
Manufacturing Operations Where the Standards are Based on a 95
Percent Reduction Requirement
Table 6 to Subpart WWWW of Part 63--Basic Requirements for Performance
Tests, Performance Evaluations, and Design Evaluations for New
and Existing Sources Using Add-On Control Devices
Table 7 to Subpart WWWW of Part 63--Options Allowing Use of the Same
Resin Across Different Operations That Use the Same Resin Type
Table 8 to Subpart WWWW of Part 63--Initial Compliance With Organic HAP
Emissions Limits
Table 9 to Subpart WWWW of Part 63--Initial Compliance With Work
Practice Standards.
Table 10 to Subpart WWWW of Part 63--Data Requirements for New and
Existing Continuous Lamination Lines and Continuous Casting
Lines Complying with a Percent Reduction Limit on a Per Line
Basis
Table 11 to Subpart WWWW of Part 63--Data Requirements for New and
Existing Continuous Lamination and Continuous Casting Lines
Complying with a Percent Reduction Limit or a Lbs/Ton Limit on
an Averaging Basis
Table 12 to Subpart WWWW of Part 63--Data Requirements for New and
Existing Continuous Lamination Lines and Continuous Casting
Lines Complying with a Lbs/Ton Organic HAP Emissions Limit on
a Per Line Basis
Table 13 to Subpart WWWW of Part 63--Applicability and Timing of
Notifications
Table 14 to Subpart WWWW of Part 63--Requirements for Reports
Table 15 to Subpart WWWW of Part 63--Applicability of General Provisions
(Subpart A) to Subpart WWWW of Part 63
Appendix A to Subpart WWWW of Part 63--Test Method for Determining Vapor
Suppressant Effectiveness
Subpart XXXX_National Emission Standards for Hazardous Air Pollutants:
Rubber Tire Manufacturing
What This Subpart Covers
63.5980 What is the purpose of this subpart?
63.5981 Am I subject to this subpart?
63.5982 What parts of my facility does this subpart cover?
63.5983 When do I have to comply with this subpart?
Emission Limits for Tire Production Affected Sources
63.5984 What emission limits must I meet for tire production affected
sources?
63.5985 What are my alternatives for meeting the emission limits for
tire production affected sources?
Emission Limits for Tire Cord Production Affected Sources
63.5986 What emission limits must I meet for tire cord production
affected sources?
63.5987 What are my alternatives for meeting the emission limits for
tire cord production affected sources?
[[Page 25]]
Emission Limitations for Puncture Sealant Application Affected Sources
63.5988 What emission limitations must I meet for puncture sealant
application affected sources?
63.5989 What are my alternatives for meeting the emission limitations
for puncture sealant application affected sources?
General Compliance Requirements
63.5990 What are my general requirements for complying with this
subpart?
General Testing and Initial Compliance Requirements
63.5991 By what date must I conduct an initial compliance demonstration
or performance test?
63.5992 When must I conduct subsequent performance tests?
63.5993 What performance tests and other procedures must I use?
Testing and Initial Compliance Requirements for Tire Production Affected
Sources
63.5994 How do I conduct tests and procedures for tire production
affected sources?
63.5995 What are my monitoring installation, operation, and maintenance
requirements?
63.5996 How do I demonstrate initial compliance with the emission limits
for tire production affected sources?
Testing and Initial Compliance Requirements for Tire Cord Production
Affected Sources
63.5997 How do I conduct tests and procedures for tire cord production
affected sources?
63.5998 What are my monitoring installation, operation, and maintenance
requirements?
63.5999 How do I demonstrate initial compliance with the emission limits
for tire cord production affected sources?
Testing and Initial Compliance Requirements for Puncture Sealant
Application Affected Sources
63.6000 How do I conduct tests and procedures for puncture sealant
application affected sources?
63.6001 What are my monitoring installation, operation, and maintenance
requirements?
63.6002 How do I demonstrate initial compliance with the emission limits
for puncture sealant application affected sources?
Continuous Compliance Requirements for Tire Production Affected Sources
63.6003 How do I monitor and collect data to demonstrate continuous
compliance with the emission limits for tire production
affected sources?
63.6004 How do I demonstrate continuous compliance with the emission
limits for tire production affected sources?
Continuous Compliance Requirements for Tire Cord Production Affected
Sources
63.6005 How do I monitor and collect data to demonstrate continuous
compliance with the emission limits for tire cord production
affected sources?
63.6006 How do I demonstrate continuous compliance with the emission
limits for tire cord production affected sources?
Continuous Compliance Requirements for Puncture Sealant Application
Affected Sources
63.6007 How do I monitor and collect data to demonstrate continuous
compliance with the emission limitations for puncture sealant
application affected sources?
63.6008 How do I demonstrate continuous compliance with the emission
limitations for puncture sealant application affected sources?
Notifications, Reports, and Records
63.6009 What notifications must I submit and when?
63.6010 What reports must I submit and when?
63.6011 What records must I keep?
63.6012 In what form and how long must I keep my records?
Other Requirements and Information
63.6013 What parts of the General Provisions apply to me?
63.6014 Who implements and enforces this subpart?
63.6015 What definitions apply to this subpart?
Table 1 to Subpart XXXX of Part 63--Emission Limits for Tire Production
Affected Sources
Table 2 to Subpart XXXX of Part 63--Emission Limits for Tire Cord
Production Affected Sources
Table 3 to Subpart XXXX of Part 63--Emission Limits for Puncture Sealant
Application Affected Sources
Table 4 to Subpart XXXX of Part 63--Operating Limits for Puncture
Sealant Application Control Devices
Table 5 to Subpart XXXX of Part 63--Requirements for Performance Tests
[[Page 26]]
Table 6 to Subpart XXXX of Part 63--Initial Compliance with the Emission
Limits for Tire Production Affected Sources
Table 7 to Subpart XXXX of Part 63--Initial Compliance with the Emission
Limits for Tire Cord Production Affected Sources
Table 8 to Subpart XXXX of Part 63--Initial Compliance with the Emission
Limits for Puncture Sealant Application Affected Sources
Table 9 to Subpart XXXX of Part 63--Minimum Data for Continuous
Compliance with the Emission Limits for Tire Production
Affected Sources
Table 10 to Subpart XXXX of Part 63--Continuous Compliance with the
Emission Limits for Tire Production Affected Sources
Table 11 to Subpart XXXX of Part 63--Minimum Data for Continuous
Compliance with the Emission Limits for Tire Cord Production
Affected Sources
Table 12 to Subpart XXXX of Part 63--Continuous Compliance with the
Emission Limits for Tire Cord Production Affected Sources
Table 13 to Subpart XXXX of Part 63--Minimum Data for Continuous
Compliance with the Emission Limitations for Puncture Sealant
Application Affected Sources
Table 14 to Subpart XXXX of Part 63--Continuous Compliance with the
Emission Limitations for Puncture Sealant Application Affected
Sources
Table 15 to Subpart XXXX of Part 63--Requirements for Reports
Table 16 to Subpart XXXX of Part 63--Selected Hazardous Air Pollutants
Table 17 to Subpart XXXX of Part 63--Applicability of General Provisions
to This Subpart XXXX
Subpart YYYY_National Emission Standards for Hazardous Air Pollutants
for Stationary Combustion Turbines
What This Subpart Covers
63.6080 What is the purpose of subpart YYYY?
63.6085 Am I subject to this subpart?
63.6090 What parts of my plant does this subpart cover?
63.6092 Are duct burners and waste heat recovery units covered by
subpart YYYY?
63.6095 When do I have to comply with this subpart?
Emission and Operating Limitations
63.6100 What emission and operating limitations must I meet?
General Compliance Requirements
63.6105 What are my general requirements for complying with this
subpart?
Testing and Initial Compliance Requirements
63.6110 By what date must I conduct the initial performance tests or
other initial compliance demonstrations?
63.6115 When must I conduct subsequent performance tests?
63.6120 What performance tests and other procedures must I use?
63.6125 What are my monitor installation, operation, and maintenance
requirements?
63.6130 How do I demonstrate initial compliance with the emission and
operating limitations?
Continuous Compliance Requirements
63.6135 How do I monitor and collect data to demonstrate continuous
compliance?
63.6140 How do I demonstrate continuous compliance with the emission and
operating limitations?
Notifications, Reports, and Records
63.6145 What notifications must I submit and when?
63.6150 What reports must I submit and when?
63.6155 What records must I keep?
63.6160 In what form and how long must I keep my records?
Other Requirements and Information
63.6165 What parts of the General Provisions apply to me?
63.6170 Who implements and enforces this subpart?
63.6175 What definitions apply to this subpart?
Table 1 to Subpart YYYY--Emission Limitations
Table 2 to Subpart YYYY--Operating Limitations
Table 3 to Subpart YYYY--Requirements for Performance Tests and Initial
Compliance Demonstrations
Table 4 to Subpart YYYY--Initial Compliance with Emission Limitations
Table 5 to Subpart YYYY--Continuous Compliance with Operating
Limitations
Table 6 to Subpart YYYY--Requirements for Reports
Table 7 to Subpart YYYY--Applicability of General Provisions to Subpart
YYYY
Authority: 42 U.S.C. 7401 et seq.
Source: 57 FR 61992, Dec. 29, 1992, unless otherwise noted.
[[Page 27]]
Subpart QQQ_National Emission Standards for Hazardous Air Pollutants for
Primary Copper Smelting
Source: 67 FR 40491, June 12, 2002, unless otherwise noted.
What This Subpart Covers
Sec. 63.1440 What is the purpose of this subpart?
This subpart establishes national emission standards for hazardous
air pollutants (NESHAP) for primary copper smelters. This subpart also
establishes requirements to demonstrate initial and continuous
compliance with all applicable emission limitations, work practice
standards, and operation and maintenance requirements in this subpart.
Sec. 63.1441 Am I subject to this subpart?
You are subject to this subpart if you own or operate a primary
copper smelter that is (or is part of) a major source of hazardous air
pollutant (HAP) emissions on the first compliance date that applies to
you, and your primary copper smelter uses batch copper converters as
defined in Sec. 63.1459. Your primary copper smelter is a major source
of HAP if it emits or has the potential to emit any single HAP at the
rate of 10 tons or more per year or any combination of HAP at a rate of
25 tons or more per year.
Sec. 63.1442 What parts of my plant does this subpart cover?
(a) This subpart applies to each new and existing affected source at
your primary copper smelter. The affected sources are each copper
concentrate dryer, each smelting furnace, each slag cleaning vessel,
each copper converter department, and the entire group of fugitive
emission sources, as defined in Sec. 63.1459.
(b) An affected source at your primary copper smelter is existing if
you commenced construction or reconstruction of the affected source
before April 20, 1998.
(c) An affected source at your primary copper smelter is new if you
commenced construction or reconstruction of the affected source on or
after April 20, 1998. An affected source is reconstructed if it meets
the definition of ``reconstruction'' in Sec. 63.2.
Sec. 63.1443 When do I have to comply with this subpart?
(a) If you have an existing affected source, you must comply with
each emission limitation, work practice standard, and operation and
maintenance requirement in this subpart that applies to you no later
than June 13, 2005.
(b) If you have a new affected source and its initial startup date
is on or before June 12, 2002, you must comply with each emission
limitation, work practice standard, and operation and maintenance
requirement in this subpart that applies to you by June 12, 2002.
(c) If you have a new affected source and its initial startup date
is after June 12, 2002, you must comply with each emission limitation,
work practice standard, and operation and maintenance requirement in
this subpart that applies to you upon initial startup.
(d) If your primary copper smelter is an area source that becomes a
major source of HAP, the compliance dates listed in paragraphs (d)(1)
and (2) of this section apply to you.
(1) Any portion of the existing primary copper smelter that is a new
affected source or a new reconstructed source must be in compliance with
this subpart upon startup.
(2) All other parts of the primary copper smelter must be in
compliance with this subpart no later than 3 years after it becomes a
major source.
(e) You must meet the notification and schedule requirements in
Sec. 63.1454. Several of these notifications must be submitted before
the compliance date for your affected source.
Emission Limitations and Work Practice Standards
Sec. 63.1444 What emissions limitations and work practice standards
must I meet for my copper concentrate dryers, smelting furnaces, slag
cleaning vessels, and copper converter departments?
(a) Copper concentrate dryers. For each copper concentrate dryer,
you must
[[Page 28]]
comply with the emission limitation in paragraph (a)(1) or (2) of this
section that applies to you.
(1) For each existing copper concentrate dryer, you must not cause
to be discharged to the atmosphere from the dryer vent any gases that
contain total particulate matter in excess of 50 milligrams per dry
standard cubic meter (mg/dscm) as measured using the test methods
specified in Sec. 63.1450(a).
(2) For each new copper concentrate dryer, you must not cause to be
discharged to the atmosphere from the dryer vent any gases that contain
total particulate matter in excess of 23 mg/dscm as measured using the
test methods specified in Sec. 63.1450(a).
(b) Smelting furnaces. For each smelting furnace, you must comply
with the emission limitations and work practice standards in paragraphs
(b)(1) and (2) of this section.
(1) For each smelting furnace, you must not cause to be discharged
to the atmosphere any process off-gas that contains nonsulfuric acid
particulate matter in excess of 6.2 mg/dscm as measured using the test
methods specified in Sec. 63.1450(b). Process off-gas from a smelting
furnace is generated when copper ore concentrates and fluxes are being
smelted to form molten copper matte and slag layers.
(2) For each smelting furnace, you must control the process fugitive
emissions released when tapping copper matte or slag from the smelting
furnace according to paragraphs (b)(2)(i) and (ii) of this section.
(i) At all times when copper matte or slag is tapped from the
smelting furnace, you must operate a capture system that collects the
gases and fumes released from the tapping port in use. The design and
placement of this capture system must be such that the tapping port
opening, launder, and receiving vessel (e.g., ladle, slag pot) are
positioned within the confines or influence of the capture system's
ventilation draft during those times when the copper matte or slag is
flowing from the tapping port opening.
(ii) You must not cause to be discharged to the atmosphere from the
capture system used to comply with paragraph (b)(2)(i) of this section
any gases that contain total particulate matter in excess of 23 mg/dscm
as measured using the test methods specified in Sec. 63.1450(a).
(c) Slag cleaning vessels. For each slag cleaning vessel, you must
comply with the emission limitations and work practice standards in
paragraphs (c)(1) through (3) of this section that apply to you.
(1) For each slag cleaning vessel, except as provided for in
paragraph (c)(2) of this section, you must not cause to be discharged to
the atmosphere any process off-gas that contains nonsulfuric acid
particulate matter in excess of 6.2 mg/dscm as measured using the test
methods specified in Sec. 63.1450(b).
(2) As an alternative to complying with the emission limit for
nonsulfuric acid particulate matter in paragraph (c)(1) of this section,
for each existing slag cleaning vessel you may choose to comply with the
emission limit for total particulate matter specified in this paragraph
(c)(2). You must not cause to be discharged to the atmosphere any
process off-gas that contains total particulate matter in excess of 46
mg/dscm as measured using the test methods specified in Sec.
63.1450(a).
(3) For each slag cleaning vessel, you must control process fugitive
emissions released when tapping copper matte or slag from the slag
cleaning vessel according to paragraphs (c)(3)(i) and (ii) of this
section.
(i) At all times when copper matte or slag is tapped from the slag
cleaning vessel, you must operate a capture system that collects the
gases and fumes released from the tapping port in use. The design and
placement of this capture system must be such that the tapping port
opening, launder, and receiving vessel (e.g., ladle, slag pot) are
positioned within the confines or influence of the capture system's
ventilation draft during those times when the copper matte or slag is
flowing from the tapping port opening.
(ii) You must not cause to be discharged to the atmosphere from the
capture system used to comply with paragraph (c)(3)(i) of this section
any gases that contain total particulate matter in excess of 23 mg/dscm
as measured using the test methods specified in Sec. 63.1450(a).
[[Page 29]]
(d) Existing copper converter departments. For each existing copper
converter department, you must comply with the emission limitations and
work practice standards in paragraphs (d)(1) through (6) of this section
that apply to you.
(1) You must operate a capture system that collects the process off
gas vented from each batch copper converter. At all times when one or
more batch copper converters are blowing, you must operate the capture
system according to the written operation and maintenance plan that has
been prepared according to the requirements in Sec. 63.1447(b).
(2) If your copper converter department uses Pierce-Smith
converters, the capture system design must include use of a primary hood
that covers the entire mouth of the converter vessel when the copper
converter is positioned for blowing. Additional hoods (e.g., secondary
hoods) or other capture devices must be included in the capture system
design as needed to achieve the opacity limit in paragraph (d)(4) of
this section. The capture system design may use multiple intake and duct
segments through which the ventilation rates are controlled
independently of each other, and individual duct segments may be
connected to separate control devices.
(3) If your copper converter department uses Hoboken converters, the
capture system must collect all process off-gas vented during blowing
through the side-flue intake on each converter vessel.
(4) You must operate the capture system such that any visible
emissions exiting the roof monitors or roof exhaust fans on the building
housing the copper converter department meet the opacity limit as
specified in paragraphs (d)(4)(i) and (ii) of this section.
(i) The opacity of any visible emissions exiting the roof monitors
or roof exhaust fans on the building housing the copper converter
department must not exceed 4 percent as determined by a performance test
conducted according to Sec. 63.1450(c).
(ii) The opacity limit in paragraph (d)(4)(i) of this section
applies only at those times when a performance test is conducted
according to Sec. 63.1450(c). The requirements for compliance with
opacity and visible emission standards specified in Sec. 63.6(h) do not
apply to this opacity limit.
(5) You must not cause to be discharged to the atmosphere from any
Pierce-Smith converter primary hood capture system or Hoboken converter
side-flue intake capture system any process off-gas that contains
nonsulfuric acid particulate matter in excess of 6.2 mg/dscm as measured
using the test methods specified in Sec. 63.1450(b).
(6) You must not cause to be discharged to the atmosphere from any
secondary capture system any gases that contain total particulate matter
in excess of 23 mg/dscm as measured using the test methods specified in
Sec. 63.1450(a).
(e) New copper converter departments. For each new copper converter
department for which construction commenced on or after April 20, 1998,
the use of batch copper converters is prohibited.
(f) Baghouses. For each baghouse applied to meet any total
particulate matter emission limit in paragraphs (a) through (d) of this
section, you must operate the baghouse such that the bag leak detection
system does not alarm for more than 5 percent of the total operating
time in any semiannual reporting period.
(g) Venturi wet scrubbers. For each venturi wet scrubber applied to
meet any total particulate matter emission limit in paragraphs (a)
through (d) of this section, you must maintain the hourly average
pressure drop and scrubber water flow rate at or above the minimum
levels established during the initial or subsequent performance test.
(h) Other control devices. For each control device other than a
baghouse or venturi wet scrubber applied to meet any total particulate
matter emission limit in paragraphs (a) through (d) of this section, you
must operate the control device as specified in paragraphs (h)(1) and
(2) of this section.
(1) You must select one or more operating parameters, as appropriate
for the control device design, that can be used as representative and
reliable indicators of the control device operation.
[[Page 30]]
(2) You must maintain the hourly average value for each of the
selected parameters at or above the minimum level or at or below the
maximum level, as appropriate for the selected parameter, established
during the initial or subsequent performance test.
Sec. 63.1445 What work practice standards must I meet for my fugitive
dust sources?
(a) You must control particulate matter emissions from fugitive dust
sources at your primary copper smelter by operating according to a
written fugitive dust control plan that has been approved by the
designated authority. For the purpose of complying with this paragraph
(a) you may use an existing fugitive dust control plan provided that the
plan complies with the requirements of this section. A fugitive dust
control plan is considered to be approved if the plan has been
incorporated in your applicable State implementation plan, and the
document addresses the fugitive dust sources specified in paragraph (b)
of this section and includes the information specified in paragraph (c)
of this section.
(b) Your fugitive dust control plan must address each of the
fugitive dust emission sources listed in paragraphs (b)(1) through (6)
of this section that are located at your primary copper smelter.
(1) On-site roadways used by trucks or other motor vehicles (e.g.,
front-end loaders) when transporting bulk quantities of fugitive dust
materials. Paved roads and parking areas that are not used by these
vehicles do not need to be included in the plan (e.g., employee and
visitor parking lots).
(2) Unloading of fugitive dust materials from trucks or railcars.
(3) Outdoor piles used for storage of fugitive dust materials.
(4) Bedding areas used for blending copper concentrate and other
feed constituents.
(5) Each transfer point in conveying systems used to transport
fugitive dust materials. These points include, but are not limited to,
transfer of material from one conveyor belt to another and transfer of
material to a hopper or bin.
(6) Other site-specific sources of fugitive dust emissions that the
Administrator or delegated permitting authority designate to be included
in your fugitive dust control plan.
(c) Your fugitive dust control plan must describe the control
measures you use to control fugitive dust emissions from each source
addressed in the plan, as applicable and appropriate for your site
conditions. Examples of control measures include, but are not limited
to, locating the source inside a building or other enclosure, installing
and operating a local hood capture system over the source and venting
the captured gas stream to a control device, placing material stockpiles
below grade, installing wind screens or wind fences around the source,
spraying water on the source as weather conditions require, applying
appropriate dust suppression agents on the source, or combinations of
these control measures.
(d) The requirement for you to operate according to a written
fugitive dust control plan must be incorporated in your operating permit
that is issued by the designated permitting authority under part 70 of
this chapter. A copy of your fugitive dust control plan must be sent to
the designated permitting authority on or before the compliance date for
your primary copper smelter, as specified in Sec. 63.1443.
Sec. 63.1446 What alternative emission limitation may I meet for my
combined gas streams?
(a) For situations where you combine gas streams from two or more
affected sources for discharge to the atmosphere through a single vent,
you may choose to meet the requirements in paragraph (b) of this section
as an alternative to complying with the individual total particulate
matter emission limits specified in Sec. 63.1444 that apply to you.
This alternative emission limit for a combined gas stream may be used
for any combination of the affected source gas steams specified in
paragraphs (a)(1) through (5) of this section.
(1) Gas stream discharged from a copper concentrate dryer vent that
would otherwise be subject to Sec. 63.1444(a)(1) or (2);
(2) Gas stream discharged from a smelting furnace capture system
that
[[Page 31]]
would otherwise be subject to Sec. 63.1444(b)(2)(ii);
(3) Process off-gas stream discharged from a slag cleaning vessel
that would otherwise be subject to Sec. 63.1444(c)(2);
(4) Gas stream discharged from a slag cleaning vessel capture system
that would otherwise be subject to Sec. 63.1444(c)(3)(ii); and
(5) Gas stream discharged from a batch copper converter secondary
capture system that would otherwise be subject to Sec. 63.1444(d)(5).
(b) You must meet the requirements specified in paragraphs (b)(1)
and (2) of this section for the combined gas stream discharged through a
single vent.
(1) For each combined gas stream discharged through a single vent,
you must not cause to be discharged to the atmosphere any gases that
contain total particulate matter in excess of the emission limit
calculated using the procedure in paragraph (b)(2) of this section and
measured using the test methods specified in Sec. 63.1450(a).
(2) You must calculate the alternative total particulate matter
emission limit for your combined gas stream using Equation 1 of this
section. The volumetric flow rate value for each of the individual
affected source gas streams that you use for Equation 1 (i.e., the flow
rate of the gas stream discharged from the affected source but before
this gas stream is combined with the other gas streams) is to be the
average of the volumetric flow rates measured using the test method
specified in Sec. 63.1450(a)(1)(ii):
[GRAPHIC] [TIFF OMITTED] TR12JN02.025
Where
EAlt = Alternative total particulate matter emission limit
for the combined gas stream discharged to atmosphere through a single
vent (mg/dscm);
Ed = Total particulate matter emission limit applicable to
copper concentrate dryer as specified in Sec. 63.1444(a)(1) or (2) (mg/
dscm);
Qd = Copper concentrate dryer exhaust gas stream volumetric
flow rate before being combined with other gas streams (dscm);
Esv = Total particulate matter emission limit for smelting
furnace capture system as specified in Sec. 63.1444(b)(2)(ii) (mg/
dscm);
Qsv = Smelting furnace capture system exhaust gas stream
volumetric flow rate before being combined with other gas streams
(dscm);
Escvp = Total particulate matter emission limit for slag
cleaning vessel process off-gas as specified in Sec. 63.1444(c)(2) (mg/
dscm);
Qscvp = Slag cleaning vessel process off-gas volumetric flow
rate before being combined with other gas streams (dscm);
Escvf = Total particulate matter emission limit for slag
cleaning vessel capture system as specified in Sec. 63.1444(c)(3)(ii)
(mg/dscm);
Qscvf = Slag cleaning vessel capture system exhaust gas
stream volumetric flow rate before being combined with other gas streams
(dscm);
Ecc = Total particulate emission limit for the batch copper
converter secondary capture system as specified in Sec. 63.1544(d)(5)
(mg/dscm); and
Qcc = Batch copper converter capture system exhaust gas
stream volumetric flow rate before being combined with other gas streams
(dscm).
(c) For each baghouse applied to meet any total particulate matter
emission limit in paragraph (b) of this section, you must operate the
baghouse such that the bag leak detection system does not alarm for more
than 5 percent of the total operating time in any semiannual reporting
period.
(d) For each venturi wet scrubber applied to meet any total
particulate matter emission limit in paragraph (b) of this section, you
must maintain the hourly average pressure drop and scrubber water flow
rate at or above the minimum levels established during the initial or
subsequent performance test.
(e) For each control device other than a baghouse or venturi wet
scrubber applied to meet any total particulate matter emission limit in
paragraph (b) of this section, you must operate the control device as
specified in paragraphs (e)(1) and (2) of this section.
[[Page 32]]
(1) You must select one or more operating parameters, as appropriate
for the control device design, that can be used as representative and
reliable indicators of the control device operation.
(2) You must maintain the hourly average value for each of the
selected parameters at or above the minimum level or at or below the
maximum level, as appropriate for the selected parameter, established
during the initial or subsequent performance test.
Operation and Maintenance Requirements
Sec. 63.1447 What are my operation and maintenance requirements?
(a) As required by Sec. 63.6(e)(1)(i), you must always operate and
maintain your affected source, including air pollution control and
monitoring equipment, in a manner consistent with good air pollution
control practices for minimizing emissions at least to the levels
required by this subpart.
(b) You must prepare and operate at all times according to a written
operation and maintenance plan for each capture system and control
device subject to standards in Sec. 63.1444 or Sec. 63.1446. The plan
must address the requirements in paragraphs (b)(1) through (3) of this
section as applicable to the capture system or control device.
(1) Preventative maintenance. You must perform preventative
maintenance for each capture system and control device according to
written procedures specified in your operation and maintenance plan. The
procedures must include a preventative maintenance schedule that is
consistent with the manufacturer's instructions for routine and long-
term maintenance.
(2) Capture system inspections. You must conduct monthly inspections
of the equipment components of the capture system that can affect the
performance of the system to collect the gases and fumes emitted from
the affected source (e.g., hoods, exposed ductwork, dampers, fans)
according to written procedures specified in your operation and
maintenance plan. The inspection procedure must include the requirements
in paragraphs (b)(2)(i) through (iii) of this section as applicable to
the capture system or control device.
(i) Observations of the physical appearance of the equipment to
confirm the physical integrity of the equipment (e.g., verify by visual
inspection no holes in ductwork or hoods, no flow constrictions caused
by dents, or accumulated dust in ductwork).
(ii) Inspection, and if necessary testing, of equipment components
to confirm that the component is operating as intended (e.g., verify by
appropriate measures that flow or pressure sensors, damper plates,
automated damper switches and motors are operating according to
manufacture or engineering design specifications).
(iii) In the event that a defective or damaged component is detected
during an inspection, you must initiate corrective action according to
written procedures specified in your operation and maintenance plan to
correct the defect or deficiency as soon as practicable.
(3) Copper converter department capture system operating limits. You
must establish, according to the requirements in paragraph (b)(3)(i)
through (iii) of this section, operating limits for the capture system
that are representative and reliable indicators of the performance of
capture system when it is used to collect the process off-gas vented
from batch copper converters during blowing.
(i) Select operating limit parameters appropriate for the capture
system design that are representative and reliable indicators of the
performance of the capture system when it is used to collect the process
off-gas vented from batch copper converters during blowing. At a
minimum, you must use appropriate operating limit parameters that
indicate the level of the ventilation draft and the damper position
settings for the capture system when operating to collect the process
off-gas from the batch copper converters during blowing. Appropriate
operating limit parameters for ventilation draft include, but are not
limited to, volumetric flow rate through each separately ducted hood,
total volumetric flow rate at the inlet to control device to which the
capture system is vented, fan motor amperage, or static pressure.
[[Page 33]]
Any parameter for damper position setting may be used that indicates the
duct damper position relative to the fully open setting.
(ii) For each operating limit parameter selected in paragraph
(b)(3)(i) of this section, designate the value or setting for the
parameter at which the capture system operates during batch copper
converter blowing. If your blister copper production operations allow
for more than one batch copper converter to be operating simultaneously
in the blowing mode, designate the value or setting for the parameter at
which the capture system operates during each possible batch copper
converter blowing configuration that you may operate at your smelter
(i.e., the operating limits with one converter blowing, with two
converters blowing, with three converters blowing, as applicable to your
smelter).
(iii) Include documentation in the plan to support your selection of
the operating limits established for the capture system. This
documentation must include a description of the capture system design, a
description of the capture system operation during blister copper
production, a description of each selected operating limit parameter, a
rationale for why you chose the parameter, a description of the method
used to monitor the parameter according to the requirements in Sec.
63.1452(a), and the data used to set the value or setting for the
parameter for each of your batch copper converter configurations.
(4) Baghouse leak detection corrective actions. In the event a bag
leak detection system alarm is triggered, you must initiate corrective
action according to written procedures specified in your operation and
maintenance plan to determine the cause of the alarm within 1 hour of
the alarm, initiate corrective action to correct the cause of the
problem within 24 hours of the alarm, and complete the corrective action
as soon as practicable. Corrective actions may include, but are not
limited to, the activities listed in paragraphs (b)(3)(i) through (vi)
of this section.
(i) Inspecting the baghouse for air leaks, torn or broken bags or
filter media, or any other condition that may cause an increase in
emissions.
(ii) Sealing off defective bags or filter media.
(iii) Replacing defective bags or filter media or otherwise
repairing the control device.
(iv) Sealing off a defective baghouse compartment.
(v) Cleaning the bag leak detection system probe, or otherwise
repair the bag leak detection system.
(vi) Shutting down the process producing the particulate emissions.
General Compliance Requirements
Sec. 63.1448 What are my general requirements for complying with this
subpart?
(a) You must be in compliance with the emission limitations, work
practice standards, and operation and maintenance requirements in this
subpart at all times, except during periods of startup, shutdown, and
malfunction as defined in Sec. 63.2.
(b) During the period between the compliance date specified for your
affected source in Sec. 63.1443, and the date upon which continuous
monitoring systems have been installed and certified and any applicable
operating limits have been set, you must maintain a log detailing the
operation and maintenance of the process and emissions control
equipment.
(c) You must develop a written startup, shutdown, and malfunction
plan according to the provisions in Sec. 63.6(e)(3).
[57 FR 61992, Dec. 29, 1992, as amended at 71 FR 20461, Apr. 20, 2006]
Initial Compliance Requirements
Sec. 63.1449 By what dates must I conduct performance tests or other
initial compliance demonstrations?
(a) As required in Sec. 63.7(a)(2), you must conduct a performance
test within 180 calendar days of the compliance date that is specified
in Sec. 63.1443 for your affected source to demonstrate initial
compliance with each emission and opacity limit in Sec. 63.1443 and
Sec. 63.1446 that applies to you.
(b) For each work practice standard and operation and maintenance
requirement that applies to you where initial compliance is not
demonstrated
[[Page 34]]
using a performance test or opacity observation, you must demonstrate
initial compliance within 30 calendar days after the compliance date
that is specified for your affected source in Sec. 63.1443.
Sec. 63.1450 What test methods and other procedures must I use to
demonstrate initial compliance with the emission limitations?
(a) Total particulate matter emission limits. You must conduct each
performance test to determine compliance with the total particulate
matter emission limits in Sec. 63.1444 or Sec. 63.1446 that apply to
you according to the requirements for representative test conditions
specified in Sec. 63.7(e)(1) and using the test methods and procedures
in paragraphs (a)(1) through (5) of this section.
(1) Determine the concentration of total particulate matter
according to the test methods in appendix A to part 60 of this chapter
as specified in paragraphs (a)(1)(i) through (iii) of this section.
(i) Method 1 to select sampling port locations and the number of
traverse points. Sampling ports must be located at the outlet of the
control device and prior to any releases to the atmosphere.
(ii) Method 2, 2F, or 2G to determine the volumetric flow rate of
the stack gas.
(iii) Method 3, 3A, or 3B to determine the dry molecular weight of
the stack gas.
(iv) Method 4 to determine the moisture content of the stack gas.
(v) Method 5, 5D, or 17, as applicable, to determine the
concentration of total particulate matter. You can also use ASTM D4536-
96 incorporated by reference in Sec. 63.14 as an alternative to the
sampling equipment and operating procedures in Method 5 or 17 when
testing a positive pressure baghouse, but you must use the sample
traverse location and number of sampling points described in Method 5D.
(2) As an alternative to using the applicable method specified in
paragraph (a)(1)(v) of this section, you may determine total particulate
matter emissions from the control device using Method 29 in appendix A
of part 60 of this chapter provided that you follow the procedures and
precautions prescribed in Method 29. If the control device is a positive
pressure baghouse, you must also follow the measurement procedure
specified in sections 4.1 through 4.3 of Method 5D.
(3) You must conduct three separate test runs for each performance
test. Each test run must have a minimum sampling time of 60 minutes and
a minimum sampling volume of 0.85 dscm. For the purpose of determining
compliance with the applicable total particulate matter emission limit,
the arithmetic mean of the results for the three separate test runs is
used.
(4) For a venturi wet scrubber applied to emissions from an affected
source and subject to operating limits in Sec. 63.1444(g) or Sec.
63.1446(d) for pressure drop and scrubber water flow rate, you must
establish site-specific operating limits according to the procedures in
paragraph (a)(4)(i) and (ii) of this section.
(i) Using the continuous parameter monitoring system (CPMS) required
in Sec. 63.1452, measure and record the pressure drop and scrubber
water flow rate during each run of the particulate matter performance
test.
(ii) Compute and record the hourly average pressure drop and
scrubber water flow rate for each individual test run. Your operating
limits are the lowest average pressure drop and scrubber water flow rate
value in any of the three runs that meet the applicable emission limit.
(5) For a control device other than a baghouse or venturi wet
scrubber applied to emissions from an affected source and subject to
site-specific operating limit(s) in Sec. 63.1444(h) or Sec. 63.1446(e)
for appropriate, site-specific operating parameters that are
representative and reliable indicators of the control device
performance, you must establish a site-specific operating limit(s)
according to the procedures in paragraph (a)(5)(i) through (iv) of this
section.
(i) Select one or more operating parameters, as appropriate for the
control device design, that can be used as representative and reliable
indicators of the control device operation.
[[Page 35]]
(ii) Using the CPMS required in Sec. 63.1452, measure and record
the selected operating parameters for the control device during each run
of the total particulate matter performance test.
(iii) Compute and record the hourly average value for each of the
selected operating parameters for each individual test run. Your
operating limits are the lowest value or the highest value, as
appropriate for the selected operating parameter, measured in any of the
three runs that meet the applicable emission limit.
(iv) You must prepare written documentation to support your
selection of the operating parameters used for the control device. This
documentation must include a description of each selected parameter, a
rationale for why you chose the parameter, a description of the method
used to monitor the parameter, and the data recorded during the
performance test and used to set the operating limit(s).
(b) Nonsulfuric acid particulate matter emission limits. You must
conduct each performance test to determine compliance with the
nonsulfuric acid particulate matter emission limits in Sec. 63.1444
that apply to you according to the requirements for representative test
conditions specified in Sec. 63.7(e)(1) and using the test methods and
procedures in paragraphs (b)(1) and (2) of this section.
(1) Determine the concentration of nonsulfuric acid particulate
matter according to the test methods in appendix A to part 60 of this
chapter as specified in paragraphs (b)(1)(i) through (v) of this
section.
(i) Method 1 to select sampling port locations and the number of
traverse points. Sampling ports must be located at the outlet of the
control device and prior to any releases to the atmosphere.
(ii) Method 2, 2F, or 2G to determine the volumetric flow rate of
the stack gas.
(iii) Method 3, 3A, or 3B to determine the dry molecular weight of
the stack gas.
(iv) Method 4 to determine the moisture content of the stack gas.
(v) Method 5B to determine the nonsulfuric acid particulate matter
emissions.
(2) You must conduct three separate test runs for each performance
test. Each test run must have a minimum sampling time of 240 minutes and
a minimum sampling volume of 3.4 dscm. For the purpose of determining
compliance with the nonsulfuric acid particulate matter emission limit,
the arithmetic mean of the results for the three separate test runs is
used.
(c) Copper converter department capture system opacity limit. You
must conduct each performance test to determine compliance with the
opacity limit in Sec. 63.1444 using the test methods and procedures in
paragraphs (c)(1) through (9) of this section.
(1) You must conduct the performance test during the period when the
primary copper smelter is operating under conditions representative of
the smelter's normal blister copper production rate. You may not conduct
a performance test during periods of startup, shutdown, or malfunction.
Before conducting the performance test, you must prepare a written test
plan specifying the copper production conditions to be maintained
throughout the opacity observation period and including a copy of the
written documentation you have prepared according to paragraph (a)(3) of
this section to support the established operating limits for the copper
converter department capture system. You must submit a copy of the test
plan for review and approval by the Administrator or delegated
authority. During the observation period, you must collect appropriate
process information and copper converter department capture system
operating information to prepare documentation sufficient to verify that
all opacity observations were made during the copper production and
capture system operating conditions specified in the approved test plan.
(2) You must notify the Administrator or delegated authority before
conducting the opacity observations to allow the Administrator or
delegated authority the opportunity to have authorized representatives
attend the test. Written notification of the location and scheduled date
for conducting
[[Page 36]]
the opacity observations must be received by the Administrator on or
before 30 calendar days before this scheduled date.
(3) You must gather the data needed for determining compliance with
the opacity limit using qualified visible emission observers and process
monitors as described in paragraphs (c)(3)(i) and (ii) of this section.
(i) Opacity observations must be performed by a sufficient number of
qualified visible emission observers to obtain two complete concurrent
sets of opacity readings for the required observation period. Each
visible emission observer must be certified as a qualified observer by
the procedure specified in section 3 of Method 9 in appendix A of part
60 of this chapter. The entire set of readings during the required
observation period does not need to be made by the same two observers.
More than two observers may be used to allow for substitutions and
provide for observer rest breaks. The owner or operator must obtain
proof of current visible emission reading certification for each
observer.
(ii) A person (or persons) familiar with the copper production
operations conducted at the smelter must serve as the indoor process
monitor. The indoor process monitor is stationed at a location inside
the building housing the batch copper converters such that he or she can
visually observe and record operations that occur in the batch copper
converter aisle during the times that the visible emission observers are
making opacity readings. More than one indoor process monitor may be
used to allow for substitutions and provide for rest breaks.
(4) You must make all opacity observations using Method 9 in
appendix A to part 60 of this chapter and following the procedures
described in paragraphs (c)(4)(i) and (ii) of this section.
(i) Each visible emission observer must make his or her readings at
a position from the outside of the building that houses the copper
converter department such that the observer's line-of-sight is
approximately perpendicular to the longer axis of the converter
building, and the observer has an unobstructed view of the building roof
monitor sections or roof exhaust fan outlets that are positioned over
each of the batch copper converters inside the building. Opacity
readings can only be made during those times when the observer's
position meets the sun orientation and other conditions specified in
section 2.1 of Method 9.
(ii) At 15-second intervals, each visible emission observer views
the building roof monitor sections or roof exhaust fan outlets that are
positioned over each of the batch copper converters inside the building
and reads the opacity of the visible plumes. If no plume is visible, the
observer records zero as the opacity value for the 15-second interval.
In situations when it is possible for an observer to distinguish two or
more visible emission plumes from the building roof monitor sections or
roof exhaust fan outlets, the observer must identify, to the extent
feasible, the plume having the highest opacity and record his or her
opacity reading for that plume as the opacity value for the 15-second
interval.
(5) You must make opacity observations for a period of sufficient
duration to obtain a minimum of 120 1-minute intervals during which at
least one copper converter is blowing and no interferences have occurred
from other copper production events, as specified in paragraph (c)(7) of
this section, which generate visible emissions inside the building that
potentially can interfere with the visible emissions from the converter
capture systems as seen by the outside observers. To obtain the required
number of 1-minute intervals, the observation period may be divided into
two or more segments performed on the same day or on different days if
conditions prevent the required number of opacity readings from being
obtained during one continuous time period. Examples of these conditions
include, but are not limited to, changes in the sun's orientation
relative to visible emission observers' positions such that the Method 9
conditions are no longer met or an unexpected thunder storm. If the
total observation period is divided into two or more segments, all
opacity observations must be made during the same set of copper
production conditions described in your approved test plan as required
by paragraph (c)(1) of this section.
[[Page 37]]
(6) You must gather indoor process information during all times that
the visible emission observers are making opacity readings outside the
building housing the copper converter department. The indoor process
monitor must continually observe the operations occurring in the copper
converter department and prepare a written record of his or her
observations using the procedure specified in paragraphs (c)(6)(i)
through (iv) of this section.
(i) At the beginning of each observation period or segment, the
clock time setting on the watch or clock to be used by the indoor
process monitor must be synchronized with the clock time settings for
the timepieces to be used by the outdoor opacity observers.
(ii) During each period or segment when opacity readings are being
made by the visible emission observers, the indoor process monitor must
continuously observe the operations occurring in the copper converter
department and record his or her observations in a log book, on data
sheets, or other type of permanent written format.
(iii) When a batch copper converter is blowing, a record must be
prepared for the converter that includes, but is not limited to, the
clock times for when blowing begins and when blowing ends and the
converter blowing rate. This information may be recorded by the indoor
process monitor or by a separate, automated computer data system.
(iv) The process monitor must record each event other than converter
blowing that occurs in or nearby the converter aisle that he or she
observes to generate visible emissions inside the building. The recorded
entry for each event must include, but is not limited to, a description
of the event and the clock times when the event begins and when the
event ends.
(7) You must prepare a summary of the data for the entire
observation period using the information recorded during the observation
period by the outdoor visible emission observers and the indoor process
monitor and the procedure specified in paragraphs (c)(7)(i) through (iv)
of this section.
(i) Using the field data sheets, identify the 1-minute clock times
for which a total of eight opacity readings were made and recorded by
both observers at 15-second intervals according to the test procedures
(i.e., a total of four opacity values have been recorded for the 1-
minute interval by each of the two observers). Calculate the average of
the eight 15-second interval readings recorded on the field data sheets
by the two observers during the clock time minute interval (add the four
consecutive 15-second interval opacity readings made by Observer A
during the specified clock time minute, plus the four consecutive 15-
second interval opacity readings made by Observer B during the same
clock time minute, and divide the resulting total by eight). Record the
clock time and the opacity average for the 1-minute interval on a data
summary sheet. Figure 1 of this subpart shows an example of the format
for the data summary sheet you may use, but are not required to use.
(ii) Using the data summary sheets prepared according to paragraph
(c)(7)(i) of this section and the process information recorded according
to paragraph (c)(6)(iii) of this section, identify those 1-minute
intervals for which at least one of the batch copper converters was
blowing.
(iii) Using the data summary sheets prepared according to paragraph
(c)(7)(ii) of this section and the process information recorded
according to paragraph (c)(6)(iv) of this section, identify the 1-minute
intervals during which at least one copper converter was blowing but
none of the interference events listed in paragraphs (c)(7)(iii)(A)
through (F) of this section occurred. Other ancillary activities not
listed but conducted in or adjacent to the converter aisle during the
opacity observations are not considered to be interference events (e.g.,
converter aisle cleaning, placement of smoking ladles or skulls on the
converter aisle floor).
(A) Charging of copper matte, reverts, or other materials to a batch
copper converter;
(B) Skimming slag or other molten materials from a batch copper
converter;
(C) Pouring of blister copper or other molten materials from a batch
copper converter;
[[Page 38]]
(D) Return of slag or other molten materials to the flash smelting
furnace or slag cleaning vessel;
(E) Roll-out or roll-in of the batch copper converter; or
(F) Smoke and fumes generated inside the converter building by
operation of the smelting furnace, the slag cleaning vessel (if used),
anode refining and casting processes that drift into the copper
converter department.
(iv) Using the data summary sheets prepared according to paragraph
(c)(7)(iii) of this section, up to five 1-minute intervals following an
interference event may be eliminated from data used for the compliance
determination calculation specified in paragraph (c)(8) of this section
by applying a time delay factor. The time delay factor must be a
constant number of minutes not to exceed 5 minutes that is added to the
clock time recorded when cessation of the interference event occurs. The
same time delay factor must be used for all interference events (i.e., a
constant time delay factor for the smelter of 1 minute, 2 minutes, 3
minutes, 4 minutes, or 5 minutes). The number of minutes to be used for
the time delay factor is determined based on the site-specific equipment
and converter building configuration. An explanation of the rationale
for selecting the value used for the time delay factor must be prepared
and included in the test report.
(8) You must use the data summary prepared in paragraph (c)(7) of
this section to calculate the average opacity value for a minimum of 120
1-minute intervals during which at least one copper converter was
blowing with no interference events as determined according to
paragraphs (c)(7)(iii) and (iv) of this section. Average opacity is
calculated using Equation 1 of this section:
[GRAPHIC] [TIFF OMITTED] TR12JN02.026
Where
VEave = Average opacity to be used for compliance
determination (percent);
n = Total number of 1-minute intervals during which at least one copper
converter was blowing with no interference events as determined
according to paragraphs (c)(7)(iii) and (iv) of this section (at least
120 1-minute intervals);
i = 1-minute interval ``i'' during which at least one copper converter
was blowing with no interference events as determined according to
paragraphs (c)(7)(iii) and (iv) of this section; and
VEi = Average opacity value calculated for the eight opacity
readings recorded during 1-minute interval ``i'' (percent).
(9) You must certify that the copper converter department capture
system operated during the performance test at the operating limits
established in your capture system operation and maintenance plan using
the procedure specified in paragraphs (c)(9)(i) through (iv) of this
section.
(i) Concurrent with all opacity observations, measure and record
values for each of the operating limit parameters in your capture system
operation and maintenance plan according to the monitoring requirements
specified in Sec. 63.1452(a).
(ii) For any dampers that are manually set and remain in the same
position at all times the capture system is operating, the damper
position must be visually checked and recorded at the beginning and end
of each opacity observation period segment.
(iii) Review the recorded monitoring data. Identify and explain any
times during batch copper converter blowing when the capture system
operated outside the applicable operating limits.
(iv) Certify in your performance test report that during all
observation period segments, the copper converter department capture
system was operating at the values or settings established in your
capture system operation and maintenance plan.
Sec. 63.1451 How do I demonstrate initial compliance with the emission
limitations, work practice standards, and operation and maintenance
requirements that apply to me?
(a) Total particulate matter emission limits. For each copper
concentrate dryer, smelting furnace, slag cleaning vessel, and copper
converter department subject to a total particulate matter emission
limits in Sec. 63.1444 or Sec. 63.1446 that applies to you, you have
demonstrated initial compliance if you meet both of the conditions in
paragraphs (a)(1) and (2) of this section.
[[Page 39]]
(1) The average concentration of total particulate matter from a
control device applied to emissions from the affected source, measured
according to the performance test procedures in Sec. 63.1450(a), did
not exceed the applicable emission limit.
(2) You have submitted a notification of compliance status according
to the requirements in Sec. 63.1454(e).
(b) Nonsulfuric acid particulate matter emissions limits. For each
smelting furnace, slag cleaning vessel, and copper converter departments
subject to the nonsulfuric acid particulate matter emissions limit in
Sec. 63.1444 as applies to you, you have demonstrated initial
compliance if you meet both of the conditions in paragraphs (b)(1) and
(2) of this section.
(1) The average concentration of nonsulfuric acid particulate matter
in the process off-gas discharged from the affected source, measured
according to the performance test procedures in Sec. 63.1450(b), did
not exceed 6.2 mg/dscm.
(2) You have submitted a notification of compliance status according
to the requirements in Sec. 63.1454(e).
(c) For each existing copper converter department subject to the
opacity limit in Sec. 63.1444, you have demonstrated initial compliance
if you meet both of the conditions in paragraphs (c)(1) and (2) of this
section.
(1) The opacity of visible emissions exiting the roof monitors or
roof exhaust fans on the building housing the copper converter
department measured according to the performance test procedures in
Sec. 63.1450(c), did not exceed 4 percent opacity.
(2) You have submitted a notification of compliance status according
to the requirements in Sec. 63.1454(e).
(d) Copper converter department capture systems. You have
demonstrated initial compliance of the copper converter department
capture system if you meet all of the conditions in paragraphs (d)(1)
through (4) of this section.
(1) Prepared the capture system operation and maintenance plan
according to the requirements of paragraph (a) of this section;
(2) Conducted an initial performance test according to the
procedures of Sec. 63.1450(c) demonstrating the opacity of any visible
emissions exiting the roof monitors or roof exhaust fans on the building
housing the copper converter department does not exceed 4 percent
opacity;
(3) Included in your notification of compliance status a copy of
your written capture system operation and maintenance plan and have
certified in your notification of compliance status that you will
operate the copper converter department capture system at all times
during blowing at the values or settings established for the operating
limits in that plan; and
(4) Submitted a notification of compliance status according to the
requirements in Sec. 63.1454(e).
(e) Baghouses. For each baghouse subject to operating limits in
Sec. 63.1444(f) or Sec. 63.1446(c), you have demonstrated initial
compliance if you meet all of the conditions in paragraphs (e)(1)
through (3) of this section.
(1) You have included in your written operation and maintenance plan
required under Sec. 63.1447(b) detailed descriptions of the procedures
you use for inspection, maintenance, bag leak detection, and corrective
action for the baghouse.
(2) You have certified in your notification of compliance status
that you will operate the baghouse according to your written operation
and maintenance plan.
(3) You have submitted the notification of compliance status
according to the requirements in Sec. 63.1454(e).
(f) Venturi wet scrubbers. For each venturi wet scrubber subject to
operating limits in Sec. 63.1444(g) or Sec. 63.1446(d), you have
demonstrated initial compliance if you meet all of the conditions in
paragraphs (f)(1) through (3) of this section.
(1) Established site-specific operating limits for pressure drop and
scrubber water flow rate and have a record of the pressure drop and
scrubber water flow rate measured during the performance test you
conduct to demonstrate initial compliance with paragraph (a) of this
section.
(2) Certified in your notification of compliance status that you
will operate the venturi wet scrubber within the established operating
limits for pressure drop and scrubber water flow rate.
[[Page 40]]
(3) Submitted a notification of compliance status according to the
requirements in Sec. 63.1454(e).
(g) Other control devices. For each control device other than a
baghouse or venturi wet scrubber subject to operating limits in Sec.
63.1444(h) or Sec. 63.1446(e), you have demonstrated initial compliance
if you meet all of the conditions in paragraphs (g)(1) through (4) of
this section.
(1) Selected one or more operating parameters, as appropriate for
the control device design, that can be used as representative and
reliable indicators of the control device operation.
(2) Established site-specific operating limits for each of the
selected operating parameters based on values measured during the
performance test you conduct to demonstrate initial compliance with
paragraph (a) of this section and have prepared written documentation
according to the requirements in Sec. 63.1450(a)(5)(iv).
(3) Included in your notification of compliance status a copy of the
written documentation you have prepared to demonstrate compliance with
paragraph (g)(2) of this section and have certified in your notification
of compliance status that you will operate the control device within the
established operating limits.
(4) Submitted a notification of compliance status according to the
requirements in Sec. 63.1454(e).
(h) Fugitive dust sources. For all fugitive dust sources subject to
work practice standards in Sec. 63.1445, you have demonstrated initial
compliance if you meet all of the conditions in paragraphs (i)(1)
through (3) of this section.
(1) Prepared a written fugitive dust control plan according to the
requirements in Sec. 63.1454 and it has been approved by the designated
authority.
(2) Certified in your notification of compliance status that you
will control emissions from the fugitive dust sources according to the
procedures in the approved plan.
(3) Submitted the notification of compliance status according to the
requirements in Sec. 63.1454(e).
(i) Operation and maintenance requirements. You have demonstrated
initial compliance with the operation and maintenance requirements that
apply to you if you meet all of the conditions in paragraphs (i)(1)
through (3) of this section.
(1) Prepared an operation and maintenance plan according to the
requirements in Sec. 63.1454(b).
(2) Certified in your notification of compliance status that you
will operate each capture system and control device according to the
procedures in the plan.
(3) Submitted the notification of compliance status according to the
requirements in Sec. 63.1454(e).
Continuous Compliance Requirements
Sec. 63.1452 What are my monitoring requirements?
(a) Copper converter department capture systems. For each operating
limit established under your capture system operation and maintenance
plan, you must install, operate, and maintain an appropriate monitoring
device according the requirements in paragraphs (a)(1) though (6) of
this section to measure and record the operating limit value or setting
at all times the copper converter department capture system is operating
during batch copper converter blowing. Dampers that are manually set and
remain in the same position at all times the capture system is operating
are exempted from the requirements of this paragraph (a).
(1) Install the monitoring device, associated sensor(s), and
recording equipment according to the manufacturers' specifications.
Locate the sensor(s) used for monitoring in or as close to a position
that provides a representative measurement of the parameter being
monitored.
(2) If a flow measurement device is used to monitor the operating
limit parameter, you must meet the requirements in paragraph (a)(2)(i)
through (iv) of this section.
(i) Locate the flow sensor and other necessary equipment such as
straightening vanes in a position that provides a representative flow.
(ii) Use a flow sensor with a minimum tolerance of 2 percent of the
flow rate.
(iii) Reduce swirling flow or abnormal velocity distributions due to
upstream and downstream disturbances.
[[Page 41]]
(iv) Conduct a flow sensor calibration check at least semiannually.
(3) If a pressure measurement device is used to monitor the
operating limit parameter, you must meet the requirements in paragraph
(a)(3)(i) through (v) of this section.
(i) Locate the pressure sensor(s) in or as close to a position that
provides a representative measurement of the pressure.
(ii) Minimize or eliminate pulsating pressure, vibration, and
internal and external corrosion.
(iii) Use a gauge with a minimum tolerance of 0.5 inch of water or a
transducer with a minimum tolerance of 1 percent of the pressure range.
(iv) Check pressure tap pluggage daily.
(v) Using a manometer, check gauge calibration quarterly and
transducer calibration monthly.
(4) Conduct calibration and validation checks any time the sensor
exceeds the manufacturer's specifications or you install a new sensor.
(5) At least monthly, inspect all components for integrity, all
electrical connections for continuity, and all mechanical connections
for leakage.
(6) Record the results of each inspection, calibration, and
validation check.
(b) Baghouses. For each baghouse subject to the operating limit in
Sec. 63.1444(f) or Sec. 63.1446(c) for the bag leak detection system
alarm, you must at all times monitor the relative change in particulate
matter loadings using a bag leak detection system according to the
requirements in paragraph (b)(1) of this section and conduct regular
inspections according to the requirements in paragraph (b)(2) of this
section.
(1) You must install, operate, and maintain each bag leak detection
system according to the requirements in paragraphs (b)(1)(i) through
(vii) of this section.
(i) The system must be certified by the manufacturer to be capable
of detecting emissions of particulate matter at concentrations of 10
milligrams per actual cubic meter (0.0044 grains per actual cubic foot)
or less.
(ii) The system must provide output of relative changes in
particulate matter loadings.
(iii) The system must be equipped with an alarm that will sound when
an increase in relative particulate loadings is detected over a preset
level. The alarm must be located such that it can be heard by the
appropriate plant personnel.
(iv) Each system that works based on the triboelectric effect must
be installed, operated, and maintained in a manner consistent with the
guidance document, ``Fabric Filter Bag Leak Detection Guidance,'' EPA-
454/R-98-015, September 1997. You may obtain a copy of this guidance
document by contacting the National Technical Information Service (NTIS)
at 800-553-6847. You may install, operate, and maintain other types of
bag leak detection systems in a manner consistent with the
manufacturer's written specifications and recommendations.
(v) To make the initial adjustment of the system, establish the
baseline output by adjusting the sensitivity (range) and the averaging
period of the device. Then, establish the alarm set points and the alarm
delay time.
(vi) Following the initial adjustment, do not adjust the sensitivity
or range, averaging period, alarm set points, or alarm delay time,
except as detailed in your operation and maintenance plan. Do not
increase the sensitivity by more than 100 percent or decrease the
sensitivity by more than 50 percent over a 365-day period unless a
responsible official certifies, in writing, that the baghouse has been
inspected and found to be in good operating condition.
(vii) Where multiple detectors are required, the system's
instrumentation and alarm may be shared among detectors.
(2) You must conduct baghouse inspections at their specified
frequencies according to the requirements in paragraphs (b)(2)(i)
through (viii) of this section.
(i) Monitor the pressure drop across each baghouse cell each day to
ensure pressure drop is within the normal operating range identified in
the manual.
(ii) Confirm that dust is being removed from hoppers through weekly
visual inspections or other means of ensuring the proper functioning of
removal mechanisms.
[[Page 42]]
(iii) Check the compressed air supply for pulse-jet baghouses each
day.
(iv) Monitor cleaning cycles to ensure proper operation using an
appropriate methodology.
(v) Check bag cleaning mechanisms for proper functioning through
monthly visual inspection or equivalent means.
(vi) Make monthly visual checks of bag tension on reverse air and
shaker-type baghouses to ensure that bags are not kinked (kneed or bent)
or laying on their sides. You do not have to make this check for shaker-
type baghouses using self-tensioning (spring-loaded) devices.
(vii) Confirm the physical integrity of the baghouse through
quarterly visual inspections of the baghouse interior for air leaks.
(viii) Inspect fans for wear, material buildup, and corrosion
through quarterly visual inspections, vibration detectors, or equivalent
means.
(c) Venturi wet scrubbers. For each venturi wet scrubber subject to
the operating limits for pressure drop and scrubber water flow rate in
Sec. 63.1444(g) or Sec. 63.1446(d), you must at all times monitor the
hourly average pressure drop and water flow rate using a CPMS. You must
install, operate, and maintain each CPMS according to the requirements
in paragraphs (c)(1) and (2) of this section.
(1) For the pressure drop CPMS, you must meet the requirements in
paragraphs (c)(1)(i) through (vi) of this section.
(i) Locate the pressure sensor(s) in or as close to a position that
provides a representative measurement of the pressure and that minimizes
or eliminates pulsating pressure, vibration, and internal and external
corrosion.
(ii) Use a gauge with a minimum measurement sensitivity of 0.5 inch
of water or a transducer with a minimum measurement sensitivity of 1
percent of the pressure range.
(iii) Check the pressure tap for pluggage daily.
(iv) Using a manometer, check gauge calibration quarterly and
transducer calibration monthly.
(v) Conduct calibration checks any time the sensor exceeds the
manufacturer's specified maximum operating pressure range, or install a
new pressure sensor.
(vi) At least monthly, inspect all components for integrity, all
electrical connections for continuity, and all mechanical connections
for leakage.
(2) For the scrubber water flow rate CPMS, you must meet the
requirements in paragraphs (c)(2)(i) through (iv) of this section.
(i) Locate the flow sensor and other necessary equipment in a
position that provides a representative flow and that reduces swirling
flow or abnormal velocity distributions due to upstream and downstream
disturbances.
(ii) Use a flow sensor with a minimum measurement sensitivity of 2
percent of the flow rate.
(iii) Conduct a flow sensor calibration check at least semiannually
according to the manufacturer's instructions.
(iv) At least monthly, inspect all components for integrity, all
electrical connections for continuity, and all mechanical connections
for leakage.
(d) Other control devices. For each control device other than a
baghouse or venturi wet scrubber subject to the operating limits for
appropriate parameters in Sec. Sec. 63.1444(h) or 63.1446(e), you must
at all times monitor each of your selected parameters using an
appropriate CPMS. You must install, operate, and maintain each CPMS
according to the equipment manufacturer's specifications and the
requirements in paragraphs (d)(1) though (5) of this section.
(1) Locate the sensor(s) used for monitoring in or as close to a
position that provides a representative measurement of the parameter
being monitored.
(2) Determine the hourly average of all recorded readings.
(3) Conduct calibration and validation checks any time the sensor
exceeds the manufacturer's specifications or you install a new sensor.
(4) At least monthly, inspect all components for integrity, all
electrical connections for continuity, and all mechanical connections
for leakage.
(5) Record the results of each inspection, calibration, and
validation check.
(e) Except for monitoring malfunctions, associated repairs, and
required quality assurance or control activities
[[Page 43]]
(including as applicable, calibration checks and required zero and span
adjustments), you must monitor continuously (or collect data at all
required intervals) at all times an affected source is operating.
(f) You may not use data recorded during monitoring malfunctions,
associated repairs, and required quality assurance or control activities
in data averages and calculations used to report emission or operating
levels or to fulfill a minimum data availability requirement, if
applicable. You must use all the data collected during all other periods
in assessing compliance.
(g) A monitoring malfunction is any sudden, infrequent, not
reasonably preventable failure of the monitor to provide valid data.
Monitoring failures that are caused in part by poor maintenance or
careless operation are not malfunctions.
[67 FR 40491, June 12, 2002, as amended at 70 FR 40673, July 14, 2005]
Sec. 63.1453 How do I demonstrate continuous compliance with the
emission limitations, work practice standards, and operation and
maintenance requirements that apply to me?
(a) Particulate matter emission limits. For each affected source
subject to a particulate matter emission limit Sec. 63.1444 or Sec.
63.1446 as applies to you, you must demonstrate continuous compliance
according to the requirements in paragraphs (a)(1) and (2) of this
section.
(1) For each copper concentrate dryer, smelting furnace, slag
cleaning vessel, and copper converter department subject to a total
particulate matter emission limit in Sec. 63.1444 or Sec. 63.1446 as
applies to you, you must demonstrate continuous compliance by meeting
the conditions in paragraphs (a)(1)(i) and (ii) of this section.
(i) Maintain the average concentration of total particulate matter
in the gases discharged from the affected source at or below the
applicable emission limit.
(ii) Conduct subsequent performance tests following your initial
performance test no less frequently than once per year according to the
performance test procedures in Sec. 63.1450(a).
(2) For each smelting furnace, slag cleaning vessel, and copper
converter department subject to the nonsulfuric acid particulate matter
emission limit in Sec. 63.1444 as applies to you, you must demonstrate
continuous compliance by meeting the conditions in paragraphs (a)(2)(i)
and (ii) of this section.
(i) Maintain the average concentration of nonsulfuric acid
particulate matter in the process off-gas discharged from the affected
source at or below 6.2 mg/dscm.
(ii) Conduct subsequent performance tests following your initial
performance test no less frequently than once per year according to the
performance test procedures in Sec. 63.1450(b).
(b) Copper converter department capture systems. You must
demonstrate continuous compliance of the copper converter department
capture system by meeting the requirements in paragraphs (b)(1) through
(4) of this section.
(1) Operate the copper converter department capture system at all
times during blowing at or above the lowest values or settings
established for the operating limits and demonstrated to achieve the
opacity limit according to the applicable requirements of this subpart;
(2) Inspect and maintain the copper converter department capture
system according to the applicable requirements in Sec. 63.1447 and
recording all information needed to document conformance with these
requirements;
(3) Monitor the copper converter department capture system according
to the requirements in Sec. 63.1452(a) and collecting, reducing, and
recording the monitoring data for each of the operating limit parameters
according to the applicable requirements of this subpart; and
(4) Conduct subsequent performance tests according to the
requirements of Sec. 63.1450(c) following your initial performance test
no less frequently than once per year to demonstrate that the opacity of
any visible emissions exiting the roof monitors or roof exhaust fans on
the building housing the copper converter department does not exceed 4
percent opacity.
(c) Baghouses. For each baghouse subject to the operating limit for
the bag leak detection system alarm in
[[Page 44]]
Sec. 63.1444(f) or Sec. 63.1446(c), you must demonstrate continuous
compliance by meeting the requirements in paragraphs (c)(1) through (3)
of this section.
(1) Maintain the baghouse such that the bag leak detection system
alarm does not sound for more than 5 percent of the operating time
during any semiannual reporting period. To determine the percent of time
the alarm sounded use the procedures in paragraphs (c)(1)(i) through (v)
of this section.
(i) Alarms that occur due solely to a malfunction of the bag leak
detection system are not included in the calculation.
(ii) Alarms that occur during startup, shutdown, or malfunction are
not included in the calculation if the condition is described in the
startup, shutdown, and malfunction plan, and you operated the source
during such periods in accordance with Sec. 63.6(e)(1).
(iii) Count 1 hour of alarm time for each alarm when you initiated
procedures to determine the cause of the alarm within 1 hour.
(iv) Count the actual amount of time you took to initiate procedures
to determine the cause of the alarm if you did not initiate procedures
to determine the cause of the alarm within 1 hour of the alarm.
(v) Calculate the percentage of time the alarm on the bag leak
detection system sounds as the ratio of the sum of alarm times to the
total operating time multiplied by 100.
(2) Maintain records of the times the bag leak detection system
alarm sounded, and for each valid alarm, the time you initiated
corrective action, the corrective action(s) taken, and the date on which
corrective action was completed.
(3) Inspect and maintain each baghouse according to the requirements
in Sec. 63.1451(b)(2) and recording all information needed to document
conformance with these requirements. If you increase or decrease the
sensitivity of the bag leak detection system beyond the limits specified
in Sec. 63.1451(b)(1)(vi), you must include a copy of the required
written certification by a responsible official in the next semiannual
compliance report.
(d) Venturi wet scrubbers. For each venturi wet scrubber subject to
the operating limits for pressure drop and scrubber water flow rate in
Sec. 63.1444(g) or Sec. 63.1446(d), you must demonstrate continuous
compliance by meeting the requirements of paragraphs (d)(1) through (3)
of this section.
(1) Maintain the hourly average pressure drop and scrubber water
flow rate at levels no lower than those established during the initial
or subsequent performance test;
(2) Inspect and maintain each venturi wet scrubber CPMS according to
Sec. 63.1452(c) and recording all information needed to document
conformance with these requirements; and
(3) Collect and reduce monitoring data for pressure drop and
scrubber water flow rate according to Sec. 63.1452(e) and recording all
information needed to document conformance with these requirements.
(e) Other control devices. For each control device other than a
baghouse or venturi wet scrubber subject to the operating limits for
site-specific operating parameters in Sec. 63.1444(h) or Sec.
63.1446(e), you must demonstrate continuous compliance by meeting the
requirements of paragraphs (e)(1) through (3) of this section:
(1) Maintain the hourly average rate at levels no lower than those
established during the initial or subsequent performance test;
(2) Inspect and maintain each CPMS operated according to Sec.
63.1452(d) and record all information needed to document conformance
with these requirements; and
(3) Collect and reduce monitoring data for selected parameters
according to Sec. 63.1452(e) and recording all information needed to
document conformance with these requirements.
(f) Fugitive dust sources. For each fugitive dust source subject to
work practice standards in Sec. 63.1445, you must demonstrate
continuous compliance by implementing all of fugitive control measures
specified for the source in your written fugitive dust control plan.
[67 FR 40491, June 12, 2002, as amended at 70 FR 40674, July 14, 2005;
71 FR 20461, Apr. 20, 2006]
[[Page 45]]
Notifications, Reports and Records
Sec. 63.1454 What notifications must I submit and when?
(a) You must submit all of the notifications in Sec. Sec.
63.6(h)(4) and (h)(5), 63.7(b) and (c), 63.8(f)(4), and 63.9(b) through
(h) that apply to you by the specified dates.
(b) As specified in Sec. 63.9(b)(2), if you start your affected
source before June 12, 2002, you must submit your initial notification
not later than October 10, 2002.
(c) As specified in Sec. 63.9(b)(3), if you start your new affected
source on or after June 12, 2002, you must submit your initial
notification not later than 120 calendar days after you become subject
to this subpart.
(d) If you are required to conduct a performance test, you must
submit a notification of intent to conduct a performance test at least
60 calendar days before the performance test is scheduled to begin as
required in Sec. 63.7(b)(1).
(e) If you are required to conduct a performance test, opacity
observation, or other initial compliance demonstration, you must submit
a notification of compliance status according to Sec. 63.9(h)(2)(ii) by
the date specified in paragraph (e)(1) or (2) of this section as applies
to you.
(1) For each initial compliance demonstration that does not include
a performance test, you must submit the notification of compliance
status before the close of business on the 30th calendar day following
the completion of the initial compliance demonstration.
(2) For each initial compliance demonstration that includes a
performance test, you must submit the notification of compliance status,
including the performance test results, before the close of business on
the 60th calendar day following the completion of the performance test
according to Sec. 63.10(d)(2).
Sec. 63.1455 What reports must I submit and when?
(a) You must submit each report in paragraphs (a)(1) and (2) of this
section that applies to you.
(1) You must submit a compliance report semiannually according to
the requirements in paragraph (b) of this section and containing the
information in paragraph (c) of this section.
(2) You must submit an immediate startup, shutdown, and malfunction
report if you had a startup, shutdown, or malfunction during the
reporting period that is not consistent with your startup, shutdown, and
malfunction plan. You must report the actions taken for the event by fax
or telephone within 2 working days after starting actions inconsistent
with the plan. You must submit the information in Sec. 63.10(d)(5)(ii)
of this part by letter within 7 working days after the end of the event
unless you have made alternative arrangements with the permitting
authority.
(b) Unless the Administrator has approved a different schedule under
Sec. 63.10(a), you must submit each compliance report required in
paragraph (a) of this section according to the applicable requirements
in paragraphs (b)(1) through (5) of this section.
(1) The first compliance report must cover the period beginning on
the compliance date that is specified for your affected source in Sec.
63.1443 and ending on June 30 or December 31, whichever date comes first
after the compliance date that is specified for your source in Sec.
63.1443.
(2) The first compliance report must be postmarked or delivered no
later than July 31 or January 31, whichever date comes first after your
first compliance report is due.
(3) Each subsequent compliance report must cover the semiannual
reporting period from January 1 through June 30 or the semiannual
reporting period from July 1 through December 31.
(4) Each subsequent compliance report must be postmarked or
delivered no later than July 31 or January 31, whichever date comes
first after the end of the semiannual reporting period.
(5) For each affected source that is subject to permitting
regulations pursuant to 40 CFR part 70 or 40 CFR part 71, and if the
permitting authority has established dates for submitting semiannual
reports pursuant to 40 CFR 70.6(a)(3)(iii)(A) or 40 CFR
71.6(a)(3)(iii)(A) of this chapter, you may submit the first and
subsequent
[[Page 46]]
compliance reports according to the dates the permitting authority has
established instead of according to the dates in paragraphs (b)(1)
through (4) of this section.
(c) Each compliance report must contain the information in
paragraphs (c)(1) through (3) of this section and, as applicable,
paragraphs (c)(4) through (8) of this section.
(1) Company name and address.
(2) Statement by a responsible official, as defined in 40 CFR 63.2,
with that official's name, title, and signature, certifying the accuracy
and completeness of the content of the report.
(3) Date of report and beginning and ending dates of the reporting
period.
(4) If you had a startup, shutdown or malfunction during the
reporting period and you took actions consistent with your startup,
shutdown, and malfunction plan, the compliance report must include the
information in Sec. 63.10(d)(5)(i).
(5) If there are no deviations from any emission limitations
(emission limit, operating limit, opacity limit) that applies to you and
there are no deviations from the requirements for work practice
standards in this subpart, a statement that there were no deviations
from the emission limitations, work practice standards, or operation and
maintenance requirements during the reporting period.
(6) If there were no periods during which an operating parameter
monitoring system was out-of-control as specified in Sec. 63.8(c)(7), a
statement that there were no periods during which the monitoring system
was out-of-control during the reporting period.
(7) For each deviation from an emission limitation (emission limit,
operating limit, opacity limit) and for each deviation from the
requirements for work practice standards that occurs at an affected
source where you are not using a continuous monitoring system to comply
with the emission limitations or work practice standards in this
subpart, the compliance report must contain the information in
paragraphs (b)(1) through (4) of this section and the information in
paragraphs (b)(7)(i) and (ii) of this section. This includes periods of
startup, shutdown, and malfunction.
(i) The total operating time of each affected source during the
reporting period.
(ii) Information on the number, duration, and cause of deviations
(including unknown cause, if applicable), as applicable, and the
corrective action taken.
(8) For each deviation from an emission limitation (emission limit,
operating limit, opacity limit, and visible emission limit) occurring at
an affected source where you are using an operating parameter monitoring
system to comply with the emission limitation in this subpart, you must
include the information in paragraphs (b)(1) through (4) of this section
and the information in paragraphs (c)(8)(i) through (xi) of this
section. This includes periods of startup, shutdown, and malfunction.
(i) The date and time that each malfunction started and stopped.
(ii) The date and time that each monitoring system was inoperative,
except for zero (low-level) and high-level checks.
(iii) The date, time and duration that each monitoring system was
out-of-control, including the information in Sec. 63.8(c)(8).
(iv) The date and time that each deviation started and stopped, and
whether each deviation occurred during a period of startup, shutdown, or
malfunction or during another period.
(v) A summary of the total duration of the deviation during the
reporting period and the total duration as a percent of the total source
operating time during that reporting period.
(vi) A breakdown of the total duration of the deviations during the
reporting period into those that are due to startup, shutdown, control
equipment problems, process problems, other known causes, and other
unknown causes.
(vii) A summary of the total duration of monitoring system downtime
during the reporting period and the total duration of monitoring system
downtime as a percent of the total source operating time during that
reporting period.
(viii) A brief description of the process units.
(ix) A brief description of the monitoring system.
[[Page 47]]
(x) The date of the latest monitoring system certification or audit.
(xi) A description of any changes in continuous monitoring systems,
processes, or controls since the last reporting period.
(d) If you have obtained a Title V operating permit pursuant to 40
CFR part 70 or 40 CFR part 71 must report all deviations as defined in
this subpart in the semiannual monitoring report required by 40 CFR
70.6(a)(3)(iii)(A) or 40 CFR 71.6(a)(3)(iii)(A). If you submit a
compliance report pursuant to paragraph (a) of this section along with,
or as part of, the semiannual monitoring report required by 40 CFR
70.6(a)(3)(iii)(A) or 40 CFR 71.6(a)(3)(iii)(A), and the compliance
report includes all required information concerning deviations from any
emission limitation(including any operating limit), or work practice
requirement in this subpart, submission of the compliance report is
deemed to satisfy any obligation to report the same deviations in the
semiannual monitoring report. However, submission of a compliance report
does not otherwise affect any obligation you may have to report
deviations from permit requirements to the permit authority.
Sec. 63.1456 What records must I keep and how long must I keep my
records?
(a) You must keep the records listed in paragraphs (a)(1) through
(7) of this section.
(1) A copy of each notification and report that you submitted to
comply with this subpart, including all documentation supporting any
initial notification or notification of compliance status that you
submitted, according to the requirements in Sec. 63.10(b)(2)(xiv).
(2) The records in Sec. 63.6(e)(3)(iii) through (v) related to
startup, shutdown, and malfunction.
(3) Records of performance tests and performance evaluations as
required in Sec. 63.10(b)(2)(viii).
(4) For each monitoring system, you must keep the records specified
in paragraphs (a)(4)(i) through (iv) of this section.
(i) Records described in Sec. 63.10(b)(2)(vi) through (xi).
(ii) Monitoring data recorded by the monitoring system during a
performance evaluation as required in Sec. 63.6(h)(7)(i) and (ii).
(iii) Previous (i.e., superseded) versions of the performance
evaluation plan as required in Sec. 63.8(d)(3).
(iv) Records of the date and time that each deviation started and
stopped, and whether the deviation occurred during a period of startup,
shutdown, or malfunction or during another period.
(5) For each performance test you conduct to demonstrate compliance
with an opacity limit according to Sec. 63.1450(c), you must keep the
records specified in paragraphs (a)(5)(i) through (ix) of this section.
(i) Dates and time intervals of all opacity observation period
segments;
(ii) Description of overall smelter operating conditions during each
observation period. Identify, if any, the smelter copper production
process equipment that was out-of-service during the performance test
and explain why this equipment was not in operation;
(iii) Name, affiliation, and copy of current visible emission
reading certification for each visible emission observer participating
in the performance test;
(iv) Name, title, and affiliation for each indoor process monitor
participating in the performance test;
(v) Copies of all visible emission observer opacity field data
sheets;
(vi) Copies of all indoor process monitor operating log sheets;
(vii) Copies of all data summary sheets used for data reduction;
(viii) Copy of calculation sheets of the average opacity value used
to demonstrate compliance with the opacity limit; and
(ix) Documentation according to the requirements in Sec.
63.1450(c)(9)(iv) to support your selection of the site-specific capture
system operating limits used for each batch copper converter capture
system when blowing.
(6) For each baghouse subject to the operating limit in Sec.
63.1444(f) or Sec. 63.1446(c), you must keep the records specified in
paragraphs (a)(6)(i) and (ii) of this section.
(i) Records of alarms for each bag leak detection system.
[[Page 48]]
(ii) Description of the corrective actions taken following each bag
leak detection alarm.
(7) For each control device other than a baghouse or venturi wet
scrubber subject to site-specific operating limits in Sec. 63.1444(g)
or Sec. 63.1446(f), you must keep documentation according to the
requirements in Sec. 63.1450(a)(5)(iv) to support your selection of the
site-specific operating limits for the control device.
(b) Your records must be in a form suitable and readily available
for expeditious review, according to Sec. 63.10(b)(1).
(c) As specified in Sec. 63.10(b)(1), you must keep each record for
5 years following the date of each occurrence, measurement, maintenance,
corrective action, report, or record.
(d) You must keep each record on site for at least 2 years after the
date of each occurrence, measurement, maintenance, corrective action,
report, or record, according to Sec. 63.10(b)(1). You can keep the
records off site for the remaining 3 years.
Other Requirements and Information
Sec. 63.1457 What part of the general provisions apply to me?
Table 2 to this subpart shows which parts of the general provisions
in Sec. Sec. 63.1 through 63.15 apply to you.
Sec. 63.1458 Who implements and enforces this subpart?
(a) This subpart can be implemented and enforced by us, the United
States Environmental Protection Agency (U.S. EPA), or a delegated
authority such as your State, local, or tribal agency. If the U.S. EPA
Administrator has delegated authority to your State, local, or tribal
agency, then that agency has the authority to implement and enforce this
subpart. You should contact your U.S. EPA Regional Office to find out if
this subpart is delegated to your State, local, or tribal agency.
(b) In delegating implementation and enforcement authority of this
subpart to a State, local, or tribal agency under 40 CFR part 63,
subpart E, the authorities listed in paragraph (c) of this section are
retained by the U.S. EPA Administrator and are not transferred to the
State, local, or tribal agency.
(c) The authorities that will not be delegated to State, local, or
tribal agencies are as listed in paragraphs (c)(1) through (4) of this
section.
(1) Approval of alternatives to the emission limitations and work
practice standards in Sec. Sec. 63.1444 through 63.1446 under Sec.
63.6(g).
(2) Approval of major alternatives to test methods under Sec.
63.7(f) and as defined in Sec. 63.90.
(3) Approval of major alternatives to monitoring under Sec. 63.8(f)
and as defined in Sec. 63.90.
(4) Approval of major alternatives to recordkeeping and reporting
under Sec. 63.10(f) and as defined in Sec. 63.90.
Sec. 63.1459 What definitions apply to this subpart?
Terms used in this subpart are defined in the Clean Air Act, in
Sec. 63.2, and in this section as follows:
Bag leak detection system means a system that is capable of
continuously monitoring relative particulate matter (dust) loadings in
the exhaust of a baghouse in order to detect bag leaks and other upset
conditions. A bag leak detection system includes, but is not limited to,
an instrument that operates on triboelectric, light scattering,
transmittance or other effect to continuously monitor relative
particulate matter loadings.
Baghouse means a control device that collects particulate matter by
filtering the gas stream through bags. A baghouse is also referred to as
a ``fabric filter.''
Batch copper converter means a Pierce-Smith converter or Hoboken
converter in which copper matte is oxidized to form blister copper by a
process that is performed in discrete batches using a sequence of
charging, blowing, skimming, and pouring.
Blowing means the operating mode for a batch copper converter during
which air or oxygen-enriched air is injected into the molten converter
bath.
Capture system means the collection of components used to capture
gases and fumes released from one or more emission points, and to convey
the captured gases and fumes to a control device. A capture system may
include,
[[Page 49]]
but is not limited to, the following components as applicable to a given
capture system design: duct intake devices, hoods, enclosures, ductwork,
dampers, manifolds, plenums, and fans.
Charging means the operating mode for a batch copper converter
during which molten or solid material is added into the vessel.
Control device means the air pollution control equipment used to
collect particulate matter emissions. Examples of such equipment
include, but are not limited to, a baghouse, an electrostatic
precipitator, and a wet scrubber.
Copper concentrate dryer means a vessel in which copper concentrates
are heated in the presence of air to reduce the moisture content of the
material. Supplemental copper-bearing feed materials and fluxes may be
added or mixed with the copper concentrates fed to a copper concentrate
dryer.
Copper converter department means the area at a primary copper
smelter in which the copper converters are located.
Copper matte means a material predominately composed of copper and
iron sulfides produced by smelting copper ore concentrates.
Deviation means any instance in which an affected source subject to
this subpart or an owner or operator of such a source fails to meet any
of the following:
(1) Any requirement or obligation established by this subpart
including, but not limited to, any emission limitation (including any
operating limit) or work practice standard;
(2) Any term or condition that is adopted to implement an applicable
requirement in this subpart and that is included in the operating permit
for any affected source required to obtain such a permit; or
(3) Any emission limitation (including any operating limit) or work
practice standard in this subpart during startup, shutdown, or
malfunction, regardless whether or not such failure is permitted by this
subpart.
Emission limitation means any emission limit, opacity limit,
operating limit, or visible emission limit.
Fugitive dust material means copper concentrate, dross, reverts,
slag, speiss, or other solid copper-bearing materials.
Fugitive dust source means a stationary source of particulate matter
emissions resulting from the handling, storage, transfer, or other
management of fugitive dust materials where the source is not associated
with a specific process, process vent, or stack. Examples of a fugitive
dust source include, but are not limited to, on-site roadways used by
trucks transporting copper concentrate, unloading of materials from
trucks or railcars, outdoor material storage piles, and transfer of
material to hoppers and bins.
Holding means the operating mode for a batch copper converter during
which the molten bath is maintained in the vessel but no blowing is
performed nor is material added into or removed from the vessel.
Opacity means the degree to which emissions reduce the transmission
of light.
Particulate matter means any finely divided solid or liquid
material, other than uncombined water, as measured by the specific
reference method.
Pouring means the operating mode for a batch copper converter during
which molten copper is removed from the vessel.
Primary copper smelter means any installation or any intermediate
process engaged in the production of copper from copper sulfide ore
concentrates through the use of pyrometallurgical techniques.
Responsible official means responsible official as defined in 40 CFR
70.2.
Skimming means the batch copper converter operating mode during
which molten slag is removed from the vessel.
Slag cleaning vessel means a vessel that receives molten copper-
bearing material and the predominant use of the vessel is to separate
this material into molten copper matte and slag layers.
Smelting furnace means a furnace, reactor, or other type of vessel
in which copper ore concentrate and fluxes are melted to form a molten
mass of material containing copper matte and slag. Other copper-bearing
materials may also be charged to the smelting furnace.
[[Page 50]]
Work practice standard means any design, equipment, work practice,
or operational standard, or combination thereof, that is promulgated
pursuant to section 112(h) of the Clean Air Act.
Table 1 to Subpart QQQ of Part 63--Applicability of General Provisions
to Subpart QQQ
As required in Sec. 63.1457, you must comply with the requirements
of the NESHAP General Provisions (40 CFR part 63, subpart A) shown in
the following table:
----------------------------------------------------------------------------------------------------------------
Citation Subject Applies to subpart QQQ Explanation
----------------------------------------------------------------------------------------------------------------
Sec. 63.1.......................... Applicability.......... Yes....................
Sec. 63.2.......................... Definitions............ Yes....................
Sec. 63.3.......................... Units and Abbreviations Yes....................
Sec. 63.4.......................... Prohibited Activities.. Yes....................
Sec. 63.5.......................... Construction and Yes....................
Reconstruction.
Sec. 63.6(a)-(g)................... Compliance with Yes....................
Standards and
Maintenance
requirements.
Sec. 63.6(h)....................... Determining compliance No..................... Subpart QQQ specifies
with Opacity and VE the requirements and
standards. test protocol used to
determine compliance
with the opacity
limits.
Sec. 63.6(i)-(j)................... Extension of Compliance Yes....................
and Presidential
Compliance Exemption.
Sec. 63.7(a)(1)-(2)................ Applicability and No..................... Subpart QQQ specifies
Performance Test Dates. performance test
applicability and
dates.
Sec. 63.7(a)(3), (b)-(h)........... Performance Testing Yes....................
Requirements.
Sec. 63.8 except for (a)(4),(c)(4), Monitoring Requirements Yes....................
and (f)(6).
Sec. 63.8(a)(4).................... Additional Monitoring No..................... Subpart QQ does not
Requirements for require flares.
Control devices in
Sec. 63.11.
Sec. 63.8(c)(4).................... Continuous Monitoring No..................... Subpart QQQ specifies
System Requirements. requirements for
operation of CMS.
Sec. 63.8(f)(6).................... RATA Alternative....... No..................... Subpart QQQ does not
require continuous
emission monitoring
systems.
Sec. 63.9.......................... Notification Yes....................
Requirements.
Sec. 63.9(g)(5).................... DATA reduction......... No..................... Subpart QQQ specifies
data reduction
requirements
Sec. 63.10 except for (b)(2)(xiii) Recordkeeping and Yes....................
and (c)(7)-(8). reporting Requirements.
Sec. 63.10(b)(2)(xiii)............. CMS Records for RATA No..................... Subpart QQQ does not
Alternative. require continuous
emission monitoring
systems.
Sec. 63.10(c)(7)-(8)............... Records of Excess No..................... Subpart QQQ specifies
Emissions and record keeping
Parameter Monitoring requirements
Accedences for CMS.
Sec. 63.11......................... Control Device No..................... Subpart QQQ does not
Requirements. require flares
Sec. 63.12......................... State Authority and Yes....................
Delegations.
Sec. Sec. 63.13-63.15............. Addresses, Yes....................
Incorporation by
Reference,
Availability of
Information.
----------------------------------------------------------------------------------------------------------------
Figure 1 to Subpart QQQ of Part 63--Data Summary Sheet for Determination
of Average Opacity
----------------------------------------------------------------------------------------------------------------
Average
Visible opacity for 1-
emissions minute
Average interference interval
Number of Converter aisle opacity for 1- observed blowing
Clock time converters activity minute during 1- without
blowing interval minute visible
(percent) interval? emission
(yes or no) interferences
(percent)
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[[Page 51]]
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Subpart RRR_National Emission Standards for Hazardous Air Pollutants for
Secondary Aluminum Production
Source: 65 FR 15710, Mar. 23, 2000, unless otherwise noted.
General
Sec. 63.1500 Applicability.
(a) The requirements of this subpart apply to the owner or operator
of each secondary aluminum production facility as defined in Sec.
63.1503.
(b) The requirements of this subpart apply to the following affected
sources, located at a secondary aluminum production facility that is a
major source of hazardous air pollutants (HAPs) as defined in Sec.
63.2:
(1) Each new and existing aluminum scrap shredder;
(2) Each new and existing thermal chip dryer;
(3) Each new and existing scrap dryer/delacquering kiln/decoating
kiln;
(4) Each new and existing group 2 furnace;
(5) Each new and existing sweat furnace;
(6) Each new and existing dross-only furnace;
(7) Each new and existing rotary dross cooler; and
(8) Each new and existing secondary aluminum processing unit.
(c) The requirements of this subpart pertaining to dioxin and furan
(D/F) emissions and associated operating, monitoring, reporting and
recordkeeping requirements apply to the following affected sources,
located at a secondary aluminum production facility that is an area
source of HAPs as defined in Sec. 63.2:
(1) Each new and existing thermal chip dryer;
(2) Each new and existing scrap dryer/delacquering kiln/decoating
kiln;
(3) Each new and existing sweat furnace;
(4) Each new and existing secondary aluminum processing unit,
containing one or more group 1 furnace emission units processing other
than clean charge.
(d) The requirements of this subpart do not apply to facilities and
equipment used for research and development that are not used to produce
a saleable product.
(e) If you are an owner or operator of an area source subject to
this subpart,
[[Page 52]]
you are exempt from the obligation to obtain a permit under 40 CFR part
70 or 71, provided you are not required to obtain a permit under 40 CFR
70.3(a) or 71.3(a) for a reason other than your status as an area source
under this subpart. Notwithstanding the previous sentence, you must
continue to comply with the provisions of this subpart applicable to
area sources.
(f) An aluminum die casting facility, aluminum foundry, or aluminum
extrusion facility shall be considered to be an area source if it does
not emit, or have the potential to emit considering controls, 10 tons
per year or more of any single listed HAP or 25 tons per year of any
combination of listed HAP from all emission sources which are located in
a contiguous area and under common control, without regard to whether or
not such sources are regulated under this subpart or any other subpart.
In the case of an aluminum die casting facility, aluminum foundry, or
aluminum extrusion facility which is an area source and is subject to
regulation under this subpart only because it operates a thermal chip
dryer, no furnace operated by such a facility shall be deemed to be
subject to the requirements of this subpart if it melts only clean
charge, internal scrap, or customer returns.
[65 FR 15710, Mar. 23, 2000, as amended at 67 FR 79814, Dec. 30, 2002;
70 FR 75346, Dec. 19, 2005]
Sec. 63.1501 Dates.
(a) The owner or operator of an existing affected source must comply
with the requirements of this subpart by March 24, 2003.
(b) Except as provided in paragraph (c) of this section, the owner
or operator of a new affected source that commences construction or
reconstruction after February 11, 1999 must comply with the requirements
of this subpart by March 24, 2000 or upon startup, whichever is later.
(c) The owner or operator of any affected source which is
constructed or reconstructed at any existing aluminum die casting
facility, aluminum foundry, or aluminum extrusion facility which
otherwise meets the applicability criteria set forth in Sec. 63.1500
must comply with the requirements of this subpart by March 24, 2003 or
upon startup, whichever is later.
[67 FR 59791, Sept. 24, 2002]
Sec. 63.1502 Incorporation by reference.
(a) The following material is incorporated by reference in the
corresponding sections noted. The incorporation by reference (IBR) of
certain publications listed in the rule will be approved by the Director
of the Office of the Federal Register as of the date of publication of
the final rule in accordance with 5 U.S.C. 552(a) and 1 CFR part 51.
This material is incorporated as it exists on the date of approval:
(1) Chapters 3 and 5 of ``Industrial Ventilation: A Manual of
Recommended Practice,'' American Conference of Governmental Industrial
Hygienists, (23rd edition, 1998), IBR approved for Sec. 63.1506(c), and
(2) ``Interim Procedures for Estimating Risks Associated with
Exposures to Mixtures of Chlorinated Dibenzo-p-Dioxins and -
Dibenzofurans (CDDs and CDFs) and 1989 Update'' (EPA/625/3-89/016).
(b) The material incorporated by reference is available for
inspection at the National Archives and Records Administration (NARA);
and at the Air and Radiation Docket and Information Center, U.S. EPA,
1200 Pennsylvania Ave., NW., Washington, DC. For information on the
availability of this material at NARA, call 202-741-6030, or go to:
http://www.archives.gov/federal--register/code--of--federal--
regulations/ibr--locations.html. The material is also available for
purchase from the following addresses:
(1) Customer Service Department, American Conference of Governmental
Industrial Hygienists (ACGIH), 1330 Kemper Meadow Drive, Cincinnati, OH
45240-1634, telephone number (513) 742-2020; and
(2) The National Technical Information Service (NTIS), 5285 Port
Royal Road, Springfield, VA, NTIS no. PB 90-145756.
Sec. 63.1503 Definitions.
Terms used in this subpart are defined in the Clean Air Act as
amended (CAA), in Sec. 63.2, or in this section as follows:
[[Page 53]]
Add-on air pollution control device means equipment installed on a
process vent that reduces the quantity of a pollutant that is emitted to
the air.
Afterburner means an air pollution control device that uses
controlled flame combustion to convert combustible materials to
noncombustible gases; also known as an incinerator or a thermal
oxidizer.
Aluminum scrap means fragments of aluminum stock removed during
manufacturing (i.e., machining), manufactured aluminum articles or parts
rejected or discarded and useful only as material for reprocessing, and
waste and discarded material made of aluminum.
Aluminum scrap shredder means a unit that crushes, grinds, or breaks
aluminum scrap into a more uniform size prior to processing or charging
to a scrap dryer/delacquering kiln/decoating kiln, or furnace. A bale
breaker is not an aluminum scrap shredder.
Bag leak detection system means an instrument that is capable of
monitoring particulate matter loadings in the exhaust of a fabric filter
(i.e., baghouse) in order to detect bag failures. A bag leak detection
system includes, but is not limited to, an instrument that operates on
triboelectric, light scattering, light transmittance, or other effect to
monitor relative particulate matter loadings.
Chips means small, uniformly-sized, unpainted pieces of aluminum
scrap, typically below 1\1/4\ inches in any dimension, primarily
generated by turning, milling, boring, and machining of aluminum parts.
Clean charge means furnace charge materials, including molten
aluminum; T-bar; sow; ingot; billet; pig; alloying elements; aluminum
scrap known by the owner or operator to be entirely free of paints,
coatings, and lubricants; uncoated/unpainted aluminum chips that have
been thermally dried or treated by a centrifugal cleaner; aluminum scrap
dried at 343 [deg]C (650 [deg]F) or higher; aluminum scrap delacquered/
decoated at 482 [deg]C (900 [deg]F) or higher, and runaround scrap.
Cover flux means salt added to the surface of molten aluminum in a
group 1 or group 2 furnace, without agitation of the molten aluminum,
for the purpose of preventing oxidation.
Customer returns means any aluminum product which is returned by a
customer to the aluminum company that originally manufactured the
product prior to resale of the product or further distribution in
commerce, and which contains no paint or other solid coatings (i.e.,
lacquers).
D/F means dioxins and furans.
Dioxins and furans means tetra-, penta-, hexa-, and octachlorinated
dibenzo dioxins and furans.
Dross means the slags and skimmings from aluminum melting and
refining operations consisting of fluxing agent(s), impurities, and/or
oxidized and non-oxidized aluminum, from scrap aluminum charged into the
furnace.
Dross-only furnace means a furnace, typically of rotary barrel
design, dedicated to the reclamation of aluminum from dross formed
during melting, holding, fluxing, or alloying operations carried out in
other process units. Dross and salt flux are the sole feedstocks to this
type of furnace.
Emission unit means a group 1 furnace or in-line fluxer at a
secondary aluminum production facility.
Fabric filter means an add-on air pollution control device used to
capture particulate matter by filtering gas streams through filter
media; also known as a baghouse.
Feed/charge means, for a furnace or other process unit that operates
in batch mode, the total weight of material (including molten aluminum,
T-bar, sow, ingot, etc.) and alloying agents that enter the furnace
during an operating cycle. For a furnace or other process unit that
operates continuously, feed/charge means the weight of material
(including molten aluminum, T-bar, sow, ingot, etc.) and alloying agents
that enter the process unit within a specified time period (e.g., a time
period equal to the performance test period). The feed/charge for a
dross only furnace includes the total weight of dross and solid flux.
Fluxing means refining of molten aluminum to improve product
quality, achieve product specifications, or reduce material loss,
including the addition of solvents to remove impurities (solvent flux);
and the injection of
[[Page 54]]
gases such as chlorine, or chlorine mixtures, to remove magnesium
(demagging) or hydrogen bubbles (degassing). Fluxing may be performed in
the furnace or outside the furnace by an in-line fluxer.
Furnace hearth means the combustion zone of a furnace in which the
molten metal is contained.
Group 1 furnace means a furnace of any design that melts, holds, or
processes aluminum that contains paint, lubricants, coatings, or other
foreign materials with or without reactive fluxing, or processes clean
charge with reactive fluxing.
Group 2 furnace means a furnace of any design that melts, holds, or
processes only clean charge and that performs no fluxing or performs
fluxing using only nonreactive, non-HAP-containing/non-HAP-generating
gases or agents.
HCl means, for the purposes of this subpart, emissions of hydrogen
chloride that serve as a surrogate measure of the total emissions of the
HAPs hydrogen chloride, hydrogen fluoride and chlorine.
In-line fluxer means a device exterior to a furnace, located in a
transfer line from a furnace, used to refine (flux) molten aluminum;
also known as a flux box, degassing box, or demagging box.
Internal scrap means all aluminum scrap regardless of the level of
contamination which originates from castings or extrusions produced by
an aluminum die casting facility, aluminum foundry, or aluminum
extrusion facility, and which remains at all times within the control of
the company that produced the castings or extrusions.
Lime means calcium oxide or other alkaline reagent.
Lime-injection means the continuous addition of lime upstream of a
fabric filter.
Melting/holding furnace means a group 1 furnace that processes only
clean charge, performs melting, holding, and fluxing functions, and does
not transfer molten aluminum to or from another furnace except for
purposes of alloy changes, off-specification product drains, or
maintenance activities.
Operating cycle means for a batch process, the period beginning when
the feed material is first charged to the operation and ending when all
feed material charged to the operation has been processed. For a batch
melting or holding furnace process, operating cycle means the period
including the charging and melting of scrap aluminum and the fluxing,
refining, alloying, and tapping of molten aluminum (the period from tap-
to-tap).
PM means, for the purposes of this subpart, emissions of particulate
matter that serve as a measure of total particulate emissions and as a
surrogate for metal HAPs contained in the particulates, including but
not limited to, antimony, arsenic, beryllium, cadmium, chromium, cobalt,
lead, manganese, mercury, nickel, and selenium.
Pollution prevention means source reduction as defined under the
Pollution Prevention Act of 1990 (e.g., equipment or technology
modifications, process or procedure modifications, reformulation or
redesign of products, substitution of raw materials, and improvements in
housekeeping, maintenance, training, or inventory control), and other
practices that reduce or eliminate the creation of pollutants through
increased efficiency in the use of raw materials, energy, water, or
other resources, or protection of natural resources by conservation.
Reactive fluxing means the use of any gas, liquid, or solid flux
(other than cover flux) that results in a HAP emission. Argon and
nitrogen are not reactive and do not produce HAP.
Reconstruction means the replacement of components of an affected
source or emission unit such that the fixed capital cost of the new
components exceeds 50 percent of the fixed capital cost that would be
required to construct a comparable new affected source, and it is
technologically and economically feasible for the reconstructed source
to meet relevant standard(s) established in this subpart. Replacement of
the refractory in a furnace is routine maintenance and is not a
reconstruction. The repair and replacement of in-line fluxer components
(e.g., rotors/shafts, burner tubes, refractory, warped steel) is
considered to be routine maintenance and is not considered a
reconstruction. In-line fluxers are typically removed to a maintenance/
repair area and are replaced with repaired
[[Page 55]]
units. The replacement of an existing in-line fluxer with a repaired
unit is not considered a reconstruction.
Residence time means, for an afterburner, the duration of time
required for gases to pass through the afterburner combustion zone.
Residence time is calculated by dividing the afterburner combustion zone
volume in cubic feet by the volumetric flow rate of the gas stream in
actual cubic feet per second.
Rotary dross cooler means a water-cooled rotary barrel device that
accelerates cooling of dross.
Runaround scrap means scrap materials generated on-site by aluminum
casting, extruding, rolling, scalping, forging, forming/stamping,
cutting, and trimming operations and that do not contain paint or solid
coatings. Uncoated/unpainted aluminum chips generated by turning,
boring, milling, and similar machining operations may be clean charge if
they have been thermally dried or treated by a centrifugal cleaner, but
are not considered to be runaround scrap.
Scrap dryer/delacquering kiln/decoating kiln means a unit used
primarily to remove various organic contaminants such as oil, paint,
lacquer, ink, plastic, and/or rubber from aluminum scrap (including used
beverage containers) prior to melting.
Secondary aluminum processing unit (SAPU). An existing SAPU means
all existing group 1 furnaces and all existing in-line fluxers within a
secondary aluminum production facility. Each existing group 1 furnace or
existing in-line fluxer is considered an emission unit within a
secondary aluminum processing unit. A new SAPU means any combination of
individual group 1 furnaces and in-line fluxers within a secondary
aluminum processing facility which either were constructed or
reconstructed after February 11, 1999, or have been permanently
redesignated as new emission units pursuant to Sec. 63.1505(k)(6). Each
of the group 1 furnaces or in-line fluxers within a new SAPU is
considered an emission unit within that secondary aluminum processing
unit.
Secondary aluminum production facility means any establishment using
clean charge, aluminum scrap, or dross from aluminum production, as the
raw material and performing one or more of the following processes:
scrap shredding, scrap drying/delacquering/decoating, thermal chip
drying, furnace operations (i.e., melting, holding, sweating, refining,
fluxing, or alloying), recovery of aluminum from dross, in-line fluxing,
or dross cooling. A secondary aluminum production facility may be
independent or part of a primary aluminum production facility. For
purposes of this subpart, aluminum die casting facilities, aluminum
foundries, and aluminum extrusion facilities are not considered to be
secondary aluminum production facilities if the only materials they melt
are clean charge, customer returns, or internal scrap, and if they do
not operate sweat furnaces, thermal chip dryers, or scrap dryers/
delacquering kilns/decoating kilns. The determination of whether a
facility is a secondary aluminum production facility is only for
purposes of this subpart and any regulatory requirements which are
derived from the applicability of this subpart, and is separate from any
determination which may be made under other environmental laws and
regulations, including whether the same facility is a ``secondary metal
production facility'' as that term is used in 42 U.S.C. Sec. 7479(1)
and 40 CFR 52.21(b)(1)(i)(A) (``prevention of significant deterioration
of air quality'').
Sidewell means an open well adjacent to the hearth of a furnace with
connecting arches between the hearth and the open well through which
molten aluminum is circulated between the hearth, where heat is applied
by burners, and the open well, which is used for charging scrap and
solid flux or salt to the furnace, injecting fluxing agents, and
skimming dross.
Sweat furnace means a furnace used exclusively to reclaim aluminum
from scrap that contains substantial quantities of iron by using heat to
separate the low-melting point aluminum from the scrap while the higher
melting-point iron remains in solid form.
TEQ means the international method of expressing toxicity
equivalents for dioxins and furans as defined in ``Interim Procedures
for Estimating Risks Associated with Exposures to Mixtures of
Chlorinated Dibenzo-p-Dioxins and
[[Page 56]]
-Dibenzofurans (CDDs and CDFs) and 1989 Update'' (EPA-625/3-89-016),
available from the National Technical Information Service (NTIS), 5285
Port Royal Road, Springfield, Virginia 22161, NTIS no. PB 90-145756.
THC means, for the purposes of this subpart, total hydrocarbon
emissions that also serve as a surrogate for the emissions of organic
HAP compounds.
Thermal chip dryer means a device that uses heat to evaporate oil or
oil/water mixtures from unpainted/uncoated aluminum chips. Pre-heating
boxes or other dryers which are used solely to remove water from
aluminum scrap are not considered to be thermal chip dryers for purposes
of this subpart.
Three-day, 24-hour rolling average means daily calculations of the
average 24-hour emission rate (lbs/ton of feed/charge), over the 3 most
recent consecutive 24-hour periods, for a secondary aluminum processing
unit.
Total reactive chlorine flux injection rate means the sum of the
total weight of chlorine in the gaseous or liquid reactive flux and the
total weight of chlorine in the solid reactive chloride flux, divided by
the total weight of feed/charge, as determined by the procedure in Sec.
63.1512(o).
[65 FR 15710, Mar. 23, 2000, as amended at 67 FR 79814, Dec. 30, 2002;
69 FR 18803, Apr. 9, 2004; 69 FR 53984, Sept. 3, 2004; 70 FR 57517, Oct.
3, 2005]
Sec. 63.1504 [Reserved]
Emission Standards and Operating Requirements
Sec. 63.1505 Emission standards for affected sources and emission units.
(a) Summary. The owner or operator of a new or existing affected
source must comply with each applicable limit in this section. Table 1
to this subpart summarizes the emission standards for each type of
source.
(b) Aluminum scrap shredder. On and after the compliance date
established by Sec. 63.1501, the owner or operator of an aluminum scrap
shredder at a secondary aluminum production facility that is a major
source must not discharge or cause to be discharged to the atmosphere:
(1) Emissions in excess of 0.023 grams (g) of PM per dry standard
cubic meter (dscm) (0.010 grain (gr) of PM per dry standard cubic foot
(dscf)); and
(2) Visible emissions (VE) in excess of 10 percent opacity from any
PM add-on air pollution control device if a continuous opacity monitor
(COM) or visible emissions monitoring is chosen as the monitoring
option.
(c) Thermal chip dryer. On and after the compliance date established
by Sec. 63.1501, the owner or operator of a thermal chip dryer must not
discharge or cause to be discharged to the atmosphere emissions in
excess of:
(1) 0.40 kilogram (kg) of THC, as propane, per megagram (Mg) (0.80
lb of THC, as propane, per ton) of feed/charge from a thermal chip dryer
at a secondary aluminum production facility that is a major source; and
(2) 2.50 micrograms ([micro]g) of D/F TEQ per Mg (3.5 x
10-5 gr per ton) of feed/charge from a thermal chip dryer at
a secondary aluminum production facility that is a major or area source.
(d) Scrap dryer/delacquering kiln/decoating kiln. On and after the
compliance date established by Sec. 63.1501:
(1) The owner or operator of a scrap dryer/delacquering kiln/
decoating kiln must not discharge or cause to be discharged to the
atmosphere emissions in excess of:
(i) 0.03 kg of THC, as propane, per Mg (0.06 lb of THC, as propane,
per ton) of feed/charge from a scrap dryer/delacquering kiln/decoating
kiln at a secondary aluminum production facility that is a major source;
(ii) 0.04 kg of PM per Mg (0.08 lb per ton) of feed/charge from a
scrap dryer/delacquering kiln/decoating kiln at a secondary aluminum
production facility that is a major source;
(iii) 0.25 [micro]g of D/F TEQ per Mg (3.5 x 10-6 gr of
D/F TEQ per ton) of feed/charge from a scrap dryer/delacquering kiln/
decoating kiln at a secondary aluminum production facility that is a
major or area source; and
(iv) 0.40 kg of HCl per Mg (0.80 lb per ton) of feed/charge from a
scrap dryer/delacquering kiln/decoating kiln at a secondary aluminum
production facility that is a major source.
(2) The owner or operator of a scrap dryer/delacquering kiln/
decoating kiln
[[Page 57]]
at a secondary aluminum production facility that is a major source must
not discharge or cause to be discharged to the atmosphere visible
emissions in excess of 10 percent opacity from any PM add-on air
pollution control device if a COM is chosen as the monitoring option.
(e) Scrap dryer/delacquering kiln/decoating kiln: alternative
limits. The owner or operator of a scrap dryer/ delacquering kiln/
decoating kiln may choose to comply with the emission limits in this
paragraph (e) as an alternative to the limits in paragraph (d) of this
section if the scrap dryer/delacquering kiln/decoating kiln is equipped
with an afterburner having a design residence time of at least 1 second
and the afterburner is operated at a temperature of at least 760 [deg]C
(1400 [deg]F) at all times. On and after the compliance date established
by Sec. 63.1501:
(1) The owner or operator of a scrap dryer/delacquering kiln/
decoating kiln must not discharge or cause to be discharged to the
atmosphere emissions in excess of:
(i) 0.10 kg of THC, as propane, per Mg (0.20 lb of THC, as propane,
per ton) of feed/charge from a scrap dryer/delacquering kiln/decoating
kiln at a secondary aluminum production facility that is a major source;
(ii) 0.15 kg of PM per Mg (0.30 lb per ton) of feed/charge from a
scrap dryer/delacquering kiln/decoating kiln at a secondary aluminum
production facility that is a major source;
(iii) 5.0 [micro]g of D/F TEQ per Mg (7.0 x 10-5 gr of D/
F TEQ per ton) of feed/charge from a scrap dryer/delacquering kiln/
decoating kiln at a secondary aluminum production facility that is a
major or area source; and
(iv) 0.75 kg of HCl per Mg (1.50 lb per ton) of feed/charge from a
scrap dryer/delacquering kiln/decoating kiln at a secondary aluminum
production facility that is a major source.
(2) The owner or operator of a scrap dryer/ delacquering kiln/
decoating kiln at a secondary aluminum production facility that is a
major source must not discharge or cause to be discharged to the
atmosphere visible emissions in excess of 10 percent opacity from any PM
add-on air pollution control device if a COM is chosen as the monitoring
option.
(f) Sweat furnace. The owner or operator of a sweat furnace shall
comply with the emission standard of paragraph (f)(2) of this section.
(1) The owner or operator is not required to conduct a performance
test to demonstrate compliance with the emission standard of paragraph
(f)(2) of this section, provided that, on and after the compliance date
of this rule, the owner or operator operates and maintains an
afterburner with a design residence time of 0.8 seconds or greater and
an operating temperature of 1600 [deg]F or greater.
(2) On and after the compliance date established by Sec. 63.1501,
the owner or operator of a sweat furnace at a secondary aluminum
production facility that is a major or area source must not discharge or
cause to be discharged to the atmosphere emissions in excess of 0.80
nanogram (ng) of D/F TEQ per dscm (3.5x10-10 gr per dscf) at
11 percent oxygen (O\2\).
(g) Dross-only furnace. On and after the compliance date established
by Sec. 63.1501, the owner or operator of a dross-only furnace at a
secondary aluminum production facility that is a major source must not
discharge or cause to be discharged to the atmosphere:
(1) Emissions in excess of 0.15 kg of PM per Mg (0.30 lb of PM per
ton) of feed/charge.
(2) Visible emissions in excess of 10 percent opacity from any PM
add-on air pollution control device if a COM is chosen as the monitoring
option.
(h) Rotary dross cooler. On and after the compliance date
established by Sec. 63.1501, the owner or operator of a rotary dross
cooler at a secondary aluminum production facility that is a major
source must not discharge or cause to be discharged to the atmosphere:
(1) Emissions in excess of 0.09 g of PM per dscm (0.04 gr per dscf).
(2) Visible emissions in excess of 10 percent opacity from any PM
add-on air pollution control device if a COM is chosen as the monitoring
option.
(i) Group 1 furnace. The owner or operator of a group 1 furnace must
use
[[Page 58]]
the limits in this paragraph to determine the emission standards for a
SAPU.
(1) 0.20 kg of PM per Mg (0.40 lb of PM per ton) of feed/charge from
a group 1 furnace, that is not a melting/holding furnace processing only
clean charge, at a secondary aluminum production facility that is a
major source;
(2) 0.40 kg of PM per Mg (0.80 lb of PM per ton) of feed/charge from
a group 1 melting/holding furnace processing only clean charge at a
secondary aluminum production facility that is a major source;
(3) 15 [micro]g of D/F TEQ per Mg (2.1 x 10-4 gr of D/F
TEQ per ton) of feed/charge from a group 1 furnace at a secondary
aluminum production facility that is a major or area source. This limit
does not apply if the furnace processes only clean charge; and
(4) 0.20 kg of HCl per Mg (0.40 lb of HCl per ton) of feed/charge
or, if the furnace is equipped with an add-on air pollution control
device, 10 percent of the uncontrolled HCl emissions, by weight, for a
group 1 furnace at a secondary aluminum production facility that is a
major source.
(5) The owner or operator of a group 1 furnace at a secondary
aluminum production facility that is a major source must not discharge
or cause to be discharged to the atmosphere visible emissions in excess
of 10 percent opacity from any PM add-on air pollution control device if
a COM is chosen as the monitoring option.
(6) The owner or operator may determine the emission standards for a
SAPU by applying the group 1 furnace limits on the basis of the aluminum
production weight in each group 1 furnace, rather than on the basis of
feed/charge.
(7) The owner or operator of a sidewell group 1 furnace that
conducts reactive fluxing (except for cover flux) in the hearth, or that
conducts reactive fluxing in the sidewell at times when the level of
molten metal falls below the top of the passage between the sidewell and
the hearth, must comply with the emission limits of paragraphs (i)(1)
through (4) of this section on the basis of the combined emissions from
the sidewell and the hearth.
(j) In-line fluxer. Except as provided in paragraph (j)(3) of this
section for an in-line fluxer using no reactive flux material, the owner
or operator of an in-line fluxer must use the limits in this paragraph
to determine the emission standards for a SAPU.
(1) 0.02 kg of HCl per Mg (0.04 lb of HCl per ton) of feed/charge;
(2) 0.005 kg of PM per Mg (0.01 lb of PM per ton) of feed/charge.
(3) The emission limits in paragraphs (j)(1) and (j)(2) of this
section do not apply to an in-line fluxer that uses no reactive flux
materials.
(4) The owner or operator of an in-line fluxer at a secondary
aluminum production facility that is a major source must not discharge
or cause to be discharged to the atmosphere visible emissions in excess
of 10 percent opacity from any PM add-on air pollution control device
used to control emissions from the in-line fluxer, if a COM is chosen as
the monitoring option.
(5) The owner or operator may determine the emission standards for a
SAPU by applying the in-line fluxer limits on the basis of the aluminum
production weight in each in-line fluxer, rather than on the basis of
feed/charge.
(k) Secondary aluminum processing unit. On and after the compliance
date established by Sec. 63.1501, the owner or operator must comply
with the emission limits calculated using the equations for PM and HCl
in paragraphs (k)(1) and (2) of this section for each secondary aluminum
processing unit at a secondary aluminum production facility that is a
major source. The owner or operator must comply with the emission limit
calculated using the equation for D/F in paragraph (k)(3) of this
section for each secondary aluminum processing unit at a secondary
aluminum production facility that is a major or area source.
(1) The owner or operator must not discharge or allow to be
discharged to the atmosphere any 3-day, 24-hour rolling average
emissions of PM in excess of:
[[Page 59]]
[GRAPHIC] [TIFF OMITTED] TR23MR00.000
Where,
LtiPM = The PM emission limit for individual emission unit i
in paragraph (i)(1) and (2) of this section for a group 1 furnace or in
paragraph (j)(2) of this section for an in-line fluxer;
Tti = The feed/charge rate for individual emission unit I;
and
LcPM = The PM emission limit for the secondary aluminum
processing unit.
Note: In-line fluxers using no reactive flux materials cannot be
included in this calculation since they are not subject to the PM limit.
(2) The owner or operator must not discharge or allow to be
discharged to the atmosphere any 3-day, 24-hour rolling average
emissions of HCl in excess of:
[GRAPHIC] [TIFF OMITTED] TR30DE02.001
Where,
LtiHCl = The HCl emission limit for individual emission unit
i in paragraph (i)(4) of this section for a group 1 furnace or in
paragraph (j)(1) of this section for an in-line fluxer; and
LcHCl = The HCl emission limit for the secondary aluminum
processing unit.
Note: In-line fluxers using no reactive flux materials cannot be
included in this calculation since they are not subject to the HCl
limit.
(3) The owner or operator must not discharge or allow to be
discharged to the atmosphere any 3-day, 24-hour rolling average
emissions of D/F in excess of:
[GRAPHIC] [TIFF OMITTED] TR23MR00.002
Where,
LtiD/F = The D/F emission limit for individual emission unit
i in paragraph (i)(3) of this section for a group 1 furnace; and
LcD/F = The D/F emission limit for the secondary aluminum
processing unit.
Note: Clean charge furnaces cannot be included in this calculation
since they are not subject to the D/F limit.
(4) The owner or operator of a SAPU at a secondary aluminum
production facility that is a major source may demonstrate compliance
with the emission limits of paragraphs (k)(1) through (3) of this
section by demonstrating that each emission unit within the SAPU is in
compliance with the applicable emission limits of paragraphs (i) and (j)
of this section.
(5) The owner or operator of a SAPU at a secondary aluminum
production facility that is an area source may demonstrate compliance
with the emission limits of paragraph (k)(3) of this section by
demonstrating that each emission unit within the SAPU is in compliance
with the emission limit of paragraph (i)(3) of this section.
(6) With the prior approval of the responsible permitting authority,
an owner or operator may redesignate any existing group 1 furnace or in-
line fluxer at a secondary aluminum production facility as a new
emission unit. Any emission unit so redesignated may thereafter be
included in a new SAPU at that facility. Any such redesignation will be
solely for the purpose of this MACT standard and will be irreversible.
[65 FR 15710, Mar. 23, 2000, as amended at 67 FR 59792, Sept. 24, 2002;
67 FR 79816, Dec. 30, 2002; 70 FR 57517, Oct. 3, 2005]
Sec. 63.1506 Operating requirements.
(a) Summary. (1) On and after the compliance date established by
Sec. 63.1501, the owner or operator must operate all new and existing
affected sources and control equipment according to the requirements in
this section.
(2) The owner or operator of an existing sweat furnace that meets
the specifications of Sec. 63.1505(f)(1) must operate the sweat furnace
and control equipment according to the requirements of this section on
and after the compliance date of this standard.
[[Page 60]]
(3) The owner or operator of a new sweat furnace that meets the
specifications of Sec. 63.1505(f)(1) must operate the sweat furnace and
control equipment according to the requirements of this section by March
23, 2000 or upon startup, whichever is later.
(4) Operating requirements are summarized in Table 2 to this
subpart.
(b) Labeling. The owner or operator must provide and maintain easily
visible labels posted at each group 1 furnace, group 2 furnace, in-line
fluxer and scrap dryer/delacquering kiln/decoating kiln that identifies
the applicable emission limits and means of compliance, including:
(1) The type of affected source or emission unit (e.g., scrap dryer/
delacquering kiln/decoating kiln, group 1 furnace, group 2 furnace, in-
line fluxer).
(2) The applicable operational standard(s) and control method(s)
(work practice or control device). This includes, but is not limited to,
the type of charge to be used for a furnace (e.g., clean scrap only, all
scrap, etc.), flux materials and addition practices, and the applicable
operating parameter ranges and requirements as incorporated in the OM&M
plan.
(3) The afterburner operating temperature and design residence time
for a scrap dryer/delacquering kiln/decoating kiln.
(c) Capture/collection systems. For each affected source or emission
unit equipped with an add-on air pollution control device, the owner or
operator must:
(1) Design and install a system for the capture and collection of
emissions to meet the engineering standards for minimum exhaust rates as
published by the American Conference of Governmental Industrial
Hygienists in chapters 3 and 5 of ``Industrial Ventilation: A Manual of
Recommended Practice'' (incorporated by reference in Sec. 63.1502 of
this subpart);
(2) Vent captured emissions through a closed system, except that
dilution air may be added to emission streams for the purpose of
controlling temperature at the inlet to a fabric filter; and
(3) Operate each capture/collection system according to the
procedures and requirements in the OM&M plan.
(d) Feed/charge weight. The owner or operator of each affected
source or emission unit subject to an emission limit in kg/Mg (lb/ton)
or [micro]g/Mg (gr/ton) of feed/charge must:
(1) Except as provided in paragraph (d)(3) of this section, install
and operate a device that measures and records or otherwise determine
the weight of feed/charge (or throughput) for each operating cycle or
time period used in the performance test; and
(2) Operate each weight measurement system or other weight
determination procedure in accordance with the OM&M plan.
(3) The owner or operator may chose to measure and record aluminum
production weight from an affected source or emission unit rather than
feed/charge weight to an affected source or emission unit, provided
that:
(i) The aluminum production weight, rather than feed/charge weight
is measured and recorded for all emission units within a SAPU; and
(ii) All calculations to demonstrate compliance with the emission
limits for SAPUs are based on aluminum production weight rather than
feed/charge weight.
(e) Aluminum scrap shredder. The owner or operator of a scrap
shredder with emissions controlled by a fabric filter must operate a bag
leak detection system, or a continuous opacity monitor, or conduct
visible emissions observations.
(1) If a bag leak detection system is used to meet the monitoring
requirements in Sec. 63.1510, the owner or operator must:
(i) Initiate corrective action within 1-hour of a bag leak detection
system alarm and complete the corrective action procedures in accordance
with the OM&M plan.
(ii) Operate each fabric filter system such that the bag leak
detection system alarm does not sound more than 5 percent of the
operating time during a 6-month block reporting period. In calculating
this operating time fraction, if inspection of the fabric filter
demonstrates that no corrective action is required, no alarm time is
counted. If corrective action is required, each alarm shall be counted
as a minimum of 1 hour. If the owner or operator
[[Page 61]]
takes longer than 1 hour to initiate corrective action, the alarm time
shall be counted as the actual amount of time taken by the owner or
operator to initiate corrective action.
(2) If a continuous opacity monitoring system is used to meet the
monitoring requirements in Sec. 63.1510, the owner or operator must
initiate corrective action within 1-hour of any 6-minute average reading
of 5 percent or more opacity and complete the corrective action
procedures in accordance with the OM&M plan.
(3) If visible emission observations are used to meet the monitoring
requirements in Sec. 63.1510, the owner or operator must initiate
corrective action within 1-hour of any observation of visible emissions
during a daily visible emissions test and complete the corrective action
procedures in accordance with the OM&M plan.
(f) Thermal chip dryer. The owner or operator of a thermal chip
dryer with emissions controlled by an afterburner must:
(1) Maintain the 3-hour block average operating temperature of each
afterburner at or above the average temperature established during the
performance test.
(2) Operate each afterburner in accordance with the OM&M plan.
(3) Operate each thermal chip dryer using only unpainted aluminum
chips as the feedstock.
(g) Scrap dryer/delacquering kiln/decoating kiln. The owner or
operator of a scrap dryer/delacquering kiln/decoating kiln with
emissions controlled by an afterburner and a lime-injected fabric filter
must:
(1) For each afterburner,
(i) Maintain the 3-hour block average operating temperature of each
afterburner at or above the average temperature established during the
performance test.
(ii) Operate each afterburner in accordance with the OM&M plan.
(2) If a bag leak detection system is used to meet the fabric filter
monitoring requirements in Sec. 63.1510,
(i) Initiate corrective action within 1-hour of a bag leak detection
system alarm and complete any necessary corrective action procedures in
accordance with the OM&M plan.
(ii) Operate each fabric filter system such that the bag leak
detection system alarm does not sound more than 5 percent of the
operating time during a 6-month block reporting period. In calculating
this operating time fraction, if inspection of the fabric filter
demonstrates that no corrective action is required, no alarm time is
counted. If corrective action is required, each alarm shall be counted
as a minimum of 1 hour. If the owner or operator takes longer than 1
hour to initiate corrective action, the alarm time shall be counted as
the actual amount of time taken by the owner or operator to initiate
corrective action.
(3) If a continuous opacity monitoring system is used to meet the
monitoring requirements in Sec. 63.1510, initiate corrective action
within 1-hour of any 6-minute average reading of 5 percent or more
opacity and complete the corrective action procedures in accordance with
the OM&M plan.
(4) Maintain the 3-hour block average inlet temperature for each
fabric filter at or below the average temperature established during the
performance test, plus 14 [deg]C (plus 25 [deg]F).
(5) For a continuous injection device, maintain free-flowing lime in
the hopper to the feed device at all times and maintain the lime feeder
setting at the same level established during the performance test.
(h) Sweat furnace. The owner or operator of a sweat furnace with
emissions controlled by an afterburner must:
(1) Maintain the 3-hour block average operating temperature of each
afterburner at or above:
(i) The average temperature established during the performance test;
or
(ii) 1600 [deg]F if a performance test was not conducted, and the
afterburner meets the specifications of Sec. 63.1505(f)(1).
(2) Operate each afterburner in accordance with the OM&M plan.
(i) Dross-only furnace. The owner or operator of a dross-only
furnace with emissions controlled by a fabric filter must:
(1) If a bag leak detection system is used to meet the monitoring
requirements in Sec. 63.1510,
(i) Initiate corrective action within 1-hour of a bag leak detection
system
[[Page 62]]
alarm and complete the corrective action procedures in accordance with
the OM&M plan.
(ii) Operate each fabric filter system such that the bag leak
detection system alarm does not sound more than 5 percent of the
operating time during a 6-month block reporting period. In calculating
this operating time fraction, if inspection of the fabric filter
demonstrates that no corrective action is required, no alarm time is
counted. If corrective action is required, each alarm shall be counted
as a minimum of 1 hour. If the owner or operator takes longer than 1
hour to initiate corrective action, the alarm time shall be counted as
the actual amount of time taken by the owner or operator to initiate
corrective action.
(2) If a continuous opacity monitoring system is used to meet the
monitoring requirements in Sec. 63.1510, initiate corrective action
within 1-hour of any 6-minute average reading of 5 percent or more
opacity and complete the corrective action procedures in accordance with
the OM&M plan.
(3) Operate each furnace using dross and salt flux as the sole
feedstock.
(j) Rotary dross cooler. The owner or operator of a rotary dross
cooler with emissions controlled by a fabric filter must:
(1) If a bag leak detection system is used to meet the monitoring
requirements in Sec. 63.1510,
(i) Initiate corrective action within 1-hour of a bag leak detection
system alarm and complete the corrective action procedures in accordance
with the OM&M plan.
(ii) Operate each fabric filter system such that the bag leak
detection system alarm does not sound more than 5 percent of the
operating time during a 6-month block reporting period. In calculating
this operating time fraction, if inspection of the fabric filter
demonstrates that no corrective action is required, no alarm time is
counted. If corrective action is required, each alarm shall be counted
as a minimum of 1 hour. If the owner or operator takes longer than 1
hour to initiate corrective action, the alarm time shall be counted as
the actual amount of time taken by the owner or operator to initiate
corrective action.
(2) If a continuous opacity monitoring system is used to meet the
monitoring requirements in Sec. 63.1510, initiate corrective action
within 1 hour of any 6-minute average reading of 5 percent or more
opacity and complete the corrective action procedures in accordance with
the OM&M plan.
(k) In-line fluxer. The owner or operator of an in-line fluxer with
emissions controlled by a lime-injected fabric filter must:
(1) If a bag leak detection system is used to meet the monitoring
requirements in Sec. 63.1510,
(i) Initiate corrective action within 1-hour of a bag leak detection
system alarm and complete the corrective action procedures in accordance
with the OM&M plan.
(ii) Operate each fabric filter system such that the bag leak
detection system alarm does not sound more than 5 percent of the
operating time during a 6-month block reporting period. In calculating
this operating time fraction, if inspection of the fabric filter
demonstrates that no corrective action is required, no alarm time is
counted. If corrective action is required, each alarm shall be counted
as a minimum of 1 hour. If the owner or operator takes longer than 1
hour to initiate corrective action, the alarm time shall be counted as
the actual amount of time taken by the owner or operator to initiate
corrective action.
(2) If a continuous opacity monitoring system is used to meet the
monitoring requirements in Sec. 63.1510, initiate corrective action
within 1 hour of any 6-minute average reading of 5 percent or more
opacity and complete the corrective action procedures in accordance with
the OM&M plan.
(3) For a continuous injection system, maintain free-flowing lime in
the hopper to the feed device at all times and maintain the lime feeder
setting at the same level established during the performance test.
(4) Maintain the total reactive chlorine flux injection rate for
each operating cycle or time period used in the performance test at or
below the average rate established during the performance test.
(l) In-line fluxer using no reactive flux material. The owner or
operator of a
[[Page 63]]
new or existing in-line fluxer using no reactive flux materials must
operate each in-line fluxer using no reactive flux materials.
(m) Group 1 furnace with add-on air pollution control devices. The
owner or operator of a group 1 furnace with emissions controlled by a
lime-injected fabric filter must:
(1) If a bag leak detection system is used to meet the monitoring
requirements in Sec. 63.1510, the owner or operator must:
(i) Initiate corrective action within 1 hour of a bag leak detection
system alarm.
(ii) Complete the corrective action procedures in accordance with
the OM&M plan.
(iii) Operate each fabric filter system such that the bag leak
detection system alarm does not sound more than 5 percent of the
operating time during a 6-month block reporting period. In calculating
this operating time fraction, if inspection of the fabric filter
demonstrates that no corrective action is required, no alarm time is
counted. If corrective action is required, each alarm shall be counted
as a minimum of 1 hour. If the owner or operator takes longer than 1
hour to initiate corrective action, the alarm time shall be counted as
the actual amount of time taken by the owner or operator to initiate
corrective action.
(2) If a continuous opacity monitoring system is used to meet the
monitoring requirements in Sec. 63.1510, the owner or operator must:
(i) Initiate corrective action within 1 hour of any 6-minute average
reading of 5 percent or more opacity; and
(ii) Complete the corrective action procedures in accordance with
the OM&M plan.
(3) Maintain the 3-hour block average inlet temperature for each
fabric filter at or below the average temperature established during the
performance test, plus 14 [deg]C (plus 25 [deg]F).
(4) For a continuous lime injection system, maintain free-flowing
lime in the hopper to the feed device at all times and maintain the lime
feeder setting at the same level established during the performance
test.
(5) Maintain the total reactive chlorine flux injection rate for
each operating cycle or time period used in the performance test at or
below the average rate established during the performance test.
(6) Operate each sidewell furnace such that:
(i) The level of molten metal remains above the top of the passage
between the sidewell and hearth during reactive flux injection, unless
emissions from both the sidewell and the hearth are included in
demonstrating compliance with all applicable emission limits.
(ii) Reactive flux is added only in the sidewell, unless emissions
from both the sidewell and the hearth are included in demonstrating
compliance with all applicable emission limits.
(n) Group 1 furnace without add-on air pollution control devices.
The owner or operator of a group 1 furnace (including a group 1 furnace
that is part of a secondary aluminum processing unit) without add-on air
pollution control devices must:
(1) Maintain the total reactive chlorine flux injection rate for
each operating cycle or time period used in the performance test at or
below the average rate established during the performance test.
(2) Operate each furnace in accordance with the work practice/
pollution prevention measures documented in the OM&M plan and within the
parameter values or ranges established in the OM&M plan.
(3) Operate each group 1 melting/holding furnace subject to the
emission standards in Sec. 63.1505(i)(2) using only clean charge as the
feedstock.
(o) Group 2 furnace. The owner or operator of a new or existing
group 2 furnace must:
(1) Operate each furnace using only clean charge as the feedstock.
(2) Operate each furnace using no reactive flux.
(p) Corrective action. When a process parameter or add-on air
pollution control device operating parameter deviates from the value or
range established during the performance test and incorporated in the
OM&M plan, the owner or operator must initiate corrective action.
Corrective action must restore operation of the affected source or
emission unit (including the process or control device) to its normal or
[[Page 64]]
usual mode of operation as expeditiously as practicable in accordance
with good air pollution control practices for minimizing emissions.
Corrective actions taken must include follow-up actions necessary to
return the process or control device parameter level(s) to the value or
range of values established during the performance test and steps to
prevent the likely recurrence of the cause of a deviation.
[65 FR 15710, Mar. 23, 2000, as amended at 67 FR 59792, Sept. 24, 2002;
67 FR 79816, Dec. 30, 2002; 69 FR 53984, Sept. 3, 2004]
Sec. Sec. 63.1507-63.1509 [Reserved]
Monitoring and Compliance Requirements
Sec. 63.1510 Monitoring requirements.
(a) Summary. On and after the compliance date established by Sec.
63.1501, the owner or operator of a new or existing affected source or
emission unit must monitor all control equipment and processes according
to the requirements in this section. Monitoring requirements for each
type of affected source and emission unit are summarized in Table 3 to
this subpart.
(b) Operation, maintenance, and monitoring (OM&M) plan. The owner or
operator must prepare and implement for each new or existing affected
source and emission unit, a written operation, maintenance, and
monitoring (OM&M) plan. The owner or operator of an existing affected
source must submit the OM&M plan to the responsible permitting authority
no later than the compliance date established by Sec. 63.1501(a). The
owner or operator of any new affected source must submit the OM&M plan
to the responsible permitting authority within 90 days after a
successful initial performance test under Sec. 63.1511(b), or within 90
days after the compliance date established by Sec. 63.1501(b) if no
initial performance test is required. The plan must be accompanied by a
written certification by the owner or operator that the OM&M plan
satisfies all requirements of this section and is otherwise consistent
with the requirements of this subpart. The owner or operator must comply
with all of the provisions of the OM&M plan as submitted to the
permitting authority, unless and until the plan is revised in accordance
with the following procedures. If the permitting authority determines at
any time after receipt of the OM&M plan that any revisions of the plan
are necessary to satisfy the requirements of this section or this
subpart, the owner or operator must promptly make all necessary
revisions and resubmit the revised plan. If the owner or operator
determines that any other revisions of the OM&M plan are necessary, such
revisions will not become effective until the owner or operator submits
a description of the changes and a revised plan incorporating them to
the permitting authority. Each plan must contain the following
information:
(1) Process and control device parameters to be monitored to
determine compliance, along with established operating levels or ranges,
as applicable, for each process and control device.
(2) A monitoring schedule for each affected source and emission
unit.
(3) Procedures for the proper operation and maintenance of each
process unit and add-on control device used to meet the applicable
emission limits or standards in Sec. 63.1505.
(4) Procedures for the proper operation and maintenance of
monitoring devices or systems used to determine compliance, including:
(i) Calibration and certification of accuracy of each monitoring
device, at least once every 6 months, according to the manufacturer's
instructions; and
(ii) Procedures for the quality control and quality assurance of
continuous emission or opacity monitoring systems as required by the
general provisions in subpart A of this part.
(5) Procedures for monitoring process and control device parameters,
including procedures for annual inspections of afterburners, and if
applicable, the procedure to be used for determining charge/feed (or
throughput) weight if a measurement device is not used.
(6) Corrective actions to be taken when process or operating
parameters or add-on control device parameters deviate from the value or
range established in paragraph (b)(1) of this section, including:
[[Page 65]]
(i) Procedures to determine and record the cause of any deviation or
excursion, and the time the deviation or excursion began and ended; and
(ii) Procedures for recording the corrective action taken, the time
corrective action was initiated, and the time/date corrective action was
completed.
(7) A maintenance schedule for each process and control device that
is consistent with the manufacturer's instructions and recommendations
for routine and long-term maintenance.
(8) Documentation of the work practice and pollution prevention
measures used to achieve compliance with the applicable emission limits
and a site-specific monitoring plan as required in paragraph (o) of this
section for each group 1 furnace not equipped with an add-on air
pollution control device.
(c) Labeling. The owner or operator must inspect the labels for each
group 1 furnace, group 2 furnace, in-line fluxer and scrap dryer/
delacquering kiln/decoating kiln at least once per calendar month to
confirm that posted labels as required by the operational standard in
Sec. 63.1506(b) are intact and legible.
(d) Capture/collection system. The owner or operator must:
(1) Install, operate, and maintain a capture/collection system for
each affected source and emission unit equipped with an add-on air
pollution control device; and
(2) Inspect each capture/collection and closed vent system at least
once each calendar year to ensure that each system is operating in
accordance with the operating requirements in Sec. 63.1506(c) and
record the results of each inspection.
(e) Feed/charge weight. The owner or operator of an affected source
or emission unit subject to an emission limit in kg/Mg (lb/ton) or
[micro]g/Mg (gr/ton) of feed/charge must install, calibrate, operate,
and maintain a device to measure and record the total weight of feed/
charge to, or the aluminum production from, the affected source or
emission unit over the same operating cycle or time period used in the
performance test. Feed/charge or aluminum production within SAPUs must
be measured and recorded on an emission unit-by-emission unit basis. As
an alternative to a measurement device, the owner or operator may use a
procedure acceptable to the applicable permitting authority to determine
the total weight of feed/charge or aluminum production to the affected
source or emission unit.
(1) The accuracy of the weight measurement device or procedure must
be 1 percent of the weight being measured. The
owner or operator may apply to the permitting agency for approval to use
a device of alternative accuracy if the required accuracy cannot be
achieved as a result of equipment layout or charging practices. A device
of alternative accuracy will not be approved unless the owner or
operator provides assurance through data and information that the
affected source will meet the relevant emission standard.
(2) The owner or operator must verify the calibration of the weight
measurement device in accordance with the schedule specified by the
manufacturer, or if no calibration schedule is specified, at least once
every 6 months.
(f) Fabric filters and lime-injected fabric filters. The owner or
operator of an affected source or emission unit using a fabric filter or
lime-injected fabric filter to comply with the requirements of this
subpart must install, calibrate, maintain, and continuously operate a
bag leak detection system as required in paragraph (f)(1) of this
section or a continuous opacity monitoring system as required in
paragraph (f)(2) of this section. The owner or operator of an aluminum
scrap shredder must install and operate a bag leak detection system as
required in paragraph (f)(1) of this section, install and operate a
continuous opacity monitoring system as required in paragraph (f)(2) of
this section, or conduct visible emission observations as required in
paragraph (f)(3) of this section.
(1) These requirements apply to the owner or operator of a new or
existing affected source or existing emission unit using a bag leak
detection system.
(i) The owner or operator must install and operate a bag leak
detection system for each exhaust stack of a fabric filter.
[[Page 66]]
(ii) Each triboelectric bag leak detection system must be installed,
calibrated, operated, and maintained according to the ``Fabric Filter
Bag Leak Detection Guidance,'' (September 1997). This document is
available from the U.S. Environmental Protection Agency; Office of Air
Quality Planning and Standards; Emissions, Monitoring and Analysis
Division; Emission Measurement Center (MD-19), Research Triangle Park,
NC 27711. This document also is available on the Technology Transfer
Network (TTN) under Emission Measurement Technical Information (EMTIC),
Continuous Emission Monitoring. Other bag leak detection systems must be
installed, operated, calibrated, and maintained in a manner consistent
with the manufacturer's written specifications and recommendations.
(iii) The bag leak detection system must be certified by the
manufacturer to be capable of detecting PM emissions at concentrations
of 10 milligrams per actual cubic meter (0.0044 grains per actual cubic
foot) or less.
(iv) The bag leak detection system sensor must provide output of
relative or absolute PM loadings.
(v) The bag leak detection system must be equipped with a device to
continuously record the output signal from the sensor.
(vi) The bag leak detection system must be equipped with an alarm
system that will sound automatically when an increase in relative PM
emissions over a preset level is detected. The alarm must be located
where it is easily heard by plant operating personnel.
(vii) For positive pressure fabric filter systems, a bag leak
detection system must be installed in each baghouse compartment or cell.
For negative pressure or induced air fabric filters, the bag leak
detector must be installed downstream of the fabric filter.
(viii) Where multiple detectors are required, the system's
instrumentation and alarm may be shared among detectors.
(ix) The baseline output must be established by adjusting the range
and the averaging period of the device and establishing the alarm set
points and the alarm delay time.
(x) Following initial adjustment of the system, the owner or
operator must not adjust the sensitivity or range, averaging period,
alarm set points, or alarm delay time except as detailed in the OM&M
plan. In no case may the sensitivity be increased by more than 100
percent or decreased more than 50 percent over a 365-day period unless
such adjustment follows a complete fabric filter inspection which
demonstrates that the fabric filter is in good operating condition.
(2) These requirements apply to the owner or operator of a new or
existing affected source or an existing emission unit using a continuous
opacity monitoring system.
(i) The owner or operator must install, calibrate, maintain, and
operate a continuous opacity monitoring system to measure and record the
opacity of emissions exiting each exhaust stack.
(ii) Each continuous opacity monitoring system must meet the design
and installation requirements of Performance Specification 1 in appendix
B to 40 CFR part 60.
(3) These requirements apply to the owner or operator of a new or
existing aluminum scrap shredder who conducts visible emission
observations. The owner or operator must:
(i) Perform a visible emissions test for each aluminum scrap
shredder using a certified observer at least once a day according to the
requirements of Method 9 in appendix A to 40 CFR part 60. Each Method 9
test must consist of five 6-minute observations in a 30-minute period;
and
(ii) Record the results of each test.
(g) Afterburner. These requirements apply to the owner or operator
of an affected source using an afterburner to comply with the
requirements of this subpart.
(1) The owner or operator must install, calibrate, maintain, and
operate a device to continuously monitor and record the operating
temperature of the afterburner consistent with the requirements for
continuous monitoring systems in subpart A of this part.
(2) The temperature monitoring device must meet each of these
performance and equipment specifications:
[[Page 67]]
(i) The temperature monitoring device must be installed at the exit
of the combustion zone of each afterburner.
(ii) The monitoring system must record the temperature in 15-minute
block averages and determine and record the average temperature for each
3-hour block period.
(iii) The recorder response range must include zero and 1.5 times
the average temperature established according to the requirements in
Sec. 63.1512(m).
(iv) The reference method must be a National Institute of Standards
and Technology calibrated reference thermocouple-potentiometer system or
alternate reference, subject to approval by the Administrator.
(3) The owner or operator must conduct an inspection of each
afterburner at least once a year and record the results. At a minimum,
an inspection must include:
(i) Inspection of all burners, pilot assemblies, and pilot sensing
devices for proper operation and clean pilot sensor;
(ii) Inspection for proper adjustment of combustion air;
(iii) Inspection of internal structures (e.g., baffles) to ensure
structural integrity;
(iv) Inspection of dampers, fans, and blowers for proper operation;
(v) Inspection for proper sealing;
(vi) Inspection of motors for proper operation;
(vii) Inspection of combustion chamber refractory lining and clean
and replace lining as necessary;
(viii) Inspection of afterburner shell for corrosion and/or hot
spots;
(ix) Documentation, for the burn cycle that follows the inspection,
that the afterburner is operating properly and any necessary adjustments
have been made; and
(x) Verification that the equipment is maintained in good operating
condition.
(xi) Following an equipment inspection, all necessary repairs must
be completed in accordance with the requirements of the OM&M plan.
(h) Fabric filter inlet temperature. These requirements apply to the
owner or operator of a scrap dryer/delacquering kiln/decoating kiln or a
group 1 furnace using a lime-injected fabric filter to comply with the
requirements of this subpart.
(1) The owner or operator must install, calibrate, maintain, and
operate a device to continuously monitor and record the temperature of
the fabric filter inlet gases consistent with the requirements for
continuous monitoring systems in subpart A of this part.
(2) The temperature monitoring device must meet each of these
performance and equipment specifications:
(i) The monitoring system must record the temperature in 15-minute
block averages and calculate and record the average temperature for each
3-hour block period.
(ii) The recorder response range must include zero and 1.5 times the
average temperature established according to the requirements in Sec.
63.1512(n).
(iii) The reference method must be a National Institute of Standards
and Technology calibrated reference thermocouple-potentiometer system or
alternate reference, subject to approval by the Administrator.
(i) Lime injection. These requirements apply to the owner or
operator of an affected source or emission unit using a lime-injected
fabric filter to comply with the requirements of this subpart.
(1) The owner or operator of a continuous lime injection system must
verify that lime is always free-flowing by either:
(i) Inspecting each feed hopper or silo at least once each 8-hour
period and recording the results of each inspection. If lime is found
not to be free-flowing during any of the 8-hour periods, the owner or
operator must increase the frequency of inspections to at least once
every 4-hour period for the next 3 days. The owner or operator may
return to inspections at least once every 8 hour period if corrective
action results in no further blockages of lime during the 3-day period;
or
(ii) Subject to the approval of the permitting agency, installing,
operating and maintaining a load cell, carrier gas/lime flow indicator,
carrier gas pressure drop measurement system or other system to confirm
that lime is free-flowing. If lime is found not to be free-flowing, the
owner or operator
[[Page 68]]
must promptly initiate and complete corrective action, or
(iii) Subject to the approval of the permitting agency, installing,
operating and maintaining a device to monitor the concentration of HCl
at the outlet of the fabric filter. If an increase in the concentration
of HCl indicates that the lime is not free-flowing, the owner or
operator must promptly initiate and complete corrective action.
(2) The owner or operator of a continuous lime injection system must
record the lime feeder setting once each day of operation.
(3) An owner or operator who intermittently adds lime to a lime
coated fabric filter must obtain approval from the permitting authority
for a lime addition monitoring procedure. The permitting authority will
not approve a monitoring procedure unless data and information are
submitted establishing that the procedure is adequate to ensure that
relevant emission standards will be met on a continuous basis.
(j) Total reactive flux injection rate. These requirements apply to
the owner or operator of a group 1 furnace (with or without add-on air
pollution control devices) or in-line fluxer. The owner or operator
must:
(1) Install, calibrate, operate, and maintain a device to
continuously measure and record the weight of gaseous or liquid reactive
flux injected to each affected source or emission unit.
(i) The monitoring system must record the weight for each 15-minute
block period, during which reactive fluxing occurs, over the same
operating cycle or time period used in the performance test.
(ii) The accuracy of the weight measurement device must be 1 percent of the weight of the reactive component of the
flux being measured. The owner or operator may apply to the permitting
authority for permission to use a weight measurement device of
alternative accuracy in cases where the reactive flux flow rates are so
low as to make the use of a weight measurement device of 1 percent impracticable. A device of alternative
accuracy will not be approved unless the owner or operator provides
assurance through data and information that the affected source will
meet the relevant emission standards.
(iii) The owner or operator must verify the calibration of the
weight measurement device in accordance with the schedule specified by
the manufacturer, or if no calibration schedule is specified, at least
once every 6 months.
(2) Calculate and record the gaseous or liquid reactive flux
injection rate (kg/Mg or lb/ton) for each operating cycle or time period
used in the performance test using the procedure in Sec. 63.1512(o).
(3) Record, for each 15-minute block period during each operating
cycle or time period used in the performance test during which reactive
fluxing occurs, the time, weight, and type of flux for each addition of:
(i) Gaseous or liquid reactive flux other than chlorine; and
(ii) Solid reactive flux.
(4) Calculate and record the total reactive flux injection rate for
each operating cycle or time period used in the performance test using
the procedure in Sec. 63.1512(o).
(5) The owner or operator of a group 1 furnace or in-line fluxer
performing reactive fluxing may apply to the Administrator for approval
of an alternative method for monitoring and recording the total reactive
flux addition rate based on monitoring the weight or quantity of
reactive flux per ton of feed/charge for each operating cycle or time
period used in the performance test. An alternative monitoring method
will not be approved unless the owner or operator provides assurance
through data and information that the affected source will meet the
relevant emission standards on a continuous basis.
(k) Thermal chip dryer. These requirements apply to the owner or
operator of a thermal chip dryer with emissions controlled by an
afterburner. The owner or operator must:
(1) Record the type of materials charged to the unit for each
operating cycle or time period used in the performance test.
(2) Submit a certification of compliance with the applicable
operational standard for charge materials in Sec. 63.1506(f)(3) for
each 6-month reporting
[[Page 69]]
period. Each certification must contain the information in Sec.
63.1516(b)(2)(i).
(l) Dross-only furnace. These requirements apply to the owner or
operator of a dross-only furnace. The owner or operator must:
(1) Record the materials charged to each unit for each operating
cycle or time period used in the performance test.
(2) Submit a certification of compliance with the applicable
operational standard for charge materials in Sec. 63.1506(i)(3) for
each 6-month reporting period. Each certification must contain the
information in Sec. 63.1516(b)(2)(ii).
(m) In-line fluxers using no reactive flux. The owner or operator of
an in-line fluxer that uses no reactive flux materials must submit a
certification of compliance with the operational standard for no
reactive flux materials in Sec. 63.1506(l) for each 6-month reporting
period. Each certification must contain the information in Sec.
63.1516(b)(2)(vi).
(n) Sidewell group 1 furnace with add-on air pollution control
devices. These requirements apply to the owner or operator of a sidewell
group 1 furnace using add-on air pollution control devices. The owner or
operator must:
(1) Record in an operating log for each charge of a sidewell furnace
that the level of molten metal was above the top of the passage between
the sidewell and hearth during reactive flux injection, unless the
furnace hearth was also equipped with an add-on control device.
(2) Submit a certification of compliance with the operational
standards in Sec. 63.1506(m)(7) for each 6-month reporting period. Each
certification must contain the information in Sec. 63.1516(b)(2)(iii).
(o) Group 1 furnace without add-on air pollution control devices.
These requirements apply to the owner or operator of a group 1 furnace
that is not equipped with an add-on air pollution control device.
(1) The owner or operator must develop, in consultation with the
responsible permitting authority, a written site-specific monitoring
plan. The site-specific monitoring plan must be submitted to the
permitting authority as part of the OM&M plan. The site-specific
monitoring plan must contain sufficient procedures to ensure continuing
compliance with all applicable emission limits and must demonstrate,
based on documented test results, the relationship between emissions of
PM, HCl, and D/F and the proposed monitoring parameters for each
pollutant. Test data must establish the highest level of PM, HCl, and D/
F that will be emitted from the furnace. This may be determined by
conducting performance tests and monitoring operating parameters while
charging the furnace with feed/charge materials containing the highest
anticipated levels of oils and coatings and fluxing at the highest
anticipated rate. If the permitting authority determines that any
revisions of the site-specific monitoring plan are necessary to meet the
requirements of this section or this subpart, the owner or operator must
promptly make all necessary revisions and resubmit the revised plan to
the permitting authority.
(i) The owner or operator of an existing affected source must submit
the site-specific monitoring plan to the applicable permitting authority
for review at least 6 months prior to the compliance date.
(ii) The permitting authority will review and approve or disapprove
a proposed plan, or request changes to a plan, based on whether the plan
contains sufficient provisions to ensure continuing compliance with
applicable emission limits and demonstrates, based on documented test
results, the relationship between emissions of PM, HCl, and D/F and the
proposed monitoring parameters for each pollutant. Test data must
establish the highest level of PM, HCl, and D/F that will be emitted
from the furnace. Subject to permitting agency approval of the OM&M
plan, this may be determined by conducting performance tests and
monitoring operating parameters while charging the furnace with feed/
charge materials containing the highest anticipated levels of oils and
coatings and fluxing at the highest anticipated rate.
(2) Each site-specific monitoring plan must document each work
practice, equipment/design practice, pollution prevention practice, or
other measure
[[Page 70]]
used to meet the applicable emission standards.
(3) Each site-specific monitoring plan must include provisions for
unit labeling as required in paragraph (c) of this section, feed/charge
weight measurement (or production weight measurement) as required in
paragraph (e) of this section and flux weight measurement as required in
paragraph (j) of this section.
(4) Each site-specific monitoring plan for a melting/holding furnace
subject to the clean charge emission standard in Sec. 63.1505(i)(3)
must include these requirements:
(i) The owner or operator must record the type of feed/ charge
(e.g., ingot, thermally dried chips, dried scrap, etc.) for each
operating cycle or time period used in the performance test; and
(ii) The owner or operator must submit a certification of compliance
with the applicable operational standard for clean charge materials in
Sec. 63.1506(n)(3) for each 6-month reporting period. Each
certification must contain the information in Sec. 63.1516(b)(2)(iv).
(5) If a continuous emission monitoring system is included in a
site-specific monitoring plan, the plan must include provisions for the
installation, operation, and maintenance of the system to provide
quality-assured measurements in accordance with all applicable
requirements of the general provisions in subpart A of this part.
(6) If a continuous opacity monitoring system is included in a site-
specific monitoring plan, the plan must include provisions for the
installation, operation, and maintenance of the system to provide
quality-assured measurements in accordance with all applicable
requirements of this subpart.
(7) If a site-specific monitoring plan includes a scrap inspection
program for monitoring the scrap contaminant level of furnace feed/
charge materials, the plan must include provisions for the demonstration
and implementation of the program in accordance with all applicable
requirements in paragraph (p) of this section.
(8) If a site-specific monitoring plan includes a calculation method
for monitoring the scrap contaminant level of furnace feed/charge
materials, the plan must include provisions for the demonstration and
implementation of the program in accordance with all applicable
requirements in paragraph (q) of this section.
(p) Scrap inspection program for group 1 furnace without add-on air
pollution control devices. A scrap inspection program must include:
(1) A proven method for collecting representative samples and
measuring the oil and coatings content of scrap samples;
(2) A scrap inspector training program;
(3) An established correlation between visual inspection and
physical measurement of oil and coatings content of scrap samples;
(4) Periodic physical measurements of oil and coatings content of
randomly-selected scrap samples and comparison with visual inspection
results;
(5) A system for assuring that only acceptable scrap is charged to
an affected group 1 furnace; and
(6) Recordkeeping requirements to document conformance with plan
requirements.
(q) Monitoring of scrap contamination level by calculation method
for group 1 furnace without add-on air pollution control devices. The
owner or operator of a group 1 furnace dedicated to processing a
distinct type of furnace feed/charge composed of scrap with a uniform
composition (such as rejected product from a manufacturing process for
which the coating-to-scrap ratio can be documented) may include a
program in the site-specific monitoring plan for determining,
monitoring, and certifying the scrap contaminant level using a
calculation method rather than a scrap inspection program. A scrap
contaminant monitoring program using a calculation method must include:
(1) Procedures for the characterization and documentation of the
contaminant level of the scrap prior to the performance test.
(2) Limitations on the furnace feed/charge to scrap of the same
composition as that used in the performance test. If the performance
test was conducted with a mixture of scrap and clean charge, limitations
on the proportion of scrap in the furnace feed/
[[Page 71]]
charge to no greater than the proportion used during the performance
test.
(3) Operating, monitoring, recordkeeping, and reporting requirements
to ensure that no scrap with a contaminant level higher than that used
in the performance test is charged to the furnace.
(r) Group 2 furnace. These requirements apply to the owner or
operator of a new or existing group 2 furnace. The owner or operator
must:
(1) Record a description of the materials charged to each furnace,
including any nonreactive, non-HAP-containing/non-HAP-generating fluxing
materials or agents.
(2) Submit a certification of compliance with the applicable
operational standard for charge materials in Sec. 63.1506(o) for each
6-month reporting period. Each certification must contain the
information in Sec. 63.1516(b)(2)(v).
(s) Site-specific requirements for secondary aluminum processing
units. (1) An owner or operator of a secondary aluminum processing unit
at a facility must include, within the OM&M plan prepared in accordance
with Sec. 63.1510(b), the following information:
(i) The identification of each emission unit in the secondary
aluminum processing unit;
(ii) The specific control technology or pollution prevention measure
to be used for each emission unit in the secondary aluminum processing
unit and the date of its installation or application;
(iii) The emission limit calculated for each secondary aluminum
processing unit and performance test results with supporting
calculations demonstrating initial compliance with each applicable
emission limit;
(iv) Information and data demonstrating compliance for each emission
unit with all applicable design, equipment, work practice or operational
standards of this subpart; and
(v) The monitoring requirements applicable to each emission unit in
a secondary aluminum processing unit and the monitoring procedures for
daily calculation of the 3-day, 24-hour rolling average using the
procedure in Sec. 63.1510(t).
(2) The SAPU compliance procedures within the OM&M plan may not
contain any of the following provisions:
(i) Any averaging among emissions of differing pollutants;
(ii) The inclusion of any affected sources other than emission units
in a secondary aluminum processing unit;
(iii) The inclusion of any emission unit while it is shutdown; or
(iv) The inclusion of any periods of startup, shutdown, or
malfunction in emission calculations.
(3) To revise the SAPU compliance provisions within the OM&M plan
prior to the end of the permit term, the owner or operator must submit a
request to the applicable permitting authority containing the
information required by paragraph (s)(1) of this section and obtain
approval of the applicable permitting authority prior to implementing
any revisions.
(t) Secondary aluminum processing unit. Except as provided in
paragraph (u) of this section, the owner or operator must calculate and
record the 3-day, 24-hour rolling average emissions of PM, HCl, and D/F
for each secondary aluminum processing unit on a daily basis. To
calculate the 3-day, 24-hour rolling average, the owner or operator
must:
(1) Calculate and record the total weight of material charged to
each emission unit in the secondary aluminum processing unit for each
24-hour day of operation using the feed/charge weight information
required in paragraph (e) of this section. If the owner or operator
chooses to comply on the basis of weight of aluminum produced by the
emission unit, rather than weight of material charged to the emission
unit, all performance test emissions results and all calculations must
be conducted on the aluminum production weight basis.
(2) Multiply the total feed/charge weight to the emission unit, or
the weight of aluminum produced by the emission unit, for each emission
unit for the 24-hour period by the emission rate (in lb/ton of feed/
charge) for that emission unit (as determined during the performance
test) to provide emissions for each emission unit for the 24-hour
period, in pounds.
[[Page 72]]
(3) Divide the total emissions for each SAPU for the 24-hour period
by the total material charged to the SAPU, or the weight of aluminum
produced by the SAPU over the 24-hour period to provide the daily
emission rate for the SAPU.
(4) Compute the 24-hour daily emission rate using Equation 4:
[GRAPHIC] [TIFF OMITTED] TR23MR00.003
Where,
Eday = The daily PM, HCl, or D/F emission rate for the
secondary aluminum processing unit for the 24-hour period;
Ti = The total amount of feed, or aluminum produced, for
emission unit i for the 24-hour period (tons or Mg);
ERi = The measured emission rate for emission unit i as
determined in the performance test (lb/ton or [micro]g/Mg of feed/
charge); and
n = The number of emission units in the secondary aluminum processing
unit.
(5) Calculate and record the 3-day, 24-hour rolling average for each
pollutant each day by summing the daily emission rates for each
pollutant over the 3 most recent consecutive days and dividing by 3.
(u) Secondary aluminum processing unit compliance by individual
emission unit demonstration. As an alternative to the procedures of
paragraph (t) of this section, an owner or operator may demonstrate,
through performance tests, that each individual emission unit within the
secondary aluminum production unit is in compliance with the applicable
emission limits for the emission unit.
(v) Alternative monitoring method for lime addition. The owner or
operator of a lime-coated fabric filter that employs intermittent or
noncontinuous lime addition may apply to the Administrator for approval
of an alternative method for monitoring the lime addition schedule and
rate based on monitoring the weight of lime added per ton of feed/charge
for each operating cycle or time period used in the performance test. An
alternative monitoring method will not be approved unless the owner or
operator provides assurance through data and information that the
affected source will meet the relevant emission standards on a
continuous basis.
(w) Alternative monitoring methods. If an owner or operator wishes
to use an alternative monitoring method to demonstrate compliance with
any emission standard in this subpart, other than those alternative
monitoring methods which may be authorized pursuant to Sec.
63.1510(j)(5) and Sec. 63.1510(v), the owner or operator may submit an
application to the Administrator. Any such application will be processed
according to the criteria and procedures set forth in paragraphs (w)(1)
through (6) of this section.
(1) The Administrator will not approve averaging periods other than
those specified in this section.
(2) The owner or operator must continue to use the original
monitoring requirement until necessary data are submitted and approval
is received to use another monitoring procedure.
(3) The owner or operator shall submit the application for approval
of alternate monitoring methods no later than the notification of the
performance test. The application must contain the information specified
in paragraphs (w)(3) (i) through (iii) of this section:
(i) Data or information justifying the request, such as the
technical or economic infeasibility, or the impracticality of using the
required approach;
(ii) A description of the proposed alternative monitoring
requirements, including the operating parameters to be monitored, the
monitoring approach and technique, and how the limit is to be
calculated; and
(iii) Data and information documenting that the alternative
monitoring requirement(s) would provide equivalent or better assurance
of compliance with the relevant emission standard(s).
(4) The Administrator will not approve an alternate monitoring
application unless it would provide equivalent or better assurance of
compliance with the relevant emission standard(s). Before disapproving
any alternate monitoring application, the Administrator will provide:
[[Page 73]]
(i) Notice of the information and findings upon which the intended
disapproval is based; and
(ii) Notice of opportunity for the owner or operator to present
additional supporting information before final action is taken on the
application. This notice will specify how much additional time is
allowed for the owner or operator to provide additional supporting
information.
(5) The owner or operator is responsible for submitting any
supporting information in a timely manner to enable the Administrator to
consider the application prior to the performance test. Neither
submittal of an application nor the Administrator's failure to approve
or disapprove the application relieves the owner or operator of the
responsibility to comply with any provisions of this subpart.
(6) The Administrator may decide at any time, on a case-by-case
basis, that additional or alternative operating limits, or alternative
approaches to establishing operating limits, are necessary to
demonstrate compliance with the emission standards of this subpart.
[65 FR 15710, Mar. 23, 2000, as amended at 67 FR 59792, Sept. 24, 2002;
67 FR 79816, Dec. 30, 2002; 69 FR 53984, Sept. 3, 2004]
Sec. 63.1511 Performance test/compliance demonstration general
requirements.
(a) Site-specific test plan. Prior to conducting any performance
test required by this subpart, the owner or operator must prepare a
site-specific test plan which satisfies all of the requirements, and
must obtain approval of the plan pursuant to the procedures, set forth
in Sec. 63.7(c).
(b) Initial performance test. Following approval of the site-
specific test plan, the owner or operator must demonstrate initial
compliance with each applicable emission, equipment, work practice, or
operational standard for each affected source and emission unit, and
report the results in the notification of compliance status report as
described in Sec. 63.1515(b). The owner or operator of any existing
affected source for which an initial performance test is required to
demonstrate compliance must conduct this initial performance test no
later than the date for compliance established by Sec. 63.1501(a). The
owner or operator of any new affected source for which an initial
performance test is required must conduct this initial performance test
within 90 days after the date for compliance established by Sec.
63.1501(b). Except for the date by which the performance test must be
conducted, the owner or operator must conduct each performance test in
accordance with the requirements and procedures set forth in Sec.
63.7(c). Owners or operators of affected sources located at facilities
which are area sources are subject only to those performance testing
requirements pertaining to D/F. Owners or operators of sweat furnaces
meeting the specifications of Sec. 63.1505(f)(1) are not required to
conduct a performance test.
(1) The owner or operator must conduct each test while the affected
source or emission unit is operating at the highest production level
with charge materials representative of the range of materials processed
by the unit and, if applicable, at the highest reactive fluxing rate.
(2) Each performance test for a continuous process must consist of 3
separate runs; pollutant sampling for each run must be conducted for the
time period specified in the applicable method or, in the absence of a
specific time period in the test method, for a minimum of 3 hours.
(3) Each performance test for a batch process must consist of three
separate runs; pollutant sampling for each run must be conducted over
the entire process operating cycle.
(4) Where multiple affected sources or emission units are exhausted
through a common stack, pollutant sampling for each run must be
conducted over a period of time during which all affected sources or
emission units complete at least 1 entire process operating cycle or for
24 hours, whichever is shorter.
(5) Initial compliance with an applicable emission limit or standard
is demonstrated if the average of three runs conducted during the
performance test is less than or equal to the applicable emission limit
or standard.
(c) Test methods. The owner or operator must use the following
methods in
[[Page 74]]
appendix A to 40 CFR part 60 to determine compliance with the applicable
emission limits or standards:
(1) Method 1 for sample and velocity traverses.
(2) Method 2 for velocity and volumetric flow rate.
(3) Method 3 for gas analysis.
(4) Method 4 for moisture content of the stack gas.
(5) Method 5 for the concentration of PM.
(6) Method 9 for visible emission observations.
(7) Method 23 for the concentration of D/F.
(8) Method 25A for the concentration of THC, as propane.
(9) Method 26A for the concentration of HCl. Where a lime-injected
fabric filter is used as the control device to comply with the 90
percent reduction standard, the owner or operator must measure the
fabric filter inlet concentration of HCl at a point before lime is
introduced to the system.
(d) Alternative methods. The owner or operator may use an
alternative test method, subject to approval by the Administrator.
(e) Repeat tests. The owner or operator of new or existing affected
sources and emission units located at secondary aluminum production
facilities that are major sources must conduct a performance test every
5 years following the initial performance test.
(f) Testing of representative emission units. With the prior
approval of the permitting authority, an owner or operator may utilize
emission rates obtained by testing a particular type of group 1 furnace
which is not controlled by any add-on control device, or by testing an
in-line flux box which is not controlled by any add-on control device,
to determine the emission rate for other units of the same type at the
same facility. Such emission test results may only be considered to be
representative of other units if all of the following criteria are
satisfied:
(1) The tested emission unit must use feed materials and charge
rates which are comparable to the emission units that it represents;
(2) The tested emission unit must use the same type of flux
materials in the same proportions as the emission units it represents;
(3) The tested emission unit must be operated utilizing the same
work practices as the emission units that it represents;
(4) The tested emission unit must be of the same design as the
emission units that it represents; and
(5) The tested emission unit must be tested under the highest load
or capacity reasonably expected to occur for any of the emission units
that it represents.
(g) Establishment of monitoring and operating parameter values. The
owner or operator of new or existing affected sources and emission units
must establish a minimum or maximum operating parameter value, or an
operating parameter range for each parameter to be monitored as required
by Sec. 63.1510 that ensures compliance with the applicable emission
limit or standard. To establish the minimum or maximum value or range,
the owner or operator must use the appropriate procedures in this
section and submit the information required by Sec. 63.1515(b)(4) in
the notification of compliance status report. The owner or operator may
use existing data in addition to the results of performance tests to
establish operating parameter values for compliance monitoring provided
each of the following conditions are met to the satisfaction of the
applicable permitting authority:
(1) The complete emission test report(s) used as the basis of the
parameter(s) is submitted.
(2) The same test methods and procedures as required by this subpart
were used in the test.
(3) The owner or operator certifies that no design or work practice
changes have been made to the source, process, or emission control
equipment since the time of the report.
(4) All process and control equipment operating parameters required
to be monitored were monitored as required in this subpart and
documented in the test report.
(h) Testing of commonly-ducted units within a secondary aluminum
processing unit. When group 1 furnaces and/or in-line fluxers are
included in a single existing SAPU or new SAPU, and the emissions from
more than one emission
[[Page 75]]
unit within that existing SAPU or new SAPU are manifolded to a single
control device, compliance for all units within the SAPU is demonstrated
if the total measured emissions from all controlled and uncontrolled
units in the SAPU do not exceed the emission limits calculated for that
SAPU based on the applicable equation in Sec. 63.1505(k).
(i) Testing of commonly-ducted units not within a secondary aluminum
processing unit. With the prior approval of the permitting authority, an
owner or operator may do combined performance testing of two or more
individual affected sources or emission units which are not included in
a single existing SAPU or new SAPU, but whose emissions are manifolded
to a single control device. Any such performance testing of commonly-
ducted units must satisfy the following basic requirements:
(1) All testing must be designed to verify that each affected source
or emission unit individually satisfies all emission requirements
applicable to that affected source or emission unit;
(2) All emissions of pollutants subject to a standard must be tested
at the outlet from each individual affected source or emission unit
while operating under the highest load or capacity reasonably expected
to occur, and prior to the point that the emissions are manifolded
together with emissions from other affected sources or emission units;
(3) The combined emissions from all affected sources and emission
units which are manifolded to a single emission control device must be
tested at the outlet of the emission control device;
(4) All tests at the outlet of the emission control device must be
conducted with all affected sources and emission units whose emissions
are manifolded to the control device operating simultaneously under the
highest load or capacity reasonably expected to occur; and
(5) For purposes of demonstrating compliance of a commonly-ducted
unit with any emission limit for a particular type of pollutant, the
emissions of that pollutant by the individual unit shall be presumed to
be controlled by the same percentage as total emissions of that
pollutant from all commonly-ducted units are controlled at the outlet of
the emission control device.
[65 FR 15710, Mar. 23, 2000, as amended at 67 FR 59792, Sept. 24, 2002;
67 FR 79817, Dec. 30, 2002]
Sec. 63.1512 Performance test/compliance demonstration requirements and
procedures.
(a) Aluminum scrap shredder. The owner or operator must conduct
performance tests to measure PM emissions at the outlet of the control
system. If visible emission observations is the selected monitoring
option, the owner or operator must record visible emission observations
from each exhaust stack for all consecutive 6-minute periods during the
PM emission test according to the requirements of Method 9 in appendix A
to 40 CFR part 60.
(b) Thermal chip dryer. The owner or operator must conduct a
performance test to measure THC and D/F emissions at the outlet of the
control device while the unit processes only unpainted aluminum chips.
(c) Scrap dryer/delacquering kiln/decoating kiln. The owner or
operator must conduct performance tests to measure emissions of THC, D/
F, HCl, and PM at the outlet of the control device.
(1) If the scrap dryer/delacquering kiln/decoating kiln is subject
to the alternative emission limits in Sec. 63.1505(e), the average
afterburner operating temperature in each 3-hour block period must be
maintained at or above 760 [deg]C (1400 [deg]F) for the test.
(2) The owner or operator of a scrap dryer/delacquering kiln/
decoating kiln subject to the alternative limits in Sec. 63.1505(e)
must submit a written certification in the notification of compliance
status report containing the information required by Sec.
63.1515(b)(7).
(d) Group 1 furnace with add-on air pollution control devices. (1)
The owner or operator of a group 1 furnace that processes scrap other
than clean charge materials with emissions controlled by a lime-injected
fabric filter must conduct performance tests to measure emissions of PM
and D/F at the outlet of the control device and emissions of
[[Page 76]]
HCl at the outlet (for the emission limit) or the inlet and the outlet
(for the percent reduction standard).
(2) The owner or operator of a group 1 furnace that processes only
clean charge materials with emissions controlled by a lime-injected
fabric filter must conduct performance tests to measure emissions of PM
at the outlet of the control device and emissions of HCl at the outlet
(for the emission limit) or the inlet and the outlet (for the percent
reduction standard).
(3) The owner or operator may choose to determine the rate of
reactive flux addition to the group 1 furnace and assume, for the
purposes of demonstrating compliance with the SAPU emission limit, that
all reactive flux added to the group 1 furnace is emitted. Under these
circumstances, the owner or operator is not required to conduct an
emission test for HCl.
(4) The owner or operator of a sidewell group 1 furnace that
conducts reactive fluxing (except for cover flux) in the hearth, or that
conducts reactive fluxing in the sidewell at times when the level of
molten metal falls below the top of the passage between the sidewell and
the hearth, must conduct the performance tests required by paragraph
(d)(1) or (d)(2) of this section, to measure emissions from both the
sidewell and the hearth.
(e) Group 1 furnace (including melting holding furnaces) without
add-on air pollution control devices. In the site-specific monitoring
plan required by Sec. 63.1510(o), the owner or operator of a group 1
furnace (including a melting/holding furnaces) without add-on air
pollution control devices must include data and information
demonstrating compliance with the applicable emission limits.
(1) If the group 1 furnace processes other than clean charge
material, the owner or operator must conduct emission tests to measure
emissions of PM, HCl, and D/F at the furnace exhaust outlet.
(2) If the group 1 furnace processes only clean charge, the owner or
operator must conduct emission tests to simultaneously measure emissions
of PM and HCl at the furnace exhaust outlet. A D/F test is not required.
Each test must be conducted while the group 1 furnace (including a
melting/holding furnace) processes only clean charge.
(3) The owner or operator may choose to determine the rate of
reactive flux addition to the group 1 furnace and assume, for the
purposes of demonstrating compliance with the SAPU emission limit, that
all reactive flux added to the group 1 furnace is emitted. Under these
circumstances, the owner or operator is not required to conduct an
emission test for HCl.
(f) Sweat furnace. Except as provided in Sec. 63.1505(f)(1), the
owner or operator must measure emissions of D/F from each sweat furnace
at the outlet of the control device.
(g) Dross-only furnace. The owner or operator must conduct a
performance test to measure emissions of PM from each dross-only furnace
at the outlet of each control device while the unit processes only dross
and salt flux as the sole feedstock.
(h) In-line fluxer. (1) The owner or operator of an in-line fluxer
that uses reactive flux materials must conduct a performance test to
measure emissions of HCl and PM or otherwise demonstrate compliance in
accordance with paragraph (h)(2) of this section. If the in-line fluxer
is equipped with an add-on control device, the emissions must be
measured at the outlet of the control device.
(2) The owner or operator may choose to limit the rate at which
reactive chlorine flux is added to an in-line fluxer and assume, for the
purposes of demonstrating compliance with the SAPU emission limit, that
all chlorine in the reactive flux added to the in-line fluxer is emitted
as HCl. Under these circumstances, the owner or operator is not required
to conduct an emission test for HCl. If the owner or operator of any in-
line flux box which has no ventilation ductwork manifolded to any outlet
or emission control device chooses to demonstrate compliance with the
emission limit for HCl by limiting use of reactive chlorine flux and
assuming that all chlorine in the flux is emitted as HCl, compliance
with the HCl limit shall also constitute compliance with the emission
limit for PM, and no separate emission test for PM is required. In this
case, the owner or operator of the unvented in-line flux box
[[Page 77]]
must utilize the maximum permissible PM emission rate for the in-line
flux boxes when determining the total emissions for any SAPU which
includes the flux box.
(i) Rotary dross cooler. The owner or operator must conduct a
performance test to measure PM emissions at the outlet of the control
device.
(j) Secondary aluminum processing unit. The owner or operator must
conduct performance tests as described in paragraphs (j)(1) through (3)
of this section. The results of the performance tests are used to
establish emission rates in lb/ton of feed/charge for PM and HCl and
[micro]g TEQ/Mg of feed/charge for D/F emissions from each emission
unit. These emission rates are used for compliance monitoring in the
calculation of the 3-day, 24-hour rolling average emission rates using
the equation in Sec. 63.1510(t). A performance test is required for:
(1) Each group 1 furnace processing only clean charge to measure
emissions of PM and either:
(i) Emissions of HCl (for the emission limit); or
(ii) The mass flow rate of HCl at the inlet to and outlet from the
control device (for the percent reduction standard).
(2) Each group 1 furnace that processes scrap other than clean
charge to measure emissions of PM and D/F and either:
(i) Emissions of HCl (for the emission limit); or
(ii) The mass flow rate of HCl at the inlet to and outlet from the
control device (for the percent reduction standard).
(3) Each in-line fluxer to measure emissions of PM and HCl.
(k) Feed/charge weight measurement. During the emission test(s)
conducted to determine compliance with emission limits in a kg/Mg (lb/
ton) format, the owner or operator of an affected source or emission
unit, subject to an emission limit in a kg/Mg (lb/ton) of feed/charge
format, must measure (or otherwise determine) and record the total
weight of feed/charge to the affected source or emission unit for each
of the three test runs and calculate and record the total weight. An
owner or operator that chooses to demonstrate compliance on the basis of
the aluminum production weight must measure the weight of aluminum
produced by the emission unit or affected source instead of the feed/
charge weight.
(l) Continuous opacity monitoring system. The owner or operator of
an affected source or emission unit using a continuous opacity
monitoring system must conduct a performance evaluation to demonstrate
compliance with Performance Specification 1 in appendix B to 40 CFR part
60. Following the performance evaluation, the owner or operator must
measure and record the opacity of emissions from each exhaust stack for
all consecutive 6-minute periods during the PM emission test.
(m) Afterburner. These requirements apply to the owner or operator
of an affected source using an afterburner to comply with the
requirements of this subpart.
(1) Prior to the initial performance test, the owner or operator
must conduct a performance evaluation for the temperature monitoring
device according to the requirements of Sec. 63.8.
(2) The owner or operator must use these procedures to establish an
operating parameter value or range for the afterburner operating
temperature.
(i) Continuously measure and record the operating temperature of
each afterburner every 15 minutes during the THC and D/F performance
tests;
(ii) Determine and record the 15-minute block average temperatures
for the three test runs; and
(iii) Determine and record the 3-hour block average temperature
measurements for the 3 test runs.
(n) Inlet gas temperature. The owner or operator of a scrap dryer/
delacquering kiln/decoating kiln or a group 1 furnace using a lime-
injected fabric filter must use these procedures to establish an
operating parameter value or range for the inlet gas temperature.
(1) Continuously measure and record the temperature at the inlet to
the lime-injected fabric filter every 15 minutes during the HCl and D/F
performance tests;
(2) Determine and record the 15-minute block average temperatures
for the 3 test runs; and
[[Page 78]]
(3) Determine and record the 3-hour block average of the recorded
temperature measurements for the 3 test runs.
(o) Flux injection rate. The owner or operator must use these
procedures to establish an operating parameter value or range for the
total reactive chlorine flux injection rate.
(1) Continuously measure and record the weight of gaseous or liquid
reactive flux injected for each 15 minute period during the HCl and D/F
tests, determine and record the 15-minute block average weights, and
calculate and record the total weight of the gaseous or liquid reactive
flux for the 3 test runs;
(2) Record the identity, composition, and total weight of each
addition of solid reactive flux for the 3 test runs;
(3) Determine the total reactive chlorine flux injection rate by
adding the recorded measurement of the total weight of chlorine in the
gaseous or liquid reactive flux injected and the total weight of
chlorine in the solid reactive flux using Equation 5:
[GRAPHIC] [TIFF OMITTED] TR23MR00.013
Where,
Wt = Total chlorine usage, by weight;
F1 = Fraction of gaseous or liquid flux that is chlorine;
W1 = Weight of reactive flux gas injected;
F2 = Fraction of solid reactive chloride flux that is
chlorine (e.g., F = 0.75 for magnesium chloride; and
W2 = Weight of solid reactive flux;
(4) Divide the weight of total chlorine usage (Wt) for
the 3 test runs by the recorded measurement of the total weight of feed
for the 3 test runs; and
(5) If a solid reactive flux other than magnesium chloride is used,
the owner or operator must derive the appropriate proportion factor
subject to approval by the applicable permitting authority.
(p) Lime injection. The owner or operator of an affected source or
emission unit using a lime-injected fabric filter system must use these
procedures during the HCl and D/F tests to establish an operating
parameter value for the feeder setting for each operating cycle or time
period used in the performance test.
(1) For continuous lime injection systems, ensure that lime in the
feed hopper or silo is free-flowing at all times; and
(2) Record the feeder setting for the 3 test runs. If the feed rate
setting varies during the runs, determine and record the average feed
rate from the 3 runs.
(q) Bag leak detection system. The owner or operator of an affected
source or emission unit using a bag leak detection system must submit
the information described in Sec. 63.1515(b)(6) as part of the
notification of compliance status report to document conformance with
the specifications and requirements in Sec. 63.1510(f).
(r) Labeling. The owner or operator of each scrap dryer/delacquering
kiln/decoating kiln, group 1 furnace, group 2 furnace and in-line fluxer
must submit the information described in Sec. 63.1515(b)(3) as part of
the notification of compliance status report to document conformance
with the operational standard in Sec. 63.1506(b).
(s) Capture/collection system. The owner or operator of a new or
existing affected source or emission unit with an add-on control device
must submit the information described in Sec. 63.1515(b)(2) as part of
the notification of compliance status report to document conformance
with the operational standard in Sec. 63.1506(c).
[65 FR 15710, Mar. 23, 2000, as amended at 67 FR 79817, Dec. 30, 2002;
69 FR 53984, Sept. 3, 2004]
Sec. 63.1513 Equations for determining compliance.
(a) THC emission limit. Use Equation 6 to determine compliance with
an emission limit for THC:
[GRAPHIC] [TIFF OMITTED] TR23MR00.004
Where,
E = Emission rate of measured pollutant, kg/Mg (lb/ton) of feed;
C = Measured volume fraction of pollutant, ppmv;
MW = Molecular weight of measured pollutant, g/g-mole (lb/lb-mole): THC
(as propane) = 44.11;
Q = Volumetric flow rate of exhaust gases, dscm/hr (dscf/hr);
K1 = Conversion factor, 1 kg/1,000 g (1 lb/lb);
K2 = Conversion factor, 1,000 L/m\3\ (1 ft\3\/ft\3\);
Mv = Molar volume, 24.45 L/g-mole (385.3 ft\3\/lb-mole); and
P = Production rate, Mg/hr (ton/hr).
[[Page 79]]
(b) PM, HCl and D/F emission limits. (1) Use Equation 7 of this
section to determine compliance with an emission limit for PM or HCl:
[GRAPHIC] [TIFF OMITTED] TR03SE04.018
Where:
E = Emission rate of PM or HCl, kg/Mg (lb/ton) of feed;
C = Concentration of PM or HCl, g/dscm (gr/dscf);
Q = Volumetric flow rate of exhaust gases, dscm/hr (dscf/hr);
K1 = Conversion factor, 1 kg/1,000 g (1 lb/7,000 gr); and
P = Production rate, Mg/hr (ton/hr).
(2) Use Equation 7A of this section to determine compliance with an
emission limit for D/F:
[GRAPHIC] [TIFF OMITTED] TR03SE04.019
Where:
E = Emission rate of D/F, [micro]g/Mg (gr/ton) of feed;
C = Concentration of D/F, [micro]g/dscm (gr/dscf);
Q = Volumetric flow rate of exhaust gases, dscm/hr (dscf/hr); and
P = Production rate, Mg/hr (ton/hr).
(c) HCl percent reduction standard. Use Equation 8 to determine
compliance with an HCl percent reduction standard:
[GRAPHIC] [TIFF OMITTED] TR23MR00.006
Where,
%R = Percent reduction of the control device;
Li = Inlet loading of pollutant, kg/Mg (lb/ton); and
Lo = Outlet loading of pollutant, kg/Mg (lb/ton).
(d) Conversion of D/F measurements to TEQ units. To convert D/F
measurements to TEQ units, the owner or operator must use the procedures
and equations in ``Interim Procedures for Estimating Risks Associated
with Exposures to Mixtures of Chlorinated Dibenzo-p-Dioxins and -
Dibenzofurans (CDDs and CDFs) and 1989 Update'' (EPA-625/3-89-016),
incorporated by reference in Sec. 63.1502 of this subpart, available
from the National Technical Information Service (NTIS), 5285 Port Royal
Road, Springfield, Virginia, NTIS no. PB 90-145756.
(e) Secondary aluminum processing unit. Use the procedures in
paragraphs (e)(1), (2), and (3) or the procedure in paragraph (e)(4) of
this section to determine compliance with emission limits for a
secondary aluminum processing unit.
(1) Use Equation 9 to compute the mass-weighted PM emissions for a
secondary aluminum processing unit. Compliance is achieved if the mass-
weighted emissions for the secondary aluminum processing unit
(EcPM) is less than or equal to the emission limit for the
secondary aluminum processing unit (LcPM) calculated using
Equation 1 in Sec. 63.1505(k).
[GRAPHIC] [TIFF OMITTED] TR23MR00.007
Where,
EcPM = The mass-weighted PM emissions for the secondary
aluminum processing unit;
EtiPM = Measured PM emissions for individual emission unit i;
Tti = The average feed rate for individual emission unit i
during the operating cycle or performance test period; and
n=The number of emission units in the secondary aluminum processing
unit.
(2) Use Equation 10 to compute the aluminum mass-weighted HCl
emissions for the secondary aluminum processing unit. Compliance is
achieved if the mass-weighted emissions for the secondary aluminum
processing unit (EcHCl) is less than or equal to the emission
limit for the secondary aluminum processing unit (LcHCl)
calculated using Equation 2 in Sec. 63.1505(k).
[GRAPHIC] [TIFF OMITTED] TR23MR00.008
Where,
EcHCl = The mass-weighted HCl emissions for the secondary
aluminum processing unit; and
EtiHCl = Measured HCl emissions for individual emission unit
i.
[[Page 80]]
(3) Use Equation 11 to compute the aluminum mass-weighted D/F
emissions for the secondary aluminum processing unit. Compliance is
achieved if the mass-weighted emissions for the secondary aluminum
processing unit is less than or equal to the emission limit for the
secondary aluminum processing unit (LcD/F) calculated using
Equation 3 in Sec. 63.1505(k).
[GRAPHIC] [TIFF OMITTED] TR23MR00.009
Where,
EcD/F = The mass-weighted D/F emissions for the secondary
aluminum processing unit; and
EtiD/F = Measured D/F emissions for individual emission unit
i.
(4) As an alternative to using the equations in paragraphs (e)(1),
(2), and (3) of this section, the owner or operator may demonstrate
compliance for a secondary aluminum processing unit by demonstrating
that each existing group 1 furnace is in compliance with the emission
limits for a new group 1 furnace in Sec. 63.1505(i) and that each
existing in-line fluxer is in compliance with the emission limits for a
new in-line fluxer in Sec. 63.1505(j).
[65 FR 15710, Mar. 23, 2000, as amended at 69 FR 53984, Sept. 3, 2004]
Sec. 63.1514 [Reserved]
Notifications, Reports, And Records
Sec. 63.1515 Notifications.
(a) Initial notifications. The owner or operator must submit initial
notifications to the applicable permitting authority as described in
paragraphs (a)(1) through (7) of this section.
(1) As required by Sec. 63.9(b)(1), the owner or operator must
provide notification for an area source that subsequently increases its
emissions such that the source is a major source subject to the
standard.
(2) As required by Sec. 63.9(b)(3), the owner or operator of a new
or reconstructed affected source, or a source that has been
reconstructed such that it is an affected source, that has an initial
startup after the effective date of this subpart and for which an
application for approval of construction or reconstruction is not
required under Sec. 63.5(d), must provide notification that the source
is subject to the standard.
(3) As required by Sec. 63.9(b)(4), the owner or operator of a new
or reconstructed major affected source that has an initial startup after
the effective date of this subpart and for which an application for
approval of construction or reconstruction is required by Sec. 63.5(d)
must provide the following notifications:
(i) Intention to construct a new major affected source, reconstruct
a major source, or reconstruct a major source such that the source
becomes a major affected source;
(ii) Date when construction or reconstruction was commenced
(submitted simultaneously with the application for approval of
construction or reconstruction if construction or reconstruction was
commenced before the effective date of this subpart, or no later than 30
days after the date construction or reconstruction commenced if
construction or reconstruction commenced after the effective date of
this subpart);
(iii) Anticipated date of startup; and
(iv) Actual date of startup.
(4) As required by Sec. 63.9(b)(5), after the effective date of
this subpart, an owner or operator who intends to construct a new
affected source or reconstruct an affected source subject to this
subpart, or reconstruct a source such that it becomes an affected source
subject to this subpart, must provide notification of the intended
construction or reconstruction. The notification must include all the
information required for an application for approval of construction or
reconstruction as required by Sec. 63.5(d). For major sources, the
application for approval of construction or reconstruction may be used
to fulfill these requirements.
(i) The application must be submitted as soon as practicable before
the construction or reconstruction is planned to commence (but no sooner
than the effective date) if the construction or reconstruction commences
after the effective date of this subpart; or
[[Page 81]]
(ii) The application must be submitted as soon as practicable before
startup but no later than 90 days after the effective date of this
subpart if the construction or reconstruction had commenced and initial
startup had not occurred before the effective date.
(5) As required by Sec. 63.9(d), the owner or operator must provide
notification of any special compliance obligations for a new source.
(6) As required by Sec. 63.9(e) and (f), the owner or operator must
provide notification of the anticipated date for conducting performance
tests and visible emission observations. The owner or operator must
notify the Administrator of the intent to conduct a performance test at
least 60 days before the performance test is scheduled; notification of
opacity or visible emission observations for a performance test must be
provided at least 30 days before the observations are scheduled to take
place.
(7) As required by Sec. 63.9(g), the owner or operator must provide
additional notifications for sources with continuous emission monitoring
systems or continuous opacity monitoring systems.
(b) Notification of compliance status report. Each owner or operator
of an existing affected source must submit a notification of compliance
status report within 60 days after the compliance date established by
Sec. 63.1501(a). Each owner or operator of a new affected source must
submit a notification of compliance status report within 90 days after
conducting the initial performance test required by Sec. 63.1511(b), or
within 90 days after the compliance date established by Sec. 63.1501(b)
if no initial performance test is required. The notification must be
signed by the responsible official who must certify its accuracy. A
complete notification of compliance status report must include the
information specified in paragraphs (a)(1) through (10) of this section.
The required information may be submitted in an operating permit
application, in an amendment to an operating permit application, in a
separate submittal, or in any combination. In a State with an approved
operating permit program where delegation of authority under section
112(l) of the CAA has not been requested or approved, the owner or
operator must provide duplicate notification to the applicable Regional
Administrator. If an owner or operator submits the information specified
in this section at different times or in different submittals, later
submittals may refer to earlier submittals instead of duplicating and
resubmitting the information previously submitted. A complete
notification of compliance status report must include:
(1) All information required in Sec. 63.9(h). The owner or operator
must provide a complete performance test report for each affected source
and emission unit for which a performance test is required. A complete
performance test report includes all data, associated measurements, and
calculations (including visible emission and opacity tests).
(2) The approved site-specific test plan and performance evaluation
test results for each continuous monitoring system (including a
continuous emission or opacity monitoring system).
(3) Unit labeling as described in Sec. 63.1506(b), including
process type or furnace classification and operating requirements.
(4) The compliant operating parameter value or range established for
each affected source or emission unit with supporting documentation and
a description of the procedure used to establish the value (e.g., lime
injection rate, total reactive chlorine flux injection rate, afterburner
operating temperature, fabric filter inlet temperature), including the
operating cycle or time period used in the performance test.
(5) Design information and analysis, with supporting documentation,
demonstrating conformance with the requirements for capture/collection
systems in Sec. 63.1506(c).
(6) If applicable, analysis and supporting documentation
demonstrating conformance with EPA guidance and specifications for bag
leak detection systems in Sec. 63.1510(f).
(7) Manufacturer's specification or analysis documenting the design
residence time of no less than 1 second for each afterburner used to
control emissions from a scrap dryer/delacquering
[[Page 82]]
kiln/decoating kiln subject to alternative emission standards in Sec.
63.1505(e).
(8) Manufacturer's specification or analysis documenting the design
residence time of no less than 0.8 seconds and design operating
temperature of no less than 1,600 [deg]F for each afterburner used to
control emissions from a sweat furnace that is not subject to a
performance test.
(9) The OM&M plan (including site-specific monitoring plan for each
group 1 furnace with no add-on air pollution control device).
(10) Startup, shutdown, and malfunction plan, with revisions.
[65 FR 15710, Mar. 23, 2000, as amended at 67 FR 59793, Sept. 24, 2002;
67 FR 79818, Dec. 30, 2002]
Sec. 63.1516 Reports.
(a) Startup, shutdown, and malfunction plan/reports. The owner or
operator must develop a written plan as described in Sec. 63.6(e)(3)
that contains specific procedures to be followed for operating and
maintaining the source during periods of startup, shutdown, and
malfunction, and a program of corrective action for malfunctioning
process and air pollution control equipment used to comply with the
standard. The owner or operator shall also keep records of each event as
required by Sec. 63.10(b) and record and report if an action taken
during a startup, shutdown, or malfunction is not consistent with the
procedures in the plan as described in Sec. 63.6(e)(3). In addition to
the information required in Sec. 63.6(e)(3), the plan must include:
(1) Procedures to determine and record the cause of the malfunction
and the time the malfunction began and ended; and
(2) Corrective actions to be taken in the event of a malfunction of
a process or control device, including procedures for recording the
actions taken to correct the malfunction or minimize emissions.
(b) Excess emissions/summary report. The owner or operator must
submit semiannual reports according to the requirements in Sec.
63.10(e)(3). Except, the owner or operator must submit the semiannual
reports within 60 days after the end of each 6-month period instead of
within 30 days after the calendar half as specified in Sec.
63.10(e)(3)(v). When no deviations of parameters have occurred, the
owner or operator must submit a report stating that no excess emissions
occurred during the reporting period.
(1) A report must be submitted if any of these conditions occur
during a 6-month reporting period:
(i) The corrective action specified in the OM&M plan for a bag leak
detection system alarm was not initiated within 1 hour.
(ii) The corrective action specified in the OM&M plan for a
continuous opacity monitoring deviation was not initiated within 1 hour.
(iii) The corrective action specified in the OM&M plan for visible
emissions from an aluminum scrap shredder was not initiated within 1
hour.
(iv) An excursion of a compliant process or operating parameter
value or range (e.g., lime injection rate or screw feeder setting, total
reactive chlorine flux injection rate, afterburner operating
temperature, fabric filter inlet temperature, definition of acceptable
scrap, or other approved operating parameter).
(v) An action taken during a startup, shutdown, or malfunction was
not consistent with the procedures in the plan as described in Sec.
63.6(e)(3).
(vi) An affected source (including an emission unit in a secondary
aluminum processing unit) was not operated according to the requirements
of this subpart.
(vii) A deviation from the 3-day, 24-hour rolling average emission
limit for a secondary aluminum processing unit.
(2) Each report must include each of these certifications, as
applicable:
(i) For each thermal chip dryer: ``Only unpainted aluminum chips
were used as feedstock in any thermal chip dryer during this reporting
period.''
(ii) For each dross-only furnace: ``Only dross and salt flux were
used as the charge materials in any dross-only furnace during this
reporting period.''
(iii) For each sidewell group 1 furnace with add-on air pollution
control devices: ``Each furnace was operated such that the level of
molten metal remained above the top of the passage between the sidewell
and hearth during
[[Page 83]]
reactive fluxing, and reactive flux, except for cover flux, was added
only to the sidewell or to a furnace hearth equipped with an add-on air
pollution control device for PM, HCl, and D/F emissions during this
reporting period.''
(iv) For each group 1 melting/holding furnace without add-on air
pollution control devices and using pollution prevention measures that
processes only clean charge material: ``Each group 1 furnace without
add-on air pollution control devices subject to emission limits in Sec.
63.1505(i)(2) processed only clean charge during this reporting
period.''
(v) For each group 2 furnace: ``Only clean charge materials were
processed in any group 2 furnace during this reporting period, and no
fluxing was performed or all fluxing performed was conducted using only
nonreactive, non-HAP-containing/non-HAP-generating fluxing gases or
agents, except for cover fluxes, during this reporting period.''
(vi) For each in-line fluxer using no reactive flux: ``Only
nonreactive, non-HAP-containing, non-HAP-generating flux gases, agents,
or materials were used at any time during this reporting period.''
(3) The owner or operator must submit the results of any performance
test conducted during the reporting period, including one complete
report documenting test methods and procedures, process operation, and
monitoring parameter ranges or values for each test method used for a
particular type of emission point tested.
(c) Annual compliance certifications. For the purpose of annual
certifications of compliance required by 40 CFR part 70 or 71, the owner
or operator must certify continuing compliance based upon, but not
limited to, the following conditions:
(1) Any period of excess emissions, as defined in paragraph (b)(1)
of this section, that occurred during the year were reported as required
by this subpart; and
(2) All monitoring, recordkeeping, and reporting requirements were
met during the year.
[65 FR 15710, Mar. 23, 2000, as amended at 69 FR 53984, Sept. 3, 2004;
71 FR 20461, Apr. 20, 2006]
Sec. 63.1517 Records
(a) As required by Sec. 63.10(b), the owner or operator shall
maintain files of all information (including all reports and
notifications) required by the general provisions and this subpart.
(1) The owner or operator must retain each record for at least 5
years following the date of each occurrence, measurement, maintenance,
corrective action, report, or record. The most recent 2 years of records
must be retained at the facility. The remaining 3 years of records may
be retained off site.
(2) The owner or operator may retain records on microfilm, computer
disks, magnetic tape, or microfiche; and
(3) The owner or operator may report required information on paper
or on a labeled computer disk using commonly available and EPA-
compatible computer software.
(b) In addition to the general records required by Sec. 63.10(b),
the owner or operator of a new or existing affected source (including an
emission unit in a secondary aluminum processing unit) must maintain
records of:
(1) For each affected source and emission unit with emissions
controlled by a fabric filter or a lime-injected fabric filter:
(i) If a bag leak detection system is used, the number of total
operating hours for the affected source or emission unit during each 6-
month reporting period, records of each alarm, the time of the alarm,
the time corrective action was initiated and completed, and a brief
description of the cause of the alarm and the corrective action(s)
taken.
(ii) If a continuous opacity monitoring system is used, records of
opacity measurement data, including records where the average opacity of
any 6-minute period exceeds 5 percent, with a brief explanation of the
cause of the emissions, the time the emissions occurred, the time
corrective action
[[Page 84]]
was initiated and completed, and the corrective action taken.
(iii) If an aluminum scrap shredder is subject to visible emission
observation requirements, records of all Method 9 observations,
including records of any visible emissions during a 30-minute daily
test, with a brief explanation of the cause of the emissions, the time
the emissions occurred, the time corrective action was initiated and
completed, and the corrective action taken.
(2) For each affected source with emissions controlled by an
afterburner:
(i) Records of 15-minute block average afterburner operating
temperature, including any period when the average temperature in any 3-
hour block period falls below the compliant operating parameter value
with a brief explanation of the cause of the excursion and the
corrective action taken; and
(ii) Records of annual afterburner inspections.
(3) For each scrap dryer/delacquering kiln/decoating kiln and group
1 furnace, subject to D/F and HCl emission standards with emissions
controlled by a lime-injected fabric filter, records of 15-minute block
average inlet temperatures for each lime-injected fabric filter,
including any period when the 3-hour block average temperature exceeds
the compliant operating parameter value +14 [deg]C (+25 [deg]F), with a
brief explanation of the cause of the excursion and the corrective
action taken.
(4) For each affected source and emission unit with emissions
controlled by a lime-injected fabric filter:
(i) Records of inspections at least once every 8-hour period
verifying that lime is present in the feeder hopper or silo and flowing,
including any inspection where blockage is found, with a brief
explanation of the cause of the blockage and the corrective action
taken, and records of inspections at least once every 4-hour period for
the subsequent 3 days. If flow monitors, pressure drop sensors or load
cells are used to verify that lime is present in the hopper and flowing,
records of all monitor or sensor output including any event where
blockage was found, with a brief explanation of the cause of the
blockage and the corrective action taken;
(ii) If lime feeder setting is monitored, records of daily
inspections of feeder setting, including records of any deviation of the
feeder setting from the setting used in the performance test, with a
brief explanation of the cause of the deviation and the corrective
action taken.
(iii) If lime addition rate for a noncontinuous lime injection
system is monitored pursuant to the approved alternative monitoring
requirements in Sec. 63.1510(v), records of the time and mass of each
lime addition during each operating cycle or time period used in the
performance test and calculations of the average lime addition rate (lb/
ton of feed/charge).
(5) For each group 1 furnace (with or without add-on air pollution
control devices) or in-line fluxer, records of 15-minute block average
weights of gaseous or liquid reactive flux injection, total reactive
flux injection rate and calculations (including records of the identity,
composition, and weight of each addition of gaseous, liquid or solid
reactive flux), including records of any period the rate exceeds the
compliant operating parameter value and corrective action taken.
(6) For each continuous monitoring system, records required by Sec.
63.10(c).
(7) For each affected source and emission unit subject to an
emission standard in kg/Mg (lb/ton) of feed/charge, records of feed/
charge (or throughput) weights for each operating cycle or time period
used in the performance test.
(8) Approved site-specific monitoring plan for a group 1 furnace
without add-on air pollution control devices with records documenting
conformance with the plan.
(9) Records of all charge materials for each thermal chip dryer,
dross-only furnace, and group 1 melting/holding furnaces without air
pollution control devices processing only clean charge.
(10) Operating logs for each group 1 sidewell furnace with add-on
air pollution control devices documenting conformance with operating
standards for maintaining the level of molten metal above the top of the
passage between the sidewell and hearth during reactive flux injection
and for adding reactive flux only to the sidewell or a furnace
[[Page 85]]
hearth equipped with a control device for PM, HCl, and D/F emissions.
(11) For each in-line fluxer for which the owner or operator has
certified that no reactive flux was used:
(i) Operating logs which establish that no source of reactive flux
was present at the in-line fluxer;
(ii) Labels required pursuant to Sec. 63.1506(b) which establish
that no reactive flux may be used at the in-line fluxer; or
(iii) Operating logs which document each flux gas, agent, or
material used during each operating cycle.
(12) Records of all charge materials and fluxing materials or agents
for a group 2 furnace.
(13) Records of monthly inspections for proper unit labeling for
each affected source and emission unit subject to labeling requirements.
(14) Records of annual inspections of emission capture/collection
and closed vent systems.
(15) Records for any approved alternative monitoring or test
procedure.
(16) Current copy of all required plans, including any revisions,
with records documenting conformance with the applicable plan,
including:
(i) Startup, shutdown, and malfunction plan;
(ii) OM&M plan; and
(iii) Site-specific secondary aluminum processing unit emission plan
(if applicable).
(17) For each secondary aluminum processing unit, records of total
charge weight, or if the owner or operator chooses to comply on the
basis of aluminum production, total aluminum produced for each 24-hour
period and calculations of 3-day, 24-hour rolling average emissions.
[65 FR 15710, Mar. 23, 2000, as amended at 67 FR 79818, Dec. 30, 2002]
Other
Sec. 63.1518 Applicability of general provisions.
The requirements of the general provisions in subpart A of this part
that are applicable to the owner or operator subject to the requirements
of this subpart are shown in appendix A to this subpart.
Sec. 63.1519 Implementation and enforcement.
(a) This subpart can be implemented and enforced by the U.S. EPA, or
a delegated authority such as the applicable State, local, or Tribal
agency. If the U.S. EPA Administrator has delegated authority to a
State, local, or Tribal agency, then that agency, in addition to the
U.S. EPA, has the authority to implement and enforce this regulation.
Contact the applicable U.S. EPA Regional Office to find out if this
subpart is delegated to a State, local, or Tribal agency.
(b) In delegating implementation and enforcement authority of this
regulation to a State, local, or Tribal agency under subpart E of this
part, the authorities contained in paragraph (c) of this section are
retained by the Administrator of U.S. EPA and cannot be transferred to
the State, local, or Tribal agency.
(c) The authorities that cannot be delegated to State, local, or
Tribal agencies are as specified in paragraphs (c)(1) through (4) of
this section.
(1) Approval of alternatives to the requirements in Sec. Sec.
63.1500 through 63.1501 and 63.1505 through 63.1506.
(2) Approval of major alternatives to test methods for under Sec.
63.7(e)(2)(ii) and (f), as defined in Sec. 63.90, and as required in
this subpart.
(3) Approval of major alternatives to monitoring under Sec.
63.8(f), as defined in Sec. 63.90, and as required in this subpart.
(4) Approval of major alternatives to recordkeeping and reporting
under Sec. 63.10(f), as defined in Sec. 63.90, and as required in this
subpart.
[68 FR 37359, June 23, 2003]
Sec. 63.1520 [Reserved]
[[Page 86]]
Table 1 to Subpart RRR of Part 63--Emission Standards for New and
Existing Affected Sources
[GRAPHIC] [TIFF OMITTED] TR23MR00.010
[[Page 87]]
[GRAPHIC] [TIFF OMITTED] TR23MR00.011
[[Page 88]]
[GRAPHIC] [TIFF OMITTED] TR23MR00.012
[[Page 89]]
Table 2 to Subpart RRR of Part 63--Summary of Operating Requirements for
New and Existing Affected Sources and Emission Units
----------------------------------------------------------------------------------------------------------------
Monitor type/operation/
Affected source/emission unit process Operating requirements
----------------------------------------------------------------------------------------------------------------
All affected sources and emission units Emission capture and Design and install in accordance with
with an add-on air pollution control collection system. Industrial Ventilation: A Handbook of
device. Recommended Practice; operate in
accordance with OM&M plan. \b\
All affected sources and emission units Charge/feed weight or Operate a device that records the weight
subject to production-based (lb/ton of Production weight. of each charge; Operate in accordance
feed) emission limits \a\. with OM&M plan. \b\
Group 1 furnace, group 2 furnace, in-line Labeling................... Identification, operating parameter
fluxer and scrap dryer/delacquering kiln/ ranges and operating requirements
decoating kiln. posted at affected sources and emission
units; control device temperature and
residence time requirements posted at
scrap dryer/delacquering kiln/decoating
kiln.
Aluminum scrap shredder with fabric Bag leak detector or....... Initiate corrective action within 1-hr
filter. of alarm and complete in accordance
with OM&M plan \b\; operate such that
alarm does not sound more than 5% of
operating time in 6-month period.
COM or..................... Initiate corrective action within 1-hr
of a 6-minute average opacity reading
of 5% or more and complete in
accordance with OM&M plan. \b\
VE......................... Initiate corrective action within 1-hr
of any observed VE and complete in
accordance with the OM&M plan. \b\
Thermal chip dryer with afterburner...... Afterburner operating Maintain average temperature for each 3-
temperature. hr period at or above average operating
temperature during the performance
test.
Afterburner operation...... Operate in accordance with OM&M plan.
\b\
Feed material.............. Operate using only unpainted aluminum
chips.
Scrap dryer/delacquering kiln/decoating Afterburner operating Maintain average temperature for each 3-
kiln with afterburner and lime-injected temperature. hr period at or above average operating
fabric filter. temperature during the performance
test.
Afterburner operation...... Operate in accordance with OM&M plan.
\b\
Bag leak detector or....... Initiate corrective action within 1-hr
of alarm and complete in accordance
with the OM&M plan; \b\ operate such
that alarm does not sound more than 5%
of operating time in 6-month period.
COM........................ Initiate corrective action within 1-hr
of a 6-minute average opacity reading
of 5% or more and complete in
accordance with the OM&M plan. \b\
Fabric filter inlet Maintain average fabric filter inlet
temperature. temperature for each 3-hr period at or
below average temperature during the
performance test +14 [deg]C (+25
[deg]F).
Lime injection rate........ Maintain free-flowing lime in the feed
hopper or silo at all times for
continuous injection systems; maintain
feeder setting at level established
during the performance test for
continuous injection systems.
Sweat furnace with afterburner........... Afterburner operating If a performance test was conducted,
temperature. maintain average temperature for each 3-
hr period at or above average operating
temperature during the performance
test; if a performance test was not
conducted, and afterburner meets
specifications of Sec. 63.1505(f)(1),
maintain average temperature for each 3-
hr period at or above 1600 [deg]F.
Afterburner operation...... Operate in accordance with OM&M plan.
\b\
Dross-only furnace with fabric filter.... Bag leak detector or....... Initiate corrective action within 1-hr
of alarm and complete in accordance
with the OM&M plan; \b\ operate such
that alarm does not sound more than 5%
of operating time in 6-month period.
COM........................ Initiate corrective action within 1-hr
of a 6-minute average opacity reading
of 5% or more and complete in
accordance with the OM&M plan. \b\
Feed/charge material....... Operate using only dross as the feed
material.
Rotary dross cooler with fabric filter... Bag leak detector or....... Initiate corrective action within 1-hr
of alarm and complete in accordance
with the OM&M plan; \b\ operate such
that alarm does not sound more than 5%
of operating time in 6-month period.
COM........................ Initiate corrective action within 1-hr
of a 6-minute average opacity reading
of 5% or more and complete in
accordance with the OM&M plan. \b\
In-line fluxer with lime-injected fabric Bag leak detector or....... Initiate corrective action within 1-hr
filter (including those that are part of of alarm and complete in accordance
a secondary aluminum processing unit). with the OM&M plan; \b\ operate such
that alarm does not sound more than 5%
of operating time in 6-month period.
[[Page 90]]
COM........................ Initiate corrective action within 1-hr
of a 6-minute average opacity reading
of 5% or more and complete in
accordance with the OM&M plan. \b\
Lime injection rate........ Maintain free-flowing lime in the feed
hopper or silo at all times for
continuous injection systems; maintain
feeder setting at level established
during performance test for continuous
injection systems.
Reactive flux injection Maintain reactive flux injection rate at
rate. or below rate used during the
performance test for each operating
cycle or time period used in the
performance test.
In-line fluxer (using no reactive flux Flux materials............. Use no reactive flux.
material).
Group 1 furnace with lime-injected fabric Bag leak detector or Initiate corrective action within 1-hr
filter (including those that are part of of alarm; operate such that alarm does
a secondary of aluminum processing not sound more than 5% of operating
unit).. time in 6-month period; complete
corrective action in accordance with
the OM&M plan. \b\
COM........................ Initiate corrective action within 1-hr
of a 6-minute average opacity reading
of 5% or more; complete corrective
action in accordance with the OM&M
plan. \b\
Fabric filter inlet Maintain average fabric filter inlet
temperature. temperature for each 3-hour period at
or below average temperature during the
performance test +14 [deg]C (+25
[deg]F).
Reactive flux injection Maintain reactive flux injection rate
rate. (kg/Mg) (lb/ton) at or below rate used
during the performance test for each
furnace cycle.
Lime injection rate........ Maintain free-flowing lime in the feed
hopper or silo at all times for
continuous injection systems; maintain
feeder setting at level established at
performance test for continuous
injection systems.
Maintain molten aluminum Operate sidewell furnaces such that the
level. level of molten metal is above the top
of the passage between sidewell and
hearth during reactive flux injection,
unless the hearth is also controlled.
Fluxing in sidewell furnace Add reactive flux only to the sidewell
hearth. of the furnace unless the hearth is
also controlled.
Group 1 furnace without add-on controls Reactive flux injection Maintain reactive flux injection rate
(including those that are part of a rate. (kg/Mg) (lb/ton) at or below rate used
secondary aluminum processing unit). during the performance test for each
operating cycle or time period used in
the performance test.
Site-specific monitoring Operate furnace within the range of
plan \c\. charge materials, contaminant levels,
and parameter values established in the
site-specific monitoring plan.
Feed material (melting/ Use only clean charge.
holding furnace).
Clean (group 2) furnace.................. Charge and flux materials.. Use only clean charge. Use no reactive
flux.
----------------------------------------------------------------------------------------------------------------
\a\ Thermal chip dryers, scrap dryers/delacquering kilns/decoating kilns, dross-only furnaces, in-line fluxers
and group 1 furnaces including melting/holding furnaces.
\b\ OM&M plan--Operation, maintenance, and monitoring plan.
\c\ Site-specific monitoring plan. Owner/operators of group 1 furnaces without control devices must include a
section in their OM&M plan that documents work practice and pollution prevention measures, including
procedures for scrap inspection, by which compliance is achieved with emission limits and process or feed
parameter-based operating requirements. This plan and the testing to demonstrate adequacy of the monitoring
plan must be developed in coordination with and approved by the permitting authority.
[65 FR 15710, Mar. 23, 2000, as amended at 67 FR 79818, Dec. 30, 2002;
69 FR 53984, Sept. 3, 2004]
Table 3 to Subpart RRR of Part 63--Summary of Monitoring Requirements
for New and Existing Affected Sources and Emission Units
----------------------------------------------------------------------------------------------------------------
Monitor type/Operation/
Affected source/Emission unit Process Monitoring requirements
----------------------------------------------------------------------------------------------------------------
All affected sources and emission units Emission capture and Annual inspection of all emission
with an add-on air pollution control collection system. capture, collection, and transport
device. systems to ensure that systems continue
to operate in accordance with ACGIH
standards.
All affected sources and emission units Feed/charge weight......... Record weight of each feed/charge,
subject to production-based (lb/ton of weight measurement device or other
feed/charge) emission limits \a\. procedure accuracy of 1% \b\; calibrate according to
manufacturers specifications, or at
least once every 6 months.
Group 1 furnace, group 2 furnace, in-line Labeling................... Check monthly to confirm that labels are
fluxer, and scrap dryer/delacquering intact and legible.
kiln/decoating kiln.
[[Page 91]]
Aluminum scrap shredder with fabric Bag leak detector or....... Install and operate in accordance with
filter. ``Fabric Filter Bag Leak Detection
Guidance'' \c\; record voltage output
from bag leak detector.
COM or..................... Design and install in accordance with PS-
1; collect data in accordance with
subpart A of 40 CFR part 63; determine
and record 6-minute block averages.
VE......................... Conduct and record results of 30-minute
daily test in accordance with Method 9.
Thermal chip dryer with afterburner...... Afterburner operating Continuous measurement device to meet
temperature. specifications in Sec. 63.1510(g)(1);
record average temperature for each 15-
minute block; determine and record 3-hr
block averages.
Afterburner operation...... Annual inspection of afterburner
internal parts; complete repairs in
accordance with the OM&M plan.
Feed/charge material....... Record identity of each feed/charge;
certify feed/charge materials every 6
months.
Scrap dryer/delacquering kiln/decoating Afterburner operating Continuous measurement device to meet
kiln with afterburner and lime-injected temperature.. specifications in Sec. 63.1510(g)(1);
fabric filter. record temperature for each 15-minute
block; determine and record 3-hr block
averages.
Afterburner operation...... Annual inspection of afterburner
internal parts; complete repairs in
accordance with the OM&M plan.
Bag leak detector or....... Install and operate in accordance with
``Fabric Filter Bag Leak Detection
Guidance \c\; record voltage output
from bag leak detector.
COM........................ Design and Install in accordance with PS-
1; collect data in accordance with
subpart A of 40 CFR part 63; determine
and record 6-minute block averages.
Lime injection rate........ For continuous injection systems,
inspect each feed hooper or silo every
8 hours to verify that lime is free
flowing; record results of each
inspection. If blockage occurs, inspect
every 4 hours for 3 days; return to 8-
hour inspections if corrective action
results in no further blockage during 3-
day period, record feeder setting
daily.
Fabric filter inlet Continous measurement device to meet
temperature.. specifications in Sec. 63.1510(h)(2);
record temperatures in 15-minute block
averages; determine and record 3-hr
block averages.
Sweat furnace with afterburner........... Afterburner operating Continuous measurement device to meet
temperature. specifications in Sec. 63.1510(g)(1);
record temperatures in 15-minute block
averages; determine and record 3-hr
block averages.
Afterburner operation...... Annual inspection of afterburner
internal parts; complete repairs in
accordance with the OM&M plan.
Dross-only furnace with fabric filter.... Bag leak detector or....... Install and operate in accordance with
``Fabric Filter Bag Leak Detection
Guidance'' \c\; record output voltage
from bag leak detector.
COM........................ Design and install in accordance with PS-
1; collect data in accordance with
subpart A of 40 CFR part 63; determine
and record 6-minute block averages.
Feed/charge material....... Record identity of each feed/charge;
certify charge materials every 6
months.
Rotary dross cooler with fabric filter... Bag leak detector or....... Install and operate in accordance with
``Fabric Filter Bag Leak Detection
Guidance'' \c\; record output voltage
from bag leak detector.
COM........................ Design and install in accordance with PS-
1; collect data in accordance with
subpart A of 40 CFR part 63; determine
and record 6-minute block averages.
In-line fluxer with lime-injected fabric Bag leak detector or....... Install and operate in accordance with
filter. ``Fabric Filter Bag Leak Detection
Guidance'' \c\; record output voltage
from bag leak detector.
COM........................ Design and install in accordance with PS-
1; collect data in accordance with
subpart A of 40 CFR part 63; determine
and record 6-minute block averages
Reactive flux injection Weight measurement device accuracy of
rate. 1% \b\; calibrate
according to manufacturer's
specifications or at least once every 6
months; record time, weight and type of
reactive flux added or injected for
each 15-minute block period while
reactive fluxing occurs; calculate and
record total reactive flux injection
rate for each operating cycle or time
period used in performance test; or
Alternative flux injection rate
determination procedure per Sec.
63.1510(j)(5).
[[Page 92]]
Lime injection rate........ For continuous injection systems, record
feeder setting daily and inspect each
feed hopper or silo every 8 hrs to
verify that lime is free-flowing;
record results of each inspection. If
blockage occurs, inspect every 4 hrs
for 3 days; return to 8-hour
inspections if corrective action
results in no further blockage during 3-
day period. \d\
In-line fluxer using no reactive flux.... Flux materials............. Record flux materials; certify every 6
months for no reactive flux.
Group 1 furnace with lime-injected fabric Bag leak detector or....... Install and operate in accordance with
filter. ``Fabric Filter Bag Leak Detection
Guidance'' \c\; record output voltage
from bag leak detector.
COM........................ Design and install in accordance with PS-
1; collect data in accordance with
subpart A of 40 part CFR 63; determine
and record 6-minute block averages.
Lime injection rate........ For continuous injection systems, record
feeder setting daily and inspect each
feed hopper or silo every 8 hours to
verify that lime is free-flowing;
record results of each inspection. If
blockage occurs, inspect every 4 hours
for 3 days; return to 8-hour
inspections if corrective action
results in no further blockage during 3-
day period. \d\
Reactive flux injection Weight measurement device accuracy of
rate. 1%\b\; calibrate
every 3 months; record weight and type
of reactive flux added or injected for
each 15-minute block period while
reactive fluxing occurs; calculate and
record total reactive flux injection
rate for each operating cycle or time
period used in performance test; or
Alternative flux injection rate
determination procedure per Sec.
63.1510(j)(5).
Fabric filter inlet Continuous measurement device to meet
temperature. specifications in Sec. 63.1510(h)(2);
record temperatures in 15-minute block
averages; determine and record 3-hour
block averages.
Maintain molten aluminum Maintain aluminum level operating log;
level in sidewell furnace. certify every 6 months.
Group 1 furnace without add-on controls.. Fluxing in sidewell furnace Maintain flux addition operating log;
hearth. certify every 6 months.
Reactive flux injection Weight measurement device accuracy of
rate. +1% \b\; calibrate according to
manufacturers specifications or at
least once every six months; record
weight and type of reactive flux added
or injected for each 15-minute block
period while reactive fluxing occurs;
calculate and record total reactive
flux injection rate for each operating
cycle or time period used in
performance test.
OM&M plan (approved by Demonstration of site-specific
permitting agency). monitoring procedures to provide data
and show correlation of emissions
across the range of charge and flux
materials and furnace operating
parameters.
Feed material (melting/ Record type of permissible feed/charge
holding furnace). material; certify charge materials
every 6 months.
Clean (group 2) furnace.................. Charge and flux materials.. Record charge and flux materials;
certify every 6 months for clean charge
and no reactive flux.
----------------------------------------------------------------------------------------------------------------
\a\ Thermal chip dryers, scrap dryers/delacquering kilns/decoating kilns, dross-only furnaces, in-line fluxers
and group 1 furnaces or melting/holding furnaces.
\b\ Permitting agency may approve measurement devices of alternative accuracy, for example in cases where flux
rates are very low and costs of meters of specified accuracy are prohibitive; or where feed/charge weighing
devices of specified accuracy are not practicable due to equipment layout or charging practices.
\c\ Non-triboelectric bag leak detectors must be installed and operated in accordance with manufacturers'
specifications.
\d\ Permitting agency may approve other alternatives including load cells for lime hopper weight, sensors for
carrier gas pressure, or HCl monitoring devices at fabric filter outlet.
[65 FR 15710, Mar. 23, 2000, as amended at 69 FR 53985, Sept. 3, 2004]
Appendix A to Subpart RRR of Part 63--General Provisions Applicability
to Subpart RRR
----------------------------------------------------------------------------------------------------------------
Citation Requirement Applies to RRR Comment
----------------------------------------------------------------------------------------------------------------
Sec. 63.1(a)(1)-(4)................... General Applicability. Yes. .....................
Sec. 63.1(a)(5)....................... ...................... No..................... [Reserved].
Sec. 63.1(a)(6)-(8)................... ...................... Yes. .....................
Sec. 63.1(a)(9)....................... ...................... No..................... [Reserved].
Sec. 63.1(a) (10)-(14)................ ...................... Yes. .....................
Sec. 63.1(b).......................... Initial Applicability Yes.................... EPA retains approval
Determination. authority.
Sec. 63.1(c)(1)....................... Applicability After Yes. .....................
Standard Established.
[[Page 93]]
Sec. 63.1(c)(2)....................... ...................... Yes.................... Sec. 63.1500(e)
exempts area sources
subject to this
subpart from the
obligation to obtain
Title V operating
permits.
Sec. 63.1(c)(3)....................... ...................... No..................... [Reserved].
Sec. 63.1(c)(4)-(5)................... ...................... Yes. .....................
Sec. 63.1(d).......................... ...................... No..................... [Reserved].
Sec. 63.1(e).......................... Applicability of Yes. .....................
Permit Program.
Sec. 63.2............................. Definitions........... Yes.................... Additional
definitions in Sec.
63.1503.
Sec. 63.3............................. Units and Yes.................... .....................
Abbreviations.
Sec. 63.4(a)(1)-(3)................... Prohibited Activities. Yes. .....................
Sec. 63.4(a)(4)....................... ...................... No..................... [Reserved]
Sec. 63.4(a)(5)....................... ...................... Yes. .....................
Sec. 63.4(b)-(c)...................... Circumvention/ Yes. .....................
Severability.
Sec. 63.5(a).......................... Construction and Yes. .....................
Reconstruction--Appli
cability.
Sec. 63.5(b)(1)....................... Existing, New, Yes. .....................
Reconstructed
Sources--Requirements.
Sec. 63.5(b)(2)....................... ...................... No..................... [Reserved].
Sec. 63.5(b)(3)-(6)................... ...................... Yes. .....................
Sec. 63.5(c).......................... ...................... No..................... [Reserved].
Sec. 63.5(d).......................... Application for Yes. .....................
Approval of
Construction/
Reconstruction.
Sec. 63.5(e).......................... Approval of Yes. .....................
Construction/
Reconstruction.
Sec. 63.5(f).......................... Approval of Yes. .....................
Construction/
Reconstruction Based
on State Review.
Sec. 63.6(a).......................... Compliance with Yes. .....................
Standards and
Maintenance--Applicab
ility.
Sec. 63.6(b)(1)-(5)................... New and Reconstructed Yes. .....................
Sources--Dates.
Sec. 63.6(b)(6)....................... ...................... No..................... [Reserved].
Sec. 63.6(b)(7)....................... ...................... Yes. .....................
Sec. 63.6(c)(1)....................... Existing Sources Dates Yes.................... Sec. 63.1501
specifies dates.
Sec. 63.6(c)(2)....................... ...................... Yes. .....................
Sec. 63.6(c)(3)-(4)................... ...................... No..................... [Reserved].
Sec. 63.6(c)(5)....................... ...................... Yes. .....................
Sec. 63.6(d).......................... ...................... No..................... [Reserved].
Sec. 63.6(e)(1)-(2)................... Operation & Yes.................... Sec. 63.1510
Maintenance requires plan.
Requirements.
Sec. 63.6(e)(3)....................... Startup, Shutdown, and Yes. .....................
Malfunction Plan.
Sec. 63.6(f).......................... Compliance with Yes. .....................
Emission Standards.
Sec. 63.6(g).......................... Alternative Standard.. No..................... .....................
Sec. 63.6(h).......................... Compliance with Yes. .....................
Opacity/VE Standards.
Sec. 63.6(i)(1)-(14).................. Extension of Yes. .....................
Compliance.
Sec. 63.6(i)(15)...................... ...................... No..................... [Reserved].
Sec. 63.6(i)(16)...................... ...................... Yes. .....................
Sec. 63.6(j).......................... Exemption from Yes. .....................
Compliance.
Sec. 63.7(a)-(h)...................... Performance Test Yes.................... Except Sec. 63.1511
Requirements- establishes dates
Applicability and for initial
Dates. performance tests.
Sec. 63.7(b).......................... Notification.......... Yes. .....................
Sec. 63.7(c).......................... Quality Assurance/Test Yes. .....................
Plan.
Sec. 63.7(d).......................... Testing Facilities.... Yes. .....................
Sec. 63.7(e).......................... Conduct of Tests...... Yes. .....................
Sec. 63.7(f).......................... Alternative Test Yes. .....................
Method.
Sec. 63.7(g).......................... Data Analysis......... Yes. .....................
Sec. 63.7(h).......................... Waiver of Tests....... Yes. .....................
Sec. 63.8(a)(1)....................... Monitoring Yes. .....................
Requirements--Applica
bility.
Sec. 63.8(a)(2)....................... ...................... Yes. .....................
Sec. 63.8(a)(3)....................... ...................... No..................... [Reserved]
Sec. 63.8(a)(4)....................... ...................... Yes.................... .....................
Sec. 63.8(b).......................... Conduct of Monitoring. Yes. .....................
Sec. 63.8(c)(1)-(3)................... CMS Operation and Yes. .....................
Maintenance.
Sec. 63.8(c)(4)-(8)................... ...................... Yes. .....................
Sec. 63.8(d).......................... Quality Control....... Yes. .....................
Sec. 63.8(e).......................... CMS Performance Yes. .....................
Evaluation.
[[Page 94]]
Sec. 63.8(f)(1)-(5)................... Alternative Monitoring No..................... Sec. 63.1510(w)
Method. includes provisions
for monitoring
alternatives.
Sec. 63.8(f)(6)....................... Alternative to RATA Yes. .....................
Test.
Sec. 63.8(g)(1)....................... Data Reduction........ Yes. .....................
Sec. 63.8(g)(2)....................... ...................... No..................... Sec. 63.1512
requires five 6-
minute averages for
an aluminum scrap
shredder.
Sec. 63.8(g)(3)-(5)................... ...................... Yes. .....................
Sec. 63.9(a).......................... Notification Yes. .....................
Requirements--Applica
bility.
Sec. 63.9(b).......................... Initial Notifications. Yes. .....................
Sec. 63.9(c).......................... Request for Compliance Yes. .....................
Extension.
Sec. 63.9(d).......................... New Source Yes. .....................
Notification for
Special Compliance
Requirements.
63.9(e)................................. Notification of Yes. .....................
Performance Test.
Sec. 63.9(f).......................... Notification of VE/ Yes. .....................
Opacity Test.
Sec. 63.9(g).......................... Additional CMS Yes. .....................
Notifications.
Sec. 63.9(h)(1)-(3)................... Notification of Yes.................... Except Sec. 63.1515
Compliance Status. establishes dates
for notification of
compliance status
reports.
Sec. 63.9(h)(4)....................... ...................... No..................... [Reserved].
Sec. 63.9(h)(5)-(6)................... ...................... Yes. .....................
Sec. 63.9(i).......................... Adjustment of Yes. .....................
Deadlines.
Sec. 63.9(j).......................... Change in Previous Yes. .....................
Information.
Sec. 63.10(a)......................... Recordkeeping/ Yes. .....................
Reporting--Applicabil
ity.
Sec. 63.10(b)......................... General Requirements.. Yes.................... Sec. 63.1517
includes additional
requirements.
Sec. 63.10(c)(1)...................... Additional CMS Yes. .....................
Recordkeeping.
Sec. 63.10(c)(2)-(4).................. ...................... No..................... [Reserved].
Sec. 63.10(c)(5)...................... ...................... Yes. .....................
Sec. 63.10(c)(6)...................... ...................... Yes. .....................
Sec. 63.10(c)(7)-(8).................. ...................... Yes. .....................
Sec. 63.10(c)(9)...................... ...................... No..................... [Reserved].
Sec. 63.10(c)(10)-(13)................ ...................... Yes. .....................
Sec. 63.10(c)(14)..................... ...................... Yes. .....................
Sec. 63.10(d)(1)...................... General Reporting Yes. .....................
Requirements.
Sec. 63.10(d)(2)...................... Performance Test Yes. .....................
Results.
Sec. 63.10(d)(3)...................... Opacity or VE Yes. .....................
Observations.
Sec. 63.10(d)(4)-(5).................. Progress Reports/ Yes. .....................
Startup, Shutdown,
and Malfunction
Reports.
Sec. 63.10(e)(1)-(2).................. Additional CMS Reports Yes. .....................
Sec. 63.10(e)(3)...................... Excess Emissions/CMS Yes.................... Reporting deadline
Performance Reports. given in Sec.
63.1516.
Sec. 63.10(e)(4)...................... COMS Data Reports..... Yes. .....................
Sec. 63.10(f)......................... Recordkeeping/ Yes. .....................
Reporting Waiver.
Sec. 63.11(a)-(b)..................... Control Device No..................... Flares not
Requirements. applicable.
Sec. 63.12(a)-(c)..................... State Authority and Yes. EPA retains authority
Delegations. for applicability
determinations.
Sec. 63.13............................ Addresses............. Yes. .....................
Sec. 63.14............................ Incorporation by Yes.................... Chapters 3 and 5 of
Reference. ACGIH Industrial
Ventilation Manual
for capture/
collection systems;
and Interim
Procedures for
Estimating Risk
Associated with
Exposure to Mixtures
of Chlorinated
Dibenzofurans (CDDs
and CDFs) and 1989
Update (incorporated
by reference in Sec.
63.1502).
Sec. 63.15............................ Availability of Yes. .....................
Information/
Confidentiality.
----------------------------------------------------------------------------------------------------------------
[65 FR 15710, Mar. 23, 2000, as amended at 67 FR 59793, Sept. 24, 2002;
67 FR 79818, Dec. 30, 2002; 69 FR 53986, Sept. 3, 2004; 70 FR 75346,
Dec. 19, 2005]
[[Page 95]]
Subpart SSS [Reserved]
Subpart TTT_National Emission Standards for Hazardous Air Pollutants for
Primary Lead Smelting
Source: 64 FR 30204, June 4, 1999, unless othewise noted.
Sec. 63.1541 Applicability.
(a) The provisions of this subpart apply to the following affected
sources at primary lead smelters: sinter machine, blast furnace, dross
furnace, process fugitive sources, and fugitive dust sources. The
provisions of this subpart do not apply to secondary lead smelters, lead
refiners, or lead remelters.
(b) Table 1 of this subpart specifies the provisions of subpart A
that apply and those that do not apply to owners and operators of
primary lead smelters. The following sections of part 63 apply to this
subpart as stated in subpart A and Table 1: Sec. 63.1 (Applicability),
Sec. 63.2 (Definitions), Sec. 63.3 (Units and abbreviations), Sec.
63.4 (Prohibited activities and circumvention), Sec. 63.5 (Construction
and reconstruction), Sec. 63.7 (Performance testing requirements),
Sec. 63.8 (Monitoring requirements), Sec. 63.12 (State authority and
delegations), Sec. 63.13 (Addresses of State air pollution control
agencies and EPA Regional Offices), Sec. 63.14 (Incorporations by
reference), and Sec. 63.15 (Availability of information
confidentiality). The following sections of part 63 apply to the extent
specified in this subpart and Table 1: Sec. 63.6 (Compliance with
standards and maintenance requirements), Sec. 63.9 (Notification
requirements), and Sec. 63.10 (Recordkeeping and reporting
requirements). Section Sec. 63.11 (Control device requirements) does
not apply to this subpart.
Sec. 63.1542 Definitions.
Terms used in this subpart are defined in the Act, in subpart A of
this part, or in this section as follows:
Bag leak detection system means a system that is capable of
continuously monitoring relative particulate matter (dust) loadings in
the exhaust of a baghouse in order to detect bag leaks and other upset
conditions. A bag leak detection system includes, but is not limited to,
an instrument that operates on triboelectric, light scattering, light
transmittance, or other effect to continuously monitor relative
particulate matter loadings.
Blast furnace means any reduction furnace to which sinter is charged
and which forms separate layers of molten slag and lead bullion.
Building means a roofed and walled structure with limited openings
to allow access and egress for people and vehicles.
Charging location means the physical opening through which raw
materials are introduced into a sinter machine, blast furnace, or dross
furnace.
Dross furnace means any smelting furnace to which drosses are
charged and which chemically and physically separates lead from other
impurities.
Drossing and refining kettle means an open-top vessel that is
constructed of cast iron or steel and is indirectly heated from below
and contains molten lead for the purpose of drossing, refining, or
alloying lead. Included are pot furnaces, receiving kettles, and holding
kettles.
Fugitive dust source means a stationary source of hazardous air
pollutant emissions at a primary lead smelter resulting from the
handling, storage, transfer, or other management of lead-bearing
materials where the source is not associated with a specific process,
process vent, or stack. Fugitive dust sources include roadways, storage
piles, materials handling transfer points, and materials transport
areas.
Furnace area means any area of a primary lead smelter in which a
blast furnace or dross furnace is located.
Malfunction means any sudden, infrequent, and not reasonably
preventable failure of air pollution control equipment, process
equipment, or a process to operate in a normal or usual manner which
causes, or has the potential to cause, the emission limitations in an
applicable standard to be exceeded. Failures that are caused in part by
poor maintenance or careless operation are not malfunctions.
Materials storage and handling area means any area of a primary lead
smelter in which lead-bearing materials (including ore concentrate,
sinter,
[[Page 96]]
granulated lead, dross, slag, and flue dust) are stored or handled
between process steps, including areas in which materials are stored in
piles, bins, or tubs, and areas in which material is prepared for
charging to a sinter machine or smelting furnace.
Operating time means the period of time in hours that an affected
source is in operation beginning at a startup and ending at the next
shutdown.
Plant operating time means the period of time in hours that either a
sinter machine or blast furnace is in operation.
Plant roadway means any area of a primary lead smelter that is
subject to vehicle traffic, including traffic by fork lifts, front-end
loaders, or vehicles carrying ore concentrates or cast lead ingots.
Excluded from this definition are employee and visitor parking areas,
provided they are not subject to traffic by vehicles carrying lead-
bearing materials.
Primary lead smelter means any facility engaged in the production of
lead metal from lead sulfide ore concentrates through the use of
pyrometallurgical techniques.
Process fugitive source means a source of hazardous air pollutant
emissions at a primary lead smelter that is associated with lead
smelting or refining but is not the primary exhaust stream and is not a
fugitive dust source. Process fugitive sources include sinter machine
charging locations, sinter machine discharge locations, sinter crushing
and sizing equipment, furnace charging locations, furnace taps, drossing
kettles, and refining kettles.
Refining and casting area means any area of a primary lead smelter
in which drossing or refining operations occur, or casting operations
occur.
Shutdown means the cessation of operation of an affected source for
any purpose.
Sinter machine means any device in which a lead sulfide ore
concentrate charge is heated in the presence of air to eliminate sulfur
contained in the charge and to agglomerate the charge into a hard porous
mass called sinter.
Sinter machine area means any area of a primary lead smelter where a
sinter machine, or sinter crushing and sizing equipment is located.
Sinter machine discharge end means the physical opening at the end
of a sinter machine where the sinter exits the sinter machine.
Startup means the setting in operation of an affected source for any
purpose.
Tapping location means the opening thru which lead and slag are
removed from the furnace.
[64 FR 30204, June 4, 1999, as amended at 71 FR 20462, Apr. 20, 2006]
Sec. 63.1543 Standards for process and process fugitive sources.
(a) No owner or operator of any existing, new, or reconstructed
primary lead smelter shall discharge or cause to be discharged into the
atmosphere lead compounds in excess of 500 grams of lead per megagram of
lead metal produced (1.0 pounds of lead per ton of lead metal produced)
from the aggregation of emissions discharged from the air pollution
control devices used to control emissions from the sources listed in
paragraphs (a)(1) through (a)(9) of this section.
(1) Sinter machine;
(2) Blast furnace;
(3) Dross furnace;
(4) Dross furnace charging location;
(5) Blast furnace and dross furnace tapping location;
(6) Sinter machine charging location;
(7) Sinter machine discharge end;
(8) Sinter crushing and sizing equipment; and
(9) Sinter machine area.
(b) The process fugitive sources listed in paragraphs (a)(4) through
(a)(8) of this section shall be equipped with a hood and shall be
ventilated to a baghouse or equivalent control device. The hood design
and ventilation rate shall be consistent with American Conference of
Governmental Industrial Hygienists recommended practices.
(c) The sinter machine area shall be enclosed in a building that is
ventilated to a baghouse or equivalent control device at a rate that
maintains a positive in-draft through any doorway opening.
(d) Except as provided in paragraph (e) of this section, following
the initial test to demonstrate compliance with paragraph (a) of this
section, the owner or operator of a primary lead smelter
[[Page 97]]
shall conduct a compliance test for lead compounds on an annual basis
(no later than 12 calendar months following any previous compliance
test).
(e) If the three most recent compliance tests demonstrate compliance
with the emission limit specified in paragraph (a) of this section, the
owner or operator of a primary lead smelter shall be allowed up to 24
calendar months from the last compliance test to conduct the next
compliance test for lead compounds.
(f) The owner or operator of a primary lead smelter shall maintain
and operate each baghouse used to control emissions from the sources
listed in paragraphs (a)(1) through (a)(9) of this section such that the
alarm on a bag leak detection system required under Sec. 63.1547(c)(9)
does not sound for more than five percent of the total operating time in
a 6-month reporting period.
(g) The owner or operator of a primary lead smelter shall record the
date and time of a bag leak detection system alarm and initiate
procedures to determine the cause of the alarm according to the
corrective action plan required under Sec. 63.1547(c)(9) within 1 hour
of the alarm. The cause of the alarm shall be corrected as soon as
practicable.
Sec. 63.1544 Standards for fugitive dust sources.
(a) Each owner or operator of a primary lead smelter shall prepare,
and at all times operate according to, a standard operating procedures
manual that describes in detail the measures that will be put in place
to control fugitive dust emissions from the sources listed in paragraphs
(a)(1) through (a)(5) of this section:
(1) Plant roadways;
(2) Material storage and handling area(s);
(3) Sinter machine area(s);
(4) Furnace area(s); and
(5) Refining and casting area(s).
(b) Not withstanding paragraph (c) of this section, the standard
operating procedures manual shall be submitted to the Administrator or
delegated authority for review and approval.
(c) Existing manuals that describe the measures in place to control
fugitive dust sources required as part of a State implementation plan
for lead shall satisfy the requirements of paragraph (a) of this section
provided they address the sources listed in paragraphs (a)(1) through
(a)(5) of this section.
Sec. 63.1545 Compliance dates.
(a) Each owner or operator of an existing primary lead smelter shall
achieve compliance with the requirements of this subpart no later than
May 4, 2001.
(b) Each owner or operator of a primary lead smelter that commences
construction or reconstruction after April 17, 1998, shall achieve
compliance with the requirements of this subpart by June 4, 1999 or upon
startup of operations, whichever is later.
Sec. 63.1546 Test methods.
(a) The following procedure shall be used to determine compliance
with the emissions standard for lead compounds under Sec. 63.1543(a):
(1) The lead compound emission rate, in units of grams of lead per
hour, for each source listed in Sec. 63.1543(a)(1) through Sec.
63.1543(a)(9) shall be determined according to the following test
methods in appendix A of part 60 of this chapter:
(i) Method 1 shall be used to select the sampling port location and
the number of traverse points.
(ii) Method 2 shall be used to measure volumetric flow rate.
(iii) Method 3 shall be used for gas analysis.
(iv) Method 4 shall be used to determine moisture content of the
stack gas
(v) Method 12 shall be used to measure the lead emission rate of the
stack gas. The minimum sample volume shall be 0.85 dry standard cubic
meters (30 dry standard cubic feet) and the minimum sampling time shall
be 60 minutes for each run. Three runs shall be performed and the
average of the three runs shall be used to determine compliance.
(2) The lead production rate, in units of megagrams per hour, shall
be determined based on production data for the previous 12 calendar
months according to the procedures detailed in paragraphs (a)(2)(i)
through (a)(2)(v) of this section:
[[Page 98]]
(i) Total lead products production multiplied by the fractional lead
content shall be determined in units of megragrams.
(ii) Total copper matte production multiplied by the fractional lead
content shall be determined in units of megragrams.
(iii) Total copper speiss production multiplied by the fractional
lead content shall be determined in units of megragrams.
(iv) Total lead production shall be determined by summing the values
obtained in paragraphs (a)(2)(i) through (a)(2)(iii) of this section.
(v) The lead production rate, in units of megragrams per hours,
shall be calculated based on the total lead production, as determined in
accordance with paragraph (a)(2)(iv) of this section, divided by the
total plant operating time, in hours, for the previous 12 months.
(3) The sum of lead compound emission rates for the sources in Sec.
63.1543(a)((1) through (a)(9), as determined in accordance with
paragraph (a)(1) of this section, shall be divided by the lead
production rate, as determined in accordance with paragraph (a)(2)(v) of
this section, to obtain a production-based, lead compound emission rate
in units of grams of lead per megagram of lead metal produced. The
production-based, lead compound emission rate shall be used to determine
compliance with the emissions standard for lead compounds under Sec.
63.1543(a).
(b) Owner and operators shall perform an initial compliance test to
demonstrate compliance with the sinter building in-draft requirements of
Sec. 63.1543(c) at each doorway opening in accordance with paragraphs
(b)(1) through (b)(4) of this section.
(1) Use a propeller anemometer or equivalent device.
(2) Determine doorway in-draft by placing the anemometer in the
plane of the doorway opening near its center.
(3) Determine doorway in-draft for each doorway that is open during
normal operation with all remaining doorways in their customary position
during normal operation.
(4) Do not determine doorway in-draft when ambient wind speed
exceeds 2 meters per second.
Sec. 63.1547 Monitoring requirements.
(a) Owners and operators of primary lead smelters shall prepare, and
at all times operate according to, a standard operating procedures
manual that describes in detail the procedures for inspection,
maintenance, and bag leak detection and corrective action for all
baghouses that are used to control process, process fugitive, or
fugitive dust emissions from any source subject to the lead emission
standards in Sec. Sec. 63.1543 and 63.1544, including those used to
control emissions from general ventilation systems.
(b) The standard operating procedures manual for baghouses required
by paragraph (a) of this section shall be submitted to the Administrator
or delegated authority for review and approval.
(c) The procedures specified in the standard operating procedures
manual for inspections and routine maintenance shall, at a minimum,
include the requirements of paragraphs (c)(1) through (c)(9) of this
section.
(1) Daily monitoring of pressure drop across each baghouse cell to
ensure pressure drop is within the normal operating range identified in
the standard operating procedures manual.
(2) Weekly confirmation that dust is being removed from hoppers
through visual inspection or equivalent means of ensuring the proper
functioning of removal mechanisms.
(3) Daily check of compressed air supply for pulse-jet baghouses.
(4) An appropriate methodology for monitoring cleaning cycles to
ensure proper operation.
(5) Monthly check of bag cleaning mechanisms for proper functioning
through visual inspection or equivalent means.
(6) Quarterly visual check of bag tension on reverse air and shaker-
type baghouses to ensure that bags are not kinked (kneed or bent) or
laying on their sides. Such checks are not required for shaker-type
baghouses using self-tensioning (spring loaded) devices.
(7) Quarterly confirmation of the physical integrity of the baghouse
[[Page 99]]
through visual inspection of the baghouse interior for air leaks.
(8) Quarterly inspection of fans for wear, material buildup, and
corrosion through visual inspection, vibration detectors, or equivalent
means.
(9) Except as provided in paragraph (h) of this section, continuous
operation of a bag leak detection system.
(d) The procedures specified in the standard operating procedures
manual for maintenance shall, at a minimum, include a preventative
maintenance schedule that is consistent with the baghouse manufacturer's
instructions for routine and long-term maintenance.
(e) The bag leak detection system required by paragraph (c)(9) of
this section shall meet the specifications and requirements of (e)(1)
through (e)(8) of this section.
(1) The bag leak detection system must be certified by the
manufacturer to be capable of detecting particulate matter emissions at
concentrations of 10 milligram per actual cubic meter (0.0044 grains per
actual cubic foot) or less.
(2) The bag leak detection system sensor must provide output of
relative particulate matter loadings, and the owner or operator shall
continuously record the output from the bag leak detection system.
(3) The bag leak detection system must be equipped with an alarm
system that will sound when an increase in relative particulate loading
is detected over a preset level, and the alarm must be located such that
it can be heard by the appropriate plant personnel.
(4) Each bag leak detection system that works based on the
triboelectric effect shall be installed, calibrated, and maintained in a
manner consistent with guidance provided in the U.S. Environmental
Protection Agency guidance document ``Fabric Filter Bag Leak Detection
Guidance'' (EPA-454/R-98-015). Other bag leak detection systems shall be
installed, calibrated, and maintained in a manner consistent with the
manufacturer's written specifications and recommendations.
(5) The initial adjustment of the system shall, at a minimum,
consist of establishing the baseline output by adjusting the sensitivity
(range) and the averaging period of the device, and establishing the
alarm set points and the alarm delay time.
(6) Following initial adjustment, the owner or operator shall not
adjust the sensitivity or range, averaging period, alarm set points, or
alarm delay time, except as detailed in the approved SOP required under
paragraph (a) of this section. In no event shall the sensitivity be
increased by more than 100 percent or decreased more than 50 percent
over a 365-day period unless a responsible official certifies that the
baghouse has been inspected and found to be in good operating condition.
(7) For negative pressure, induced air baghouses, and positive
pressure baghouses that are discharged to the atmosphere through a
stack, the bag leak detector must be installed downstream of the
baghouse and upstream of any wet acid gas scrubber.
(8) Where multiple detectors are required, the system's
instrumentation and alarm may be shared among detectors.
(f) The standard operating procedures manual required by paragraph
(a) of this section shall include a corrective action plan that
specifies the procedures to be followed in the event of a bag leak
detection system alarm. The corrective action plan shall include, at a
minimum, procedures to be used to determine the cause of an alarm, as
well as actions to be taken to minimize emissions, which may include,
but are not limited to, the following.
(1) Inspecting the baghouse for air leaks, torn or broken bags or
filter media, or any other condition that may cause an increase in
emissions.
(2) Sealing off defective bags or filter media.
(3) Replacing defective bags or filter media, or otherwise repairing
the control device.
(4) Sealing off a defective baghouse compartment.
(5) Cleaning the bag leak detection system probe, or otherwise
repairing the bag leak detection system.
(6) Shutting down the process producing the particulate emissions.
[[Page 100]]
(g) The percentage of total operating time the alarm on the bag leak
detection system sounds in a 6-month reporting period shall be
calculated in order to determine compliance with the five percent
operating limit in Sec. 63.1543(f). The percentage of time the alarm on
the bag leak detection system sounds shall be determined according to
paragraphs (g)(1) through (g)(5) of this section.
(1) Alarms that occur due solely to a malfunction of the bag leak
detection system shall not be included in the calculation.
(2) Alarms that occur during startup, shutdown, or malfunction shall
not be included in the calculation if the condition is described in the
startup, shutdown, and malfunction plan and the owner or operator
operates the source during such periods in accordance with Sec.
63.6(e)(1).
(3) For each alarm where the owner or operator initiates procedures
to determine the cause of an alarm within 1 hour of the alarm, 1 hour of
alarm time shall be counted.
(4) For each alarm where the owner or operator does not initiate
procedures to determine the cause of the alarm within 1 hour of the
alarm, alarm time will be counted as the actual amount of time taken by
the owner or operator to initiate procedures to determine the cause of
the alarm.
(5) The percentage of time the alarm on the bag leak detection
system sounds shall be calculated as the ratio of the sum of alarm times
to the total operating time multiplied by 100.
(h) Baghouses equipped with HEPA filters as a secondary filter used
to control process or process fugitive sources subject to the lead
emission standards in Sec. 63.1543 are exempt from the requirement in
Sec. 63.1543(c)(9) to be equipped with a bag leak detector. The owner
or operator of an affected source that uses a HEPA filter shall monitor
and record the pressure drop across the HEPA filter system daily. If the
pressure drop is outside the limit(s) specified by the filter
manufacturer, the owner or operator must take appropriate corrective
measures, which may include, but not be limited to, the following:
(1) Inspecting the filter and filter housing for air leaks and torn
or broken filters.
(2) Replacing defective filter media, or otherwise repairing the
control device.
(3) Sealing off a defective control device by routing air to other
control devices.
(4) Shutting down the process producing the particulate emissions.
(i) Owners and operators shall monitor sinter machine building in-
draft to demonstrate continued compliance with the operating standard
specified in Sec. 63.1543(c) in accordance with either paragraph
(i)(1), (i)(2), or (i)(3) of this section.
(1) Owners and operators shall check and record on a daily basis
doorway in-draft at each doorway in accordance with the methodology
specified in Sec. 63.1546(b).
(2) Owners and operators shall establish and maintain baseline
ventilation parameters which result in a positive in-draft according to
paragraphs (i)(2)(i) through (i)(2)(iv) of this section.
(i) Owners and operators shall install, calibrate, maintain, and
operate a monitoring device that continuously records the actual
volumetric flow rate through each separately ducted hood; or install,
calibrate, maintain, and operate a monitoring device that continuously
records the volumetric flow rate at the control device inlet of each
exhaust system ventilating the building. The flow rate monitoring
device(s) can be installed in any location in the exhaust duct such that
reproducible flow rate monitoring will result. The flow rate monitoring
device(s) shall have an accuracy of plus or minus 10 percent over its
normal operating range and shall be calibrated according to
manufacturer's instructions.
(ii) During the initial demonstration of sinter building in-draft,
and at any time the owner or operator wishes to re-establish the
baseline ventilation parameters, the owner or operator shall
continuously record the volumetric flow rate through each separately
ducted hood, or continuously record the volumetric flow rate at the
control device inlet of each exhaust system ventilating the building and
[[Page 101]]
record exhaust system damper positions. The owner or operator shall
determine the average volumetric flow rate(s) corresponding to the
period of time the in-draft compliance determinations are being
conducted.
(iii) The owner or operator shall maintain the volumetric flow
rate(s) at or above the value(s) established during the most recent in-
draft determination at all times the sinter machine is in operation.
Volumetric flow rate(s) shall be calculated as a 15-minute average.
(iv) If the volumetric flow rate is monitored at the control device
inlet, the owner or operator shall check and record damper positions
daily to ensure they are in the positions they were in during the most
recent in-draft determination.
(3) An owner or operator may request an alternative monitoring
method by following the procedures and requirements in Sec. 63.8(f) of
the General Provisions.
[64 FR 30204, June 4, 1999, as amended at 71 FR 20462, Apr. 20, 2006]
Sec. 63.1548 Notification requirements.
(a) The owner or operator of a primary lead smelter shall comply
with all of the notification requirements of Sec. 63.9 of subpart A,
General Provisions.
(b) The owner or operator of a primary lead smelter shall submit the
fugitive dust control standard operating procedures manual required
under Sec. 63.1544(a) and the standard operating procedures manual for
baghouses required under Sec. 63.1547(a) to the Administrator or
delegated authority along with a notification that the smelter is
seeking review and approval of these plans and procedures. Owners or
operators of existing primary lead smelters shall submit this
notification no later than November 6, 2000. The owner or operator of a
primary lead smelter that commences construction or reconstruction after
April 17, 1998, shall submit this notification no later than 180 days
before startup of the constructed or reconstructed primary lead smelter,
but no sooner than September 2, 1999.
Sec. 63.1549 Recordkeeping and reporting requirements.
(a) The owner or operator of a primary lead smelter shall comply
with all of the recordkeeping requirements of Sec. 63.10 of subpart A,
General Provisions.
(b) In addition to the general records required by paragraph (a) of
this section, each owner or operator of a primary lead smelter shall
maintain for a period of 5 years, records of the information listed in
paragraphs (b)(1) through (b)(8) of this section.
(1) Production records of the weight and lead content of lead
products, copper matte, and copper speiss.
(2) Records of the bag leak detection system output.
(3) An identification of the date and time of all bag leak detection
system alarms, the time that procedures to determine the cause of the
alarm were initiated, the cause of the alarm, an explanation of the
actions taken, and the date and time the cause of the alarm was
corrected.
(4) Any recordkeeping required as part of the practices described in
the standard operating procedures manual required under Sec. 63.1544(a)
for the control of fugitive dust emissions.
(5) Any recorkeeping required as part of the practices described in
the standard operating procedures manual for baghouses required under
Sec. 63.1547(a).
(6) If an owner or operator chooses to demonstrate continuous
compliance with the sinter building in-draft requirement under Sec.
63.1543(c) by employing the method allowed in Sec. 63.1546(i)(1), the
records of the daily doorway in-draft checks, an identification of the
periods when there was not a positive in-draft, and an explanation of
the corrective actions taken.
(7) If an owner or operator chooses to demonstrate continuous
compliance with the sinter building in-draft requirement under Sec.
63.1543(c) by employing the method allowed in Sec. 63.1546(i)(2), the
records of the output from the continuous volumetric flow monitor(s), an
identification of the periods when the 15-minute volumetric flow rate
dropped below the minimum established during the most recent in-draft
determination, and an explanation of the corrective actions taken.
[[Page 102]]
(8) If an owner or operator chooses to demonstrate continuous
compliance with the sinter building in-draft requirement under Sec.
63.1543(c) by employing the method allowed in Sec. 63.1546(i)(2), and
volumetric flow rate is monitored at the baghouse inlet, records of the
daily checks of damper positions, an identification of the days that the
damper positions were not in the positions established during the most
recent in-draft determination, and an explanation of the corrective
actions taken.
(c) Records for the most recent 2 years of operation must be
maintained on site. Records for the previous 3 years may be maintained
off site.
(d) The owner or operator of a primary lead smelter shall comply
with all of the reporting requirements of Sec. 63.10 of subpart A,
General Provisions.
(e) In addition to the information required under Sec. 63.10 of the
General Provisions, the owner or operator shall provide semi-annual
reports containing the information specified in paragraphs (e)(1)
through (e)(7) of this section to the Administrator or designated
authority.
(1) The reports shall include records of all alarms from the bag
leak detection system specified in Sec. 63.1547(e).
(2) The reports shall include a description of the actions taken
following each bag leak detection system alarm pursuant to Sec.
63.1547(f).
(3) The reports shall include a calculation of the percentage of
time the alarm on the bag leak detection system sounded during the
reporting period pursuant to Sec. 63.1547(g).
(4) If an owner or operator chooses to demonstrate continuous
compliance with the sinter building in-draft requirement under Sec.
63.1543(c) by employing the method allowed in Sec. 63.1546(i)(1), the
reports shall contain an identification of the periods when there was
not a positive in-draft, and an explanation of the corrective actions
taken.
(5) If an owner or operator chooses to demonstrate continuous
compliance with the sinter building in-draft requirement under Sec.
63.1543(c) by employing the method allowed in Sec. 63.1546(i)(2), the
reports shall contain an identification of the periods when the 15-
minute volumetric flow rate(s) dropped below the minimum established
during the most recent in-draft determination, and an explanation of the
corrective actions taken.
(6) If an owner or operator chooses to demonstrate continuous
compliance with the sinter building in-draft requirement under Sec.
63.1543(c) by employing the method allowed in Sec. 63.1546(i)(2), and
volumetric flow rate is monitored at the baghouse inlet, the reports
shall contain an identification of the days that the damper positions
were not in the positions established during the most recent in-draft
determination, and an explanation of the corrective actions taken.
(7) The reports shall contain a summary of the records maintained as
part of the practices described in the standard operating procedures
manual for baghouses required under Sec. 63.1547(a), including an
explanation of the periods when the procedures were not followed and the
corrective actions taken.
(8) The reports shall contain a summary of the fugitive dust control
measures performed during the required reporting period, including an
explanation of any periods when the procedures outlined in the standard
operating procedures manual required by Sec. 63.1544(a) were not
followed and the corrective actions taken. The reports shall not contain
copies of the daily records required to demonstrate compliance with the
requirements of the standard operating procedures manuals required under
Sec. Sec. 63.1544(a) and Sec. 63.1547(a).
Sec. 63.1550 Implementation and enforcement.
(a) This subpart will be implemented and enforced by the U.S. EPA,
or a delegated authority such as the applicable State, local, or Tribal
agency. If the U.S. EPA Administrator has delegated authority to a
State, local, or Tribal agency, then that agency, in addition to the
U.S. EPA, has the authority to implement and enforce this subpart.
Contact the applicable U.S. EPA Regional Office to find out if this
subpart is delegated to a State, local, or Tribal agency.
(b) In delegating implementation and enforcement authority of this
subpart to a State, local, or Tribal agency
[[Page 103]]
under subpart E of this part, the authorities contained in paragraph (c)
of this section are retained by the Administrator of U.S. EPA and cannot
be transferred to the State, local, or Tribal agency.
(c) The authorities that cannot be delegated to State, local, or
Tribal agencies are as specified in paragraphs (c)(1) through (4) of
this section.
(1) Approval of alternatives to the requirements in Sec. Sec.
63.1541, 63.1543(a) through (c), (f) through (g), and 63.1544 through
63.1545.
(2) Approval of major alternatives to test methods under Sec.
63.7(e)(2)(ii) and (f), as defined in Sec. 63.90, and as required in
this subpart.
(3) Approval of major alternatives to monitoring under Sec.
63.8(f), as defined in Sec. 63.90, and as required in this subpart.
(4) Approval of major alternatives to recordkeeping and reporting
under Sec. 63.10(f), as defined in Sec. 63.90, and as required in this
subpart.
[68 FR 37360, June 23, 2003]
Table 1 to Subpart TTT of Part 63--Summary of Monitoring Requirements
for New and Existing Affected Sources and Emission Units
------------------------------------------------------------------------
Applies to subpart
Reference TTT Comment
------------------------------------------------------------------------
Sec. 63.1.................. Yes
Sec. 63.2.................. Yes
Sec. 63.3.................. Yes
Sec. 63.4.................. Yes
Sec. 63.5.................. Yes
Sec. 63.6(a), (b), (c), Yes
(e), (f), (g), (i) and (j).
Sec. 63.6(d) and (h)....... No No opacity limits in
rule.
Sec. 63.7.................. Yes
Sec. 63.8.................. Yes
Sec. 63.9 (a), (b), (c), Yes
(d), (e), (g), (h)(1)
through (3), (h)(5) and (6),
(i) and (j).
Sec. 63.9(f) and (h)(4).... No No opacity or visible
emission limits in
rule.
Sec. 63.10................. Yes
Sec. 63.11................. No Flares will not be
used to comply with
the emission limits.
Sec. 63.12 through 63.15... Yes
------------------------------------------------------------------------
Subpart UUU_National Emission Standards for Hazardous Air Pollutants for
Petroleum Refineries: Catalytic Cracking Units, Catalytic Reforming
Units, and Sulfur Recovery Units
Source: 67 FR 17773, Apr. 11, 2002, unless otherwise noted.
What This Subpart Covers
Sec. 63.1560 What is the purpose of this subpart?
This subpart establishes national emission standards for hazardous
air pollutants (HAP) emitted from petroleum refineries. This subpart
also establishes requirements to demonstrate initial and continuous
compliance with the emission limitations and work practice standards.
Sec. 63.1561 Am I subject to this subpart?
(a) You are subject to this subpart if you own or operate a
petroleum refinery that is located at a major source of HAP emissions.
(1) A petroleum refinery is an establishment engaged primarily in
petroleum refining as defined in the Standard Industrial Classification
(SIC) code 2911 and the North American Industry Classification (NAIC)
code 32411, and used mainly for:
(i) Producing transportation fuels (such as gasoline, diesel fuels,
and jet fuels), heating fuels (such as kerosene, fuel gas distillate,
and fuel oils), or lubricants;
(ii) Separating petroleum; or
[[Page 104]]
(iii) Separating, cracking, reacting, or reforming an intermediate
petroleum stream, or recovering a by-product(s) from the intermediate
petroleum stream (e.g., sulfur recovery).
(2) A major source of HAP is a plant site that emits or has the
potential to emit any single HAP at a rate of 9.07 megagrams (10 tons)
or more per year or any combination of HAP at a rate of 22.68 megagrams
(25 tons) or more per year.
(b) [Reserved]
Sec. 63.1562 What parts of my plant are covered by this subpart?
(a) This subpart applies to each new, reconstructed, or existing
affected source at a petroleum refinery.
(b) The affected sources are:
(1) The process vent or group of process vents on fluidized
catalytic cracking units that are associated with regeneration of the
catalyst used in the unit (i.e., the catalyst regeneration flue gas
vent).
(2) The process vent or group of process vents on catalytic
reforming units (including but not limited to semi-regenerative, cyclic,
or continuous processes) that are associated with regeneration of the
catalyst used in the unit. This affected source includes vents that are
used during the unit depressurization, purging, coke burn, and catalyst
rejuvenation.
(3) The process vent or group of process vents on Claus or other
types of sulfur recovery plant units or the tail gas treatment units
serving sulfur recovery plants, that are associated with sulfur
recovery.
(4) Each bypass line serving a new, existing, or reconstructed
catalytic cracking unit, catalytic reforming unit, or sulfur recovery
unit. This means each vent system that contains a bypass line (e.g.,
ductwork) that could divert an affected vent stream away from a control
device used to comply with the requirements of this subpart.
(c) An affected source is a new affected source if you commence
construction of the affected source after September 11, 1998, and you
meet the applicability criteria in Sec. 63.1561 at the time you
commenced construction.
(d) Any affected source is reconstructed if you meet the criteria in
Sec. 63.2.
(e) An affected source is existing if it is not new or
reconstructed.
(f) This subpart does not apply to:
(1) A thermal catalytic cracking unit.
(2) A sulfur recovery unit that does not recover elemental sulfur or
where the modified reaction is carried out in a water solution which
contains a metal ion capable of oxidizing the sulfide ion to sulfur
(e.g., the LO-CAT II process).
(3) A redundant sulfur recovery unit not located at a petroleum
refinery and used by the refinery only for emergency or maintenance
backup.
(4) Equipment associated with bypass lines such as low leg drains,
high point bleed, analyzer vents, open-ended valves or lines, or
pressure relief valves needed for safety reasons.
(5) Gaseous streams routed to a fuel gas system.
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6938, Feb. 9, 2005]
Sec. 63.1563 When do I have to comply with this subpart?
(a) If you have a new or reconstructed affected source, you must
comply with this subpart according to the requirements in paragraphs
(a)(1) and (2) of this section.
(1) If you startup your affected source before April 11, 2002, then
you must comply with the emission limitations and work practice
standards for new and reconstructed sources in this subpart no later
than April 11, 2002.
(2) If you startup your affected source after April 11, 2002, you
must comply with the emission limitations and work practice standards
for new and reconstructed sources in this subpart upon startup of your
affected source.
(b) If you have an existing affected source, you must comply with
the emission limitations and work practice standards for existing
affected sources in this subpart by no later than April 11, 2005 except
as specified in paragraph (c) of this section.
(c) We will grant an extension of compliance for an existing
catalytic cracking unit allowing additional time
[[Page 105]]
to meet the emission limitations and work practice standards for
catalytic cracking units in Sec. Sec. 63.1564 and 63.1565 if you commit
to hydrotreating the catalytic cracking unit feedstock and to meeting
the emission limitations of this subpart on the same date that your
facility meets the final Tier 2 gasoline sulfur control standard (40 CFR
part 80, subpart J). To obtain an extension, you must submit a written
notification to your permitting authority according to the requirements
in Sec. 63.1574(e). Your notification must include the information in
paragraphs (c)(1) and (2) of this section.
(1) Identification of the affected source with a brief description
of the controls to be installed (if needed) to comply with the emission
limitations for catalytic cracking units in this subpart.
(2) A compliance schedule, including the information in paragraphs
(c)(2)(i) through (iv) of this section.
(i) The date by which onsite construction or the process change is
to be initiated.
(ii) The date by which onsite construction or the process change is
to be completed.
(iii) The date by which your facility will achieve final compliance
with both the final Tier 2 gasoline sulfur control standard as specified
in Sec. 80.195, and the emission limitations and work practice
standards for catalytic cracking units in this subpart. In no case will
your permitting authority grant an extension beyond the date you are
required to meet the Tier 2 gasoline sulfur control standard or December
31, 2009, whichever comes first. If you don't comply with the emission
limitations and work practice standards for existing catalytic cracking
units by the specified date, you will be out-of-compliance with the
requirements for catalytic cracking units beginning April 11, 2005.
(iv) A brief description of interim emission control measures that
will be taken to ensure proper operation and maintenance of the process
equipment during the period of the compliance extension.
(d) If you have an area source that increases its emissions or its
potential to emit such that it becomes a major source of HAP, the
requirements in paragraphs (d)(1) and (2) of this section apply.
(1) Any portion of the existing facility that is a new affected
source or a new reconstructed source must be in compliance with the
requirements of this subpart upon startup.
(2) All other parts of the source must be in compliance with the
requirements of this subpart by no later than 3 years after it becomes a
major source or, if applicable, the extended compliance date granted
according to the requirements in paragraph (c) of this section.
(e) You must meet the notification requirements in Sec. 63.1574
according to the schedule in Sec. 63.1574 and in 40 CFR part 63,
subpart A. Some of the notifications must be submitted before the date
you are required to comply with the emission limitations and work
practice standards in this subpart.
Catalytic Cracking Units, Catalytic Reforming Units, Sulfur Recovery
Units, and Bypass Lines
Sec. 63.1564 What are my requirements for metal HAP emissions from
catalytic cracking units?
(a) What emission limitations and work practice standards must I
meet? You must:
(1) Meet each emission limitation in Table 1 of this subpart that
applies to you. If your catalytic cracking unit is subject to the NSPS
for PM in Sec. 60.102 of this chapter, you must meet the emission
limitations for NSPS units. If your catalytic cracking unit isn't
subject to the NSPS for PM, you can choose from the four options in
paragraphs (a)(1)(i) through (iv) of this section:
(i) You can elect to comply with the NSPS requirements (Option 1);
(ii) You can elect to comply with the PM emission limit (Option 2);
(iii) You can elect to comply with the Nickel (Ni) lb/hr emission
limit (Option 3); or
(iv) You can elect to comply with the Ni lb/1,000 lbs of coke burn-
off emission limit (Option 4).
(2) Comply with each operating limit in Table 2 of this subpart that
applies to you.
[[Page 106]]
(3) Prepare an operation, maintenance, and monitoring plan according
to the requirements in Sec. 63.1574(f) and operate at all times
according to the procedures in the plan.
(4) The emission limitations and operating limits for metal HAP
emissions from catalytic cracking units required in paragraphs (a)(1)
and (2) of this section do not apply during periods of planned
maintenance preapproved by the applicable permitting authority according
to the requirements in Sec. 63.1575(j).
(b) How do I demonstrate initial compliance with the emission
limitations and work practice standard? You must:
(1) Install, operate, and maintain a continuous monitoring system(s)
according to the requirements in Sec. 63.1572 and Table 3 of this
subpart.
(2) Conduct a performance test for each catalytic cracking unit not
subject to the NSPS for PM according to the requirements in Sec.
63.1571 and under the conditions specified in Table 4 of this subpart.
(3) Establish each site-specific operating limit in Table 2 of this
subpart that applies to you according to the procedures in Table 4 of
this subpart.
(4) Use the procedures in paragraphs (b)(4)(i) through (iv) of this
section to determine initial compliance with the emission limitations.
(i) If you elect Option 1 in paragraph (a)(1)(i) of ths section, the
NSPS requirements, compute the PM emission rate (lb/1,000 lbs of coke
burn-off) for each run using Equations 1, 2, and 3 (if applicable) of
this section as follows:
[GRAPHIC] [TIFF OMITTED] TR11AP02.000
Where:
Rc = Coke burn-off rate, kg/hr (lb/hr);
Qr = Volumetric flow rate of exhaust gas from catalyst
regenerator before adding air or gas streams. Example: You may measure
upstream or downstream of an electrostatic precipitator, but you must
measure upstream of a carbon monoxide boiler, dscm/min (dscf/min). You
may use the alternative in either Sec. 63.1573(a)(1) or (a)(2), as
applicable, to calculate Qr;
Qa = Volumetric flow rate of air to catalytic cracking unit
catalyst regenerator, as determined from instruments in the catalytic
cracking unit control room, dscm/min (dscf/min);
%CO2 = Carbon dioxide concentration in regenerator exhaust,
percent by volume (dry basis);
%CO = Carbon monoxide concentration in regenerator exhaust, percent by
volume (dry basis);
%O2 = Oxygen concentration in regenerator exhaust, percent by
volume (dry basis);
K1 = Material balance and conversion factor, 0.2982 (kg-min)/
(hr-dscm-%) (0.0186 (lb-min)/(hr-dscf-%));
K2 = Material balance and conversion factor, 2.088 (kg-min)/
(hr-dscm) (0.1303 (lb-min)/(hr-dscf));
K3 = Material balance and conversion factor, 0.0994 (kg-min)/
(hr-dscm-%) (0.0062 (lb-min)/(hr-dscf-%));
Qoxy = Volumetric flow rate of oxygen-enriched air stream to
regenerator, as determined from instruments in the catalytic cracking
unit control room, dscm/min (dscf/min); and
%Oxy = Oxygen concentration in oxygen-enriched air stream,
percent by volume (dry basis).
[GRAPHIC] [TIFF OMITTED] TR11AP02.001
Where:
E = Emission rate of PM, kg/1,000 kg (lb/1,000 lb) of coke burn-off;
Cs = Concentration of PM, g/dscm (lb/dscf);
Qsd = Volumetric flow rate of the catalytic cracking unit
catalyst regenerator flue gas as measured by Method 2 in appendix A to
part 60 of this chapter, dscm/hr (dscf/hr);
Rc = Coke burn-off rate, kg coke/hr (1,000 lb coke/hr); and
K = Conversion factor, 1.0 (kg\2\/g)/(1,000 kg) (1,000 lb/(1,000 lb)).
[GRAPHIC] [TIFF OMITTED] TR11AP02.002
Where:
Es = Emission rate of PM allowed, kg/1,000 kg (1b/1,000 lb)
of coke burn-off in catalyst regenerator;
1.0 = Emission limitation, kg coke/1,000 kg (lb coke/1,000 lb);
A = Allowable incremental rate of PM emissions, 0.18 g/million cal (0.10
lb/million Btu); and
H = Heat input rate from solid or liquid fossil fuel, million cal/hr
(million Btu/hr).
[[Page 107]]
Make sure your permitting authority approves procedures for determining
the heat input rate.
Rc = Coke burn-off rate, kg coke/hr (1,000 lb coke/hr)
determined using Equation 1 of this section; and
K' = Conversion factor to units to standard, 1.0 (kg\2\/g)/(1,000 kg)
(10\3\ lb/(1,000 lb)).
(ii) If you elect Option 2 in paragraph (a)(1)(ii) of this section,
the PM emission limit, compute your PM emission rate (lb/1,000 lbs of
coke burn-off) using Equations 1 and 2 of this section and your site-
specific opacity operating limit (if you use a continuous opacity
monitoring system) using Equation 4 of this section as follows:
[GRAPHIC] [TIFF OMITTED] TR11AP02.003
Where:
Opacity limit = Maximum permissible hourly average opacity, percent, or
10 percent, whichever is greater;
Opacityst = Hourly average opacity measured during the source
test runs, percent; and
PMEmRst = PM emission rate measured during the source test,
lb/1,000 lbs coke burn.
[GRAPHIC] [TIFF OMITTED] TR11AP02.004
(iii) If you elect Option 3 in paragraph (a)(1)(iii) of this
section, the Ni lb/hr emission limit, compute your Ni emission rate
using Equation 5 of this section and your site-specific Ni operating
limit (if you use a continuous opacity monitoring system) using
Equations 6 and 7 of this section as follows:
Where:
ENi1 = Mass emission rate of Ni, mg/hr (lb/hr); and
CNi = Ni concentration in the catalytic cracking unit
catalyst regenerator flue gas as measured by Method 29 in appendix A to
part 60 of this chapter, mg/dscm (lbs/dscf).
[GRAPHIC] [TIFF OMITTED] TR11AP02.005
Where:
Opacityl = Opacity value for use in Equation 7 of this
section, percent, or 10 percent, whichever is greater; and
NiEmR1st = Average Ni emission rate calculated as the
arithmetic average Ni emission rate using Equation 5 of this section for
each of the performance test runs, g Ni/hr.
[GRAPHIC] [TIFF OMITTED] TR11AP02.006
Where:
Ni operating limit1 = Maximum permissible hourly average Ni
operating limit, percent-acfm-ppmw, i.e., your site-specific Ni
operating limit;
Qmon,st = Hourly average actual gas flow rate as measured by
the continuous parameter monitoring system during the performance test
or using the alternative procedure in Sec. 63.1573, acfm; and
E-Catst = Ni concentration on equilibrium catalyst measured
during source test, ppmw.
(iv) If you elect Option 4 in paragraph (a)(1)(iv) of this section,
the Ni lbs/1,000 lbs of coke burn-off emission limit, compute your Ni
emission rate using Equations 1 and 8 of this section and your site-
specific Ni operating limit (if
[[Page 108]]
you use a continuous opacity monitoring system) using Equations 9 and 10
of this section as follows:
[GRAPHIC] [TIFF OMITTED] TR11AP02.007
Where:
ENi2 = Normalized mass emission rate of Ni, mg/kg coke (lb/
1,000 lbs coke).
[GRAPHIC] [TIFF OMITTED] TR11AP02.008
Where:
Opacity2 = Opacity value for use in Equation 10 of this
section, percent, or 10 percent, whichever is greater; and
NiEmR2st = Average Ni emission rate calculated as the
arithmetic average Ni emission rate using Equation 8 of this section for
each of the performance test runs, mg/kg coke.
[GRAPHIC] [TIFF OMITTED] TR11AP02.009
Where:
Ni operating limit2 = Maximum permissible hourly average Ni
operating limit, percent-ppmw-acfm-hr/kg coke, i.e., your site-specific
Ni operating limit; and
Rc,st = Coke burn rate from Equation 1 of this section, as
measured during the initial performance test, kg coke/hr.
(5) Demonstrate initial compliance with each emission limitation
that applies to you according to Table 5 of this subpart.
(6) Demonstrate initial compliance with the work practice standard
in paragraph (a)(3) of this section by submitting your operation,
maintenance, and monitoring plan to your permitting authority as part of
your Notification of Compliance Status.
(7) Submit the Notification of Compliance Status containing the
results of the initial compliance demonstration according to the
requirements in Sec. 63.1574.
(c) How do I demonstrate continuous compliance with the emission
limitations and work practice standards? You must:
(1) Demonstrate continuous compliance with each emission limitation
in Tables 1 and 2 of this subpart that applies to you according to the
methods specified in Tables 6 and 7 of this subpart.
(2) Demonstrate continuous compliance with the work practice
standard in paragraph (a)(3) of this section by maintaining records to
document conformance with the procedures in your operation, maintenance,
and monitoring plan.
(3) If you use a continuous opacity monitoring system and elect to
comply with Option 3 in paragraph (a)(1)(iii) of this section, determine
continuous compliance with your site-specific Ni operating limit by
using Equation 11 of this section as follows:
[GRAPHIC] [TIFF OMITTED] TR11AP02.010
Where:
Ni operating value1 = Maximum permissible hourly average Ni
standard operating value, %-acfm-ppmw;
[[Page 109]]
Opacity = Hourly average opacity, percent;
Qmon = Hourly average actual gas flow rate as measured by
continuous parameter monitoring system or calculated by alternative
procedure in Sec. 63.1573, acfm; and
E-Cat = Ni concentration on equilibrium catalyst from weekly or more
recent measurement, ppmw.
(4) If you use a continuous opacity monitoring system and elect to
comply with Option 4 in paragraph (a)(1)(iv) of this section, determine
continuous compliance with your site-specific Ni operating limit by
using Equation 12 of this section as follows:
[GRAPHIC] [TIFF OMITTED] TR11AP02.011
Where:
Ni operating value2 = Maximum permissible hourly average Ni
standard operating value, percent-acfm-ppmw-hr/kg coke.
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6938, Feb. 9, 2005]
Sec. 63.1565 What are my requirements for organic HAP emissions from
catalytic cracking units?
(a) What emission limitations and work practice standards must I
meet? You must:
(1) Meet each emission limitation in Table 8 of this subpart that
applies to you. If your catalytic cracking unit is subject to the NSPS
for carbon monoxide (CO) in Sec. 60.103 of this chapter, you must meet
the emission limitations for NSPS units. If your catalytic cracking unit
isn't subject to the NSPS for CO, you can choose from the two options in
paragraphs (a)(1)(i) through (ii) of this section:
(i) You can elect to comply with the NSPS requirements (Option 1);
or
(ii) You can elect to comply with the CO emission limit (Option 2).
(2) Comply with each site-specific operating limit in Table 9 of
this subpart that applies to you.
(3) Prepare an operation, maintenance, and monitoring plan according
to the requirements in Sec. 63.1574(f) and operate at all times
according to the procedures in the plan.
(4) The emission limitations and operating limits for organic HAP
emissions from catalytic cracking units required in paragraphs (a)(1)
and (2) of this section do not apply during periods of planned
maintenance preapproved by the applicable permitting authority according
to the requirements in Sec. 63.1575(j).
(b) How do I demonstrate initial compliance with the emission
limitations and work practice standards? You must:
(1) Install, operate, and maintain a continuous monitoring system
according to the requirements in Sec. 63.1572 and Table 10 of this
subpart. Except:
(i) Whether or not your catalytic cracking unit is subject to the
NSPS for CO in Sec. 60.103 of this chapter, you don't have to install
and operate a continuous emission monitoring system if you show that CO
emissions from your vent average less than 50 parts per million (ppm),
dry basis. You must get an exemption from your permitting authority,
based on your written request. To show that the emissions average is
less than 50 ppm (dry basis), you must continuously monitor CO emissions
for 30 days using a CO continuous emission monitoring system that meets
the requirements in Sec. 63.1572.
(ii) If your catalytic cracking unit isn't subject to the NSPS for
CO, you don't have to install and operate a continuous emission
monitoring system or a continuous parameter monitoring system if you
vent emissions to a boiler (including a ``CO boiler'') or process heater
that has a design heat input capacity of at least 44 megawatts (MW).
(iii) If your catalytic cracking unit isn't subject to the NSPS for
CO, you don't have to install and operate a continuous emission
monitoring system or a continuous parameter monitoring system if you
vent emissions to a boiler or process heater in which all vent streams
are introduced into the flame zone.
(2) Conduct each performance test for a catalytic cracking unit not
subject to
[[Page 110]]
the NSPS for CO according to the requirements in Sec. 63.1571 and under
the conditions specified in Table 11 of this subpart.
(3) Establish each site-specific operating limit in Table 9 of this
subpart that applies to you according to the procedures in Table 11 of
this subpart.
(4) Demonstrate initial compliance with each emission limitation
that applies to you according to Table 12 of this subpart.
(5) Demonstrate initial compliance with the work practice standard
in paragraph (a)(3) of this section by submitting the operation,
maintenance, and monitoring plan to your permitting authority as part of
your Notification of Compliance Status according to Sec. 63.1574.
(6) Submit the Notification of Compliance Status containing the
results of the initial compliance demonstration according to the
requirements in Sec. 63.1574.
(c) How do I demonstrate continuous compliance with the emission
limitations and work practice standards? You must:
(1) Demonstrate continuous compliance with each emission limitation
in Tables 8 and 9 of this subpart that applies to you according to the
methods specified in Tables 13 and 14 of this subpart.
(2) Demonstrate continuous compliance with the work practice
standard in paragraph (a)(3) of this section by complying with the
procedures in your operation, maintenance, and monitoring plan.
Sec. 63.1566 What are my requirements for organic HAP emissions from
catalytic reforming units?
(a) What emission limitations and work practice standards must I
meet? You must:
(1) Meet each emission limitation in Table 15 of this subpart that
applies to you. You can choose from the two options in paragraphs
(a)(1)(i) through (ii) of this section:
(i) You can elect to vent emissions of total organic compounds (TOC)
to a flare that meets the control device requirements in Sec. 63.11(b)
(Option 1); or
(ii) You can elect to meet a TOC or nonmethane TOC percent reduction
standard or concentration limit, whichever is less stringent (Option 2).
(2) Comply with each site-specific operating limit in Table 16 of
this subpart that applies to you.
(3) Except as provided in paragraph (a)(4) of this section, the
emission limitations in Tables 15 and 16 of this subpart apply to
emissions from catalytic reforming unit process vents associated with
initial catalyst depressuring and catalyst purging operations that occur
prior to the coke burn-off cycle. The emission limitations in Tables 15
and 16 of this subpart do not apply to the coke burn-off, catalyst
rejuvenation, reduction or activation vents, or to the control systems
used for these vents.
(4) The emission limitations in Tables 15 and 16 of this subpart do
not apply to emissions from process vents during depressuring and
purging operations when the reactor vent pressure is 5 pounds per square
inch gauge (psig) or less.
(5) Prepare an operation, maintenance, and monitoring plan according
to the requirements in Sec. 63.1574(f) and operate at all times
according to the procedures in the plan.
(b) How do I demonstrate initial compliance with the emission
limitations and work practice standard? You must:
(1) Install, operate, and maintain a continuous monitoring system(s)
according to the requirements in Sec. 63.1572 and Table 17 of this
subpart.
(2) Conduct each performance test for a catalytic reforming unit
according to the requirements in Sec. 63.1571 and under the conditions
specified in Table 18 of this subpart.
(3) Establish each site-specific operating limit in Table 16 of this
subpart that applies to you according to the procedures in Table 18 of
this subpart.
(4) Use the procedures in paragraph (b)(4)(i) or (ii) of this
section to determine initial compliance with the emission limitations.
(i) If you elect the percent reduction standard under Option 2,
calculate the emission rate of nonmethane TOC using Equation 1 of this
section (if you use Method 25) or Equation 2 of this section (if you use
Method 25A or Methods 25A and 18), then calculate the mass emission
reduction using Equation 3 of this section as follows:
[[Page 111]]
[GRAPHIC] [TIFF OMITTED] TR11AP02.012
Where:
E = Emission rate of nonmethane TOC in the vent stream, kilograms-C per
hour;
K4 = Constant, 6.0 x 10-5 (kilograms per
milligram)(minutes per hour);
Mc = Mass concentration of total gaseous nonmethane organic
(as carbon) as measured and calculated using Method 25 in appendix A to
part 60 of this chapter, mg/dscm; and
Qs = Vent stream flow rate, dscm/min, at a temperature of 20
degrees Celsius (C).
[GRAPHIC] [TIFF OMITTED] TR09FE05.001
Where:
K5 = Constant, 1.8 x 10-\4\ (parts per million)
-\1\ (gram-mole per standard cubic meter) (gram-C per gram-
mole-hexane) (kilogram per gram) (minutes per hour), where the standard
temperature (standard cubic meter) is at 20 degrees C (uses 72g-C/g.mole
hexane);
C TOC = Concentration of TOC on a dry basis in ppmv as hexane
as measured by Method 25A in appendix A to part 60 of this chapter;
C methane = Concentration of methane on a dry basis in ppmv
as measured by Method 18 in appendix A to part 60 of this chapter. If
the concentration of methane is not determined, assume C
methane equals zero; and
Q s = Vent stream flow rate, dry standard cubic meters per
minute, at a temperature of 20 degrees C.
[GRAPHIC] [TIFF OMITTED] TR11AP02.014
Where:
E i = Mass emission rate of TOC at control device inlet, kg/
hr; and
E o = Mass emission rate of TOC at control device outlet, kg/
hr.
(ii) If you elect the 20 parts per million by volume (ppmv)
concentration limit, correct the measured TOC concentration for oxygen
(O2) content in the gas stream using Equation 4 of this
section as follows:
[GRAPHIC] [TIFF OMITTED] TR09FE05.002
Where:
CNMTOC, 3O2 = Concentration of nonmethane
TOC on a dry basis in ppmv as hexane corrected to 3 percent oxygen.
(5) You are not required to do a TOC performance test if:
(i) You elect to vent emissions to a flare as provided in paragraph
(a)(1)(i) of this section (Option 1); or
(ii) You elect the TOC percent reduction or concentration limit in
paragraph (a)(1)(ii) of this section (Option 2), and you use a boiler or
process heater with a design heat input capacity of 44 MW or greater or
a boiler or process heater in which all vent streams are introduced into
the flame zone.
(6) Demonstrate initial compliance with each emission limitation
that applies to you according to Table 19 of this subpart.
(7) Demonstrate initial compliance with the work practice standard
in paragraph (a)(5) of this section by submitting the operation,
maintenance, and monitoring plan to your permitting authority as part of
your Notification of Compliance Status.
(8) Submit the Notification of Compliance Status containing the
results of the initial compliance demonstration according to the
requirements in Sec. 63.1574.
(c) How do I demonstrate continuous compliance with the emission
limitations and work practice standards? You must:
(1) Demonstrate continuous compliance with each emission limitation
in
[[Page 112]]
Tables 15 and 16 of this subpart that applies to you according to the
methods specified in Tables 20 and 21 of this subpart.
(2) Demonstrate continuous compliance with the work practice
standards in paragraph (a)(3) of this section by complying with the
procedures in your operation, maintenance, and monitoring plan.
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6938, Feb. 9, 2005]
Sec. 63.1567 What are my requirements for inorganic HAP emissions from
catalytic reforming units?
(a) What emission limitations and work practice standards must I
meet? You must:
(1) Meet each emission limitation in Table 22 to this subpart that
applies to you. If you operate a catalytic reforming unit in which
different reactors in the catalytic reforming unit are regenerated in
separate regeneration systems, then these emission limitations apply to
each separate regeneration system. These emission limitations apply to
emissions from catalytic reforming unit process vents associated with
the coke burn-off and catalyst rejuvenation operations during coke burn-
off and catalyst regeneration. You can choose from the two options in
paragraphs (a)(1)(i) through (ii) of this section:
(i) You can elect to meet a percent reduction standard for hydrogen
chloride (HCl) emissions (Option 1); or
(ii) You can elect to meet an HCl concentration limit (Option 2).
(2) Meet each site-specific operating limit in Table 23 of this
subpart that applies to you. These operating limits apply during coke
burn-off and catalyst rejuvenation.
(3) Prepare an operation, maintenance, and monitoring plan according
to the requirements in Sec. 63.1574(f) and operate at all times
according to the procedures in the plan.
(b) How do I demonstrate initial compliance with the emission
limitations and work practice standard? You must:
(1) Install, operate, and maintain a continuous monitoring system(s)
according to the requirements in Sec. 63.1572 and Table 24 of this
subpart.
(2) Conduct each performance test for a catalytic reforming unit
according to the requirements in Sec. 63.1571 and the conditions
specified in Table 25 of this subpart.
(3) Establish each site-specific operating limit in Table 23 of this
subpart that applies to you according to the procedures in Table 25 of
this subpart.
(4) Use the equations in paragraphs (b)(4)(i) through (iv) of this
section to determine initial compliance with the emission limitations.
(i) Correct the measured HCl concentration for oxygen
(O2) content in the gas stream using Equation 1 of this
section as follows:
[GRAPHIC] [TIFF OMITTED] TR09FE05.003
Where:
CHCl,3 O2 = Concentration of HCl on a dry
basis in ppmv corrected to 3 percent oxygen or 1 ppmv, whichever is
greater;
CHCl = Concentration of HCl on a dry basis in ppmv, as
measured by Method 26A in 40 CFR part 60, appendix A; and
%O2 = Oxygen concentration in percent by volume (dry basis).
(ii) If you elect the percent reduction standard, calculate the
emission rate of HCl using Equation 2 of this section; then calculate
the mass emission reduction from the mass emission rates using Equation
3 of this section as follows:
[GRAPHIC] [TIFF OMITTED] TR09FE05.004
Where:
E HCl, = Emission rate of HCl in the vent stream, grams per
hour;
K6 = Constant, 0.091 (parts per million) -1 (grams
HCl per standard cubic meter) (minutes per hour), where the standard
[[Page 113]]
temperature (standard cubic meter) is at 20 degrees Celsius (C); and
Q s = Vent stream flow rate, dscm/min, at a temperature of 20
degrees C.
[GRAPHIC] [TIFF OMITTED] TR09FE05.005
Where:
E HCl,i = Mass emission rate of HCl at control device inlet,
g/hr; and
E HCl,o = Mass emission rate of HCl at control device outlet,
g/hr.
(iii) If you are required to use a colormetric tube sampling system
to demonstrate continuous compliance with the HCl concentration
operating limit, calculate the HCl operating limit using Equation 4 of
this section as follows:
[GRAPHIC] [TIFF OMITTED] TR09FE05.006
Where:
CHCl,ppmvLimit = Maximum permissible HCl concentration for
the HCl concentration operating limit, ppmv;
CHCl,AveTube = Average HCl concentration from the colormetric
tube sampling system, calculated as the arithmetic average of the
average HCl concentration measured for each performance test run, ppmv
or 1 ppmv, whichever is greater; and
CHCl,RegLimit = Maximum permissible outlet HCl concentration
for the applicable catalytic reforming unit as listed in Table 22 of
this subpart, either 10 or 30 ppmv.
(iv) If you are required to use a colormetric tube sampling system
to demonstrate continuous compliance with the percent reduction
operating limit, calculate the HCl operating limit using Equation 5 of
this section as follows:
[GRAPHIC] [TIFF OMITTED] TR09FE05.007
Where:
CHCl,Limit = Maximum permissible HCl
concentration for the percent reduction operating limit, ppmv;
%HCl ReductionLimit = Minimum permissible HCl reduction for
the applicable catalytic reforming unit as listed in Table 22 of this
subpart, either 97 or 92 percent; and
%HCl ReductionTest = Average percent HCl reduction calculated
as the arithmetic average HCl reduction calculated using Equation 3 of
this section for each performance source test, percent.
(5) Demonstrate initial compliance with each emission limitation
that applies to you according to Table 26 of this subpart.
(6) Demonstrate initial compliance with the work practice standard
in paragraph (a)(3) of this section by submitting the operation,
maintenance, and monitoring plan to your permitting authority as part of
your Notification of Compliance Status.
(7) Submit the Notification of Compliance Status containing the
results of the initial compliance demonstration according to the
requirements in Sec. 63.1574.
[[Page 114]]
(c) How do I demonstrate continuous compliance with the emission
limitations and work practice standard? You must:
(1) Demonstrate continuous compliance with each emission limitation
in Tables 22 and 23 of this subpart that applies to you according to the
methods specified in Tables 27 and 28 of this subpart.
(2) Demonstrate continuous compliance with the work practice
standard in paragraph (a)(3) of this section by maintaining records to
document conformance with the procedures in your operation, maintenance
and monitoring plan.
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6939, Feb. 9, 2005]
Sec. 63.1568 What are my requirements for HAP emissions from sulfur
recovery units?
(a) What emission limitations and work practice standard must I
meet? You must:
(1) Meet each emission limitation in Table 29 of this subpart that
applies to you. If your sulfur recovery unit is subject to the NSPS for
sulfur oxides in Sec. 60.104 of this chapter, you must meet the
emission limitations for NSPS units. If your sulfur recovery unit isn't
subject to the NSPS for sulfur oxides, you can choose from the options
in paragraphs (a)(1)(i) through (ii) of this section:
(i) You can elect to meet the NSPS requirements (Option 1); or
(ii) You can elect to meet the total reduced sulfur (TRS) emission
limitation (Option 2).
(2) Meet each operating limit in Table 30 of this subpart that
applies to you.
(3) Prepare an operation, maintenance, and monitoring plan according
to the requirements in Sec. 63.1574(f) and operate at all times
according to the procedures in the plan.
(b) How do I demonstrate initial compliance with the emission
limitations and work practice standards? You must:
(1) Install, operate, and maintain a continuous monitoring system
according to the requirements in Sec. 63.1572 and Table 31 of this
subpart.
(2) Conduct each performance test for a sulfur recovery unit not
subject to the NSPS for sulfur oxides according to the requirements in
Sec. 63.1571 and under the conditions specified in Table 32 of this
subpart.
(3) Establish each site-specific operating limit in Table 30 of this
subpart that applies to you according to the procedures in Table 32 of
this subpart.
(4) Correct the reduced sulfur samples to zero percent excess air
using Equation 1 of this section as follows:
[GRAPHIC] [TIFF OMITTED] TR11AP02.016
Where:
Cadj = pollutant concentration adjusted to zero percent
oxygen, ppm or g/dscm;
Cmeas = pollutant concentration measured on a dry basis, ppm
or g/dscm;
20.9c = 20.9 percent oxygen--0.0 percent oxygen (defined
oxygen correction basis), percent;
20.9 = oxygen concentration in air, percent;
%O2 = oxygen concentration measured on a dry basis, percent.
(5) Demonstrate initial compliance with each emission limitation
that applies to you according to Table 33 of this subpart.
(6) Demonstrate initial compliance with the work practice standard
in paragraph (a)(3) of this section by submitting the operation,
maintenance, and monitoring plan to your permitting authority as part of
your notification of compliance status.
(7) Submit the notification of compliance status containing the
results of the initial compliance demonstration according to the
requirements in Sec. 63.1574.
(c) How do I demonstrate continuous compliance with the emission
limitations and work practice standards? You must:
(1) Demonstrate continuous compliance with each emission limitation
in Tables 29 and 30 of this subpart that applies to you according to the
methods
[[Page 115]]
specified in Tables 34 and 35 of this subpart.
(2) Demonstrate continuous compliance with the work practice
standard in paragraph (a)(3) of this section by complying with the
procedures in your operation, maintenance, and monitoring plan.
Sec. 63.1569 What are my requirements for HAP emissions from bypass
lines?
(a) What work practice standards must I meet? (1) You must meet each
work practice standard in Table 36 of this subpart that applies to you.
You can choose from the four options in paragraphs (a)(1)(i) through
(iv) of this section:
(i) You can elect to install an automated system (Option 1);
(ii) You can elect to use a manual lock system (Option 2);
(iii) You can elect to seal the line (Option 3); or
(iv) You can elect to vent to a control device (Option 4).
(2) As provided in Sec. 63.6(g), we, the EPA, may choose to grant
you permission to use an alternative to the work practice standard in
paragraph (a)(1) of this section.
(3) You must prepare an operation, maintenance, and monitoring plan
according to the requirements in Sec. 63.1574(f) and operate at all
times according to the procedures in the plan.
(b) How do I demonstrate initial compliance with the work practice
standards? You must:
(1) If you elect the option in paragraph (a)(1)(i) of this section,
conduct each performance test for a bypass line according to the
requirements in Sec. 63.1571 and under the conditions specified in
Table 37 of this subpart.
(2) Demonstrate initial compliance with each work practice standard
in Table 36 of this subpart that applies to you according to Table 38 of
this subpart.
(3) Demonstrate initial compliance with the work practice standard
in paragraph (a)(3) of this section by submitting the operation,
maintenance, and monitoring plan to your permitting authority as part of
your notification of compliance status.
(4) Submit the notification of compliance status containing the
results of the initial compliance demonstration according to the
requirements in Sec. 63.1574.
(c) How do I demonstrate continuous compliance with the work
practice standards? You must:
(1) Demonstrate continuous compliance with each work practice
standard in Table 36 of this subpart that applies to you according to
the requirements in Table 39 of this subpart.
(2) Demonstrate continuous compliance with the work practice
standard in paragraph (a)(2) of this section by complying with the
procedures in your operation, maintenance, and monitoring plan.
General Compliance Requirements
Sec. 63.1570 What are my general requirements for complying with this
subpart?
(a) You must be in compliance with all of the non-opacity standards
in this subpart during the times specified in Sec. 63.6(f)(1).
(b) You must be in compliance with the opacity and visible emission
limits in this subpart during the times specified in Sec. 63.6(h)(1).
(c) You must always operate and maintain your affected source,
including air pollution control and monitoring equipment, according to
the provisions in Sec. 63.6(e)(1)(i). During the period between the
compliance date specified for your affected source and the date upon
which continuous monitoring systems have been installed and validated
and any applicable operating limits have been set, you must maintain a
log detailing the operation and maintenance of the process and emissions
control equipment.
(d) You must develop a written startup, shutdown, and malfunction
plan (SSMP) according to the provisions in Sec. 63.6(e)(3).
(e) [Reserved]
(f) You must report each instance in which you did not meet each
emission limitation and each operating limit in this subpart that
applies to you. This includes periods of startup, shutdown, and
malfunction. You also must report each instance in which you did not
meet the work practice standards in
[[Page 116]]
this subpart that apply to you. These instances are deviations from the
emission limitations and work practice standards in this subpart. These
deviations must be reported according to the requirements in Sec.
63.1575.
(g) Consistent with Sec. Sec. 63.6(e) and 63.7(e)(1), deviations
that occur during a period of startup, shutdown, or malfunction are not
violations if you demonstrate to the Administrator's satisfaction that
you were operating in accordance with Sec. 63.6(e)(1). The SSMP must
include elements designed to minimize the frequency of such periods
(i.e., root cause analysis). The Administrator will determine whether
deviations that occur during a period of startup, shutdown, or
malfunction are violations, according to the provisions in Sec.
63.6(e).
[67 FR 17773, Apr. 11, 2002, as amended at 71 FR 20462, Apr. 20, 2006]
Sec. 63.1571 How and when do I conduct a performance test or other
initial compliance demonstration?
(a) When must I conduct a performance test? You must conduct
performance tests and report the results by no later than 150 days after
the compliance date specified for your source in Sec. 63.1563 and
according to the provisions in Sec. 63.7(a)(2). If you are required to
do a performance evaluation or test for a semi-regenerative catalytic
reforming unit catalyst regenerator vent, you may do them at the first
regeneration cycle after your compliance date and report the results in
a followup Notification of Compliance Status report due no later than
150 days after the test.
(1) For each emission limitation or work practice standard where
initial compliance is not demonstrated using a performance test, opacity
observation, or visible emission observation, you must conduct the
initial compliance demonstration within 30 calendar days after the
compliance date that is specified for your source in Sec. 63.1563.
(2) For each emission limitation where the averaging period is 30
days, the 30-day period for demonstrating initial compliance begins at
12:00 a.m. on the compliance date that is specified for your source in
Sec. 63.1563 and ends at 11:59 p.m., 30 calendar days after the
compliance date that is specified for your source in Sec. 63.1563.
(3) If you commenced construction or reconstruction between
September 11, 1998 and April 11, 2002, you must demonstrate initial
compliance with either the proposed emission limitation or the
promulgated emission limitation no later than October 8, 2002 or within
180 calendar days after startup of the source, whichever is later,
according to Sec. 63.7(a)(2)(ix).
(4) If you commenced construction or reconstruction between
September 11, 1998 and April 11, 2002, and you chose to comply with the
proposed emission limitation when demonstrating initial compliance, you
must conduct a second compliance demonstration for the promulgated
emission limitation by October 10, 2005, or after startup of the source,
whichever is later, according to Sec. 63.7(a)(2)(ix).
(b) What are the general requirements for performance test and
performance evaluations? You must:
(1) Conduct each performance test according to the requirements in
Sec. 63.7(e)(1).
(2) Except for opacity and visible emission observations, conduct
three separate test runs for each performance test as specified in Sec.
63.7(e)(3). Each test run must last at least 1 hour.
(3) Conduct each performance evaluation according to the
requirements in Sec. 63.8(e).
(4) Not conduct performance tests during periods of startup,
shutdown, or malfunction, as specified in Sec. 63.7(e)(1).
(5) Calculate the average emission rate for the performance test by
calculating the emission rate for each individual test run in the units
of the applicable emission limitation using Equation 2, 5, or 8 of Sec.
63.1564, and determining the arithmetic average of the calculated
emission rates.
(c) What procedures must I use for an engineering assessment? You
may choose to use an engineering assessment to calculate the process
vent flow rate, net heating value, TOC emission rate, and total organic
HAP emission rate expected to yield the highest daily emission rate when
determining the emission reduction or outlet concentration for the
organic HAP standard for catalytic reforming units. If
[[Page 117]]
you use an engineering assessment, you must document all data,
assumptions, and procedures to the satisfaction of the applicable
permitting authority. An engineering assessment may include the
approaches listed in paragraphs (c)(1) through (c)(4) of this section.
Other engineering assessments may be used but are subject to review and
approval by the applicable permitting authority.
(1) You may use previous test results provided the tests are
representative of current operating practices at the process unit, and
provided EPA methods or approved alternatives were used;
(2) You may use bench-scale or pilot-scale test data representative
of the process under representative operating conditions;
(3) You may use maximum flow rate, TOC emission rate, organic HAP
emission rate, or organic HAP or TOC concentration specified or implied
within a permit limit applicable to the process vent; or
(4) You may use design analysis based on engineering principles,
measurable process parameters, or physical or chemical laws or
properties. Examples of analytical methods include, but are not limited
to:
(i) Use of material balances based on process stoichiometry to
estimate maximum TOC concentrations;
(ii) Calculation of hourly average maximum flow rate based on
physical equipment design such as pump or blower capacities; and
(iii) Calculation of TOC concentrations based on saturation
conditions.
(d) Can I adjust the process or control device measured values when
establishing an operating limit? If you do a performance test to
demonstrate compliance, you must base the process or control device
operating limits for continuous parameter monitoring systems on the
results measured during the performance test. You may adjust the values
measured during the performance test according to the criteria in
paragraphs (d)(1) through (3) of this section.
(1) If you must meet the HAP metal emission limitations in Sec.
63.1564, you elect the option in paragraph (a)(1)(iii) in Sec. 63.1564
(Ni lb/hr), and you use continuous parameter monitoring systems, you
must establish an operating limit for the equilibrium catalyst Ni
concentration based on the laboratory analysis of the equilibrium
catalyst Ni concentration from the initial performance test. Section
63.1564(b)(2) allows you to adjust the laboratory measurements of the
equilibrium catalyst Ni concentration to the maximum level. You must
make this adjustment using Equation 1 of this section as follows:
[GRAPHIC] [TIFF OMITTED] TR11AP02.017
Where:
Ecat-Limit = Operating limit for equilibrium catalyst Ni concentration,
mg/kg;
NiEmR1st = Average Ni emission rate calculated as the
arithmetic average Ni emission rate using Equation 5 of this section for
each performance test run, g Ni/hr; and
Ecatst = Average equilibrium Ni concentration from laboratory
test results, mg/kg.
(2) If you must meet the HAP metal emission limitations in Sec.
63.1564, you elect the option in paragraph (a)(1)(iv) in Sec. 63.1564
(Ni lb/1,000 lb of coke burn-off), and you use continuous parameter
monitoring systems, you must establish an operating limit for the
equilibrium catalyst Ni concentration based on the laboratory analysis
of the equilibrium catalyst Ni concentration from the initial
performance test. Section 63.1564(b)(2) allows you to adjust the
laboratory measurements of the equilibrium catalyst Ni concentration to
the maximum level. You must make this adjustment using Equation 2 of
this section as follows:
[[Page 118]]
[GRAPHIC] [TIFF OMITTED] TR11AP02.018
Where:
NiEmR2st = Average Ni emission rate calculated as the
arithmetic average Ni emission rate using Equation 8 of Sec. 63.1564
for each performance test run, mg/kg coke burn-off.
(3) If you choose to adjust the equilibrium catalyst Ni
concentration to the maximum level, you can't adjust any other monitored
operating parameter (i.e., gas flow rate, voltage, pressure drop,
liquid-to-gas ratio).
(4) Except as specified in paragraph (d)(3) of this section, if you
use continuous parameter monitoring systems, you may adjust one of your
monitored operating parameters (flow rate, voltage and secondary
current, pressure drop, liquid-to-gas ratio) from the average of
measured values during the performance test to the maximum value (or
minimum value, if applicable) representative of worst-case operating
conditions, if necessary. This adjustment of measured values may be done
using control device design specifications, manufacturer
recommendations, or other applicable information. You must provide
supporting documentation and rationale in your Notification of
Compliance Status, demonstrating to the satisfaction of your permitting
authority, that your affected source complies with the applicable
emission limit at the operating limit based on adjusted values.
(e) Can I change my operating limit? You may change the established
operating limit by meeting the requirements in paragraphs (e)(1) through
(3) of this section.
(1) You may change your established operating limit for a continuous
parameter monitoring system by doing an additional performance test, a
performance test in conjunction with an engineering assessment, or an
engineering assessment to verify that, at the new operating limit, you
are in compliance with the applicable emission limitation.
(2) You must establish a revised operating limit for your continuous
parameter monitoring system if you make any change in process or
operating conditions that could affect control system performance or you
change designated conditions after the last performance or compliance
tests were done. You can establish the revised operating limit as
described in paragraph (e)(1) of this section.
(3) You may change your site-specific opacity operating limit or Ni
operating limit only by doing a new performance test.
Sec. 63.1572 What are my monitoring installation, operation, and
maintenance requirements?
(a) You must install, operate, and maintain each continuous emission
monitoring system according to the requirements in paragraphs (a)(1)
through (4) of this section.
(1) You must install, operate, and maintain each continuous emission
monitoring system according to the requirements in Table 40 of this
subpart.
(2) If you use a continuous emission monitoring system to meet the
NSPS CO or SO2 limit, you must conduct a performance
evaluation of each continuous emission monitoring system according to
the requirements in Sec. 63.8 and Table 40 of this subpart. This
requirement does not apply to an affected source subject to the NSPS
that has already demonstrated initial compliance with the applicable
performance specification.
(3) As specified in Sec. 63.8(c)(4)(ii), each continuous emission
monitoring system must complete a minimum of one cycle of operation
(sampling, analyzing, and data recording) for each successive 15-minute
period.
(4) Data must be reduced as specified in Sec. 63.8(g)(2).
(b) You must install, operate, and maintain each continuous opacity
monitoring system according to the requirements in paragraphs (b)(1)
through (3) of this section.
(1) Each continuous opacity monitoring system must be installed,
operated, and maintained according to the
[[Page 119]]
requirements in Table 40 of this subpart.
(2) If you use a continuous opacity monitoring system to meet the
NSPS opacity limit, you must conduct a performance evaluation of each
continuous opacity monitoring system according to the requirements in
Sec. 63.8 and Table 40 of this subpart. This requirement does not apply
to an affected source subject to the NSPS that has already demonstrated
initial compliance with the applicable performance specification.
(3) As specified in Sec. 63.8(c)(4)(i), each continuous opacity
monitoring system must complete a minimum of one cycle of sampling and
analyzing for each successive 10-second period and one cycle of data
recording for each successive 6-minute period.
(c) You must install, operate, and maintain each continuous
parameter monitoring system according to the requirements in paragraphs
(c)(1) through (5) of this section.
(1) The owner or operator shall install, operate, and maintain each
continuous parameter monitoring system in a manner consistent with the
manufacturer's specifications or other written procedures that provide
adequate assurance that the equipment will monitor accurately. The owner
or operator shall also meet the equipment specifications in Table 41 of
this subpart if pH strips or colormetric tube sampling systems are used.
(2) The continuous parameter monitoring system must complete a
minimum of one cycle of operation for each successive 15-minute period.
You must have a minimum of four successive cycles of operation to have a
valid hour of data (or at least two if a calibration check is performed
during that hour or if the continuous parameter monitoring system is
out-of-control).
(3) Each continuous parameter monitoring system must have valid
hourly average data from at least 75 percent of the hours during which
the process operated.
(4) Each continuous parameter monitoring system must determine and
record the hourly average of all recorded readings and if applicable,
the daily average of all recorded readings for each operating day. The
daily average must cover a 24-hour period if operation is continuous or
the number of hours of operation per day if operation is not continuous.
(5) Each continuous parameter monitoring system must record the
results of each inspection, calibration, and validation check.
(d) You must monitor and collect data according to the requirements
in paragraphs (d)(1) and (2) of this section.
(1) Except for monitoring malfunctions, associated repairs, and
required quality assurance or control activities (including as
applicable, calibration checks and required zero and span adjustments),
you must conduct all monitoring in continuous operation (or collect data
at all required intervals) at all times the affected source is
operating.
(2) You may not use data recorded during monitoring malfunctions,
associated repairs, and required quality assurance or control activities
for purposes of this regulation, including data averages and
calculations, for fulfilling a minimum data availability requirement, if
applicable. You must use all the data collected during all other periods
in assessing the operation of the control device and associated control
system.
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6940, Feb. 9, 2005]
Sec. 63.1573 What are my monitoring alternatives?
(a) What are the approved alternatives for measuring gas flow rate?
(1) You may use this alternative to a continuous parameter monitoring
system for the catalytic regenerator exhaust gas flow rate for your
catalytic cracking unit if the unit does not introduce any other gas
streams into the catalyst regeneration vent (i.e., complete combustion
units with no additional combustion devices). You may also use this
alternative to a continuous parameter monitoring system for the
catalytic regenerator atmospheric exhaust gas flow rate for your
catalytic reforming unit during the coke burn and rejuvenation cycles if
the unit operates as a constant pressure system during these cycles. If
you use this alternative, you shall use the same procedure for the
[[Page 120]]
performance test and for monitoring after the performance test. You
shall:
(i) Install and operate a continuous parameter monitoring system to
measure and record the hourly average volumetric air flow rate to the
catalytic cracking unit or catalytic reforming unit regenerator. Or, you
may determine and record the hourly average volumetric air flow rate to
the catalytic cracking unit or catalytic reforming unit regenerator
using the appropriate control room instrumentation.
(ii) Install and operate a continuous parameter monitoring system to
measure and record the temperature of the gases entering the control
device (or exiting the catalyst regenerator if you do not use an add-on
control device).
(iii) Calculate and record the hourly average actual exhaust gas
flow rate using Equation 1 of this section as follows:
[GRAPHIC] [TIFF OMITTED] TR09FE05.008
Where
Q gas = Hourly average actual gas flow rate, acfm;
1.12 = Default correction factor to convert gas flow from dry standard
cubic feet per minute (dscfm) to standard cubic feet per minute (scfm);
Q air = Volumetric flow rate of air to regenerator, as
determined from the control room instrumentations, dscfm;
Q other = Volumetric flow rate of other gases entering the
regenerator as determined from the control room instrumentations, dscfm.
(Examples of ``other'' gases include an oxygen-enriched air stream to
catalytic cracking unit regenerators and a nitrogen stream to catalytic
reforming unit regenerators.);
Tempgas = Temperature of gas stream in vent measured as near
as practical to the control device or opacity monitor, [deg]K. For wet
scrubbers, temperature of gas prior to the wet scrubber; and
Pvent = Absolute pressure in the vent measured as near as
practical to the control device or opacity monitor, as applicable, atm.
When used to assess the gas flow rate in the final atmospheric vent
stack, you can assume Pvent = 1 atm.
(2) You may use this alternative to calculating Q r, the
volumetric flow rate of exhaust gas for the catalytic cracking
regenerator as required in Equation 1 of Sec. 63.1564, if you have a
gas analyzer installed in the catalytic cracking regenerator exhaust
vent prior to the addition of air or other gas streams. You may measure
upstream or downstream of an electrostatic precipitator, but you shall
measure upstream of a carbon monoxide boiler. You shall:
(i) Install and operate a continuous parameter monitoring system to
measure and record the hourly average volumetric air flow rate to the
catalytic cracking unit regenerator. Or, you can determine and record
the hourly average volumetric air flow rate to the catalytic cracking
unit regenerator using the catalytic cracking unit control room
instrumentation.
(ii) Install and operate a continuous gas analyzer to measure and
record the concentration of carbon dioxide, carbon monoxide, and oxygen
of the catalytic cracking regenerator exhaust.
(iii) Calculate and record the hourly average flow rate using
Equation 2 of this section as follows:
[GRAPHIC] [TIFF OMITTED] TR09FE05.009
[[Page 121]]
Where:
Q r = Volumetric flow rate of exhaust gas from the catalyst
regenerator before adding air or gas streams, dscm/min (dscf/min);
79 = Default concentration of nitrogen and argon in dry air, percent by
volume (dry basis);
%Oxy = Oxygen concentration in oxygen-enriched air stream,
percent by volume (dry basis);
Q oxy = Volumetric flow rate of oxygen-enriched air stream to
regenerator as determined from the catalytic cracking unit control room
instrumentations, dscm/min (dscf/min);
%CO2 = Carbon dioxide concentration in regenerator exhaust,
percent by volume (dry basis);
CO = Carbon monoxide concentration in regenerator exhaust, percent by
volume (dry basis); and
%O2 = Oxygen concentration in regenerator exhaust, percent by
volume (dry basis).
(b) What is the approved alternative for monitoring pH or alkalinity
levels? You may use the alternative in paragraph (b)(1) or (2) of this
section for a catalytic reforming unit.
(1) You shall measure and record the pH of the water (or scrubbing
liquid) exiting the wet scrubber or internal scrubbing system at least
once an hour during coke burn-off and catalyst rejuvenation using pH
strips as an alternative to a continuous parameter monitoring system.
The pH strips must meet the requirements in Table 41 of this subpart.
(2) You shall measure and record the alkalinity of the water (or
scrubbing liquid) exiting the wet scrubber or internal scrubbing system
at least once an hour during coke burn-off and catalyst rejuvenation
using titration as an alternative to a continuous parameter monitoring
system.
(c) Can I use another type of monitoring system? You may request
approval from your permitting authority to use an automated data
compression system. An automated data compression system does not record
monitored operating parameter values at a set frequency (e.g., once
every hour) but records all values that meet set criteria for variation
from previously recorded values. Your request must contain a description
of the monitoring system and data recording system, including the
criteria used to determine which monitored values are recorded and
retained, the method for calculating daily averages, and a demonstration
that the system meets all of the criteria in paragraphs (c)(1) through
(5) of this section:
(1) The system measures the operating parameter value at least once
every hour;
(2) The system records at least 24 values each day during periods of
operation;
(3) The system records the date and time when monitors are turned
off or on;
(4) The system recognizes unchanging data that may indicate the
monitor is not functioning properly, alerts the operator, and records
the incident; and
(5) The system computes daily average values of the monitored
operating parameter based on recorded data.
(d) Can I monitor other process or control device operating
parameters? You may request approval to monitor parameters other than
those required in this subpart. You must request approval if:
(1) You use a control device other than a thermal incinerator,
boiler, process heater, flare, electrostatic precipitator, or wet
scrubber;
(2) You use a combustion control device (e.g., incinerator, flare,
boiler or process heater with a design heat capacity of at least 44 MW,
boiler or process heater where the vent stream is introduced into the
flame zone), electrostatic precipitator, or scrubber but want to monitor
a parameter other than those specified; or
(3) You wish to use another type of continuous emission monitoring
system that provides direct measurement of a pollutant (i.e., a PM or
multi-metals HAP continuous emission monitoring system, a carbonyl
sulfide/carbon disulfide continuous emission monitoring system, a TOC
continuous emission monitoring system, or HCl continuous emission
monitoring system).
(e) How do I request to monitor alternative parameters? You must
submit a request for review and approval or disapproval to the
Administrator. The request must include the information in paragraphs
(e)(1) through (5) of this section.
[[Page 122]]
(1) A description of each affected source and the parameter(s) to be
monitored to determine whether the affected source will continuously
comply with the emission limitations and an explanation of the criteria
used to select the parameter(s).
(2) A description of the methods and procedures that will be used to
demonstrate that the parameter can be used to determine whether the
affected source will continuously comply with the emission limitations
and the schedule for this demonstration. You must certify that you will
establish an operating limit for the monitored parameter(s) that
represents the conditions in existence when the control device is being
properly operated and maintained to meet the emission limitation.
(3) The frequency and content of monitoring, recording, and
reporting, if monitoring and recording are not continuous. You also must
include the rationale for the proposed monitoring, recording, and
reporting requirements.
(4) Supporting calculations.
(5) Averaging time for the alternative operating parameter.
(f) How do I apply for alternative monitoring requirements if my
catalytic cracking unit is equipped with a wet scrubber and I have
approved alternative monitoring requirements under the new source
performance standards for petroleum refineries? (1) You may request
alternative monitoring requirements according to the procedures in this
paragraph if you meet each of the conditions in paragraphs (f)(1)(i)
through (iii) of this section:
(i) Your fluid catalytic cracking unit regenerator vent is subject
to the PM limit in 40 CFR 60.102(a)(1) and uses a wet scrubber for PM
emissions control;
(ii) You have alternative monitoring requirements for the continuous
opacity monitoring system requirement in 40 CFR 60.105(a)(1) approved by
the Administrator; and
(iii) You are required by this subpart to install, operate, and
maintain a continuous opacity monitoring system for the same catalytic
cracking unit regenerator vent for which you have approved alternative
monitoring requirements.
(2) You can request approval to use an alternative monitoring method
prior to submitting your notification of compliance status, in your
notification of compliance status, or at any time.
(3) You must submit a copy of the approved alternative monitoring
requirements along with a monitoring plan that includes a description of
the continuous monitoring system or method, including appropriate
operating parameters that will be monitored, test results demonstrating
compliance with the opacity limit used to establish an enforceable
operating limit(s), and the frequency of measuring and recording to
establish continuous compliance. If applicable, you must also include
operation and maintenance requirements for the continuous monitoring
system.
(4) We will contact you within 30 days of receipt of your
application to inform you of approval or of our intent to disapprove
your request.
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6940, Feb. 9, 2005]
Notifications, Reports, and Records
Sec. 63.1574 What notifications must I submit and when?
(a) Except as allowed in paragraphs (a)(1) through (3) of this
section, you must submit all of the notifications in Sec. Sec. 63.6(h),
63.7(b) and (c), 63.8(e), 63.8(f)(4), 63.8(f)(6), and 63.9(b) through
(h) that apply to you by the dates specified.
(1) You must submit the notification of your intention to construct
or reconstruct according to Sec. 63.9(b)(5) unless construction or
reconstruction had commenced and initial startup had not occurred before
April 11, 2002. In this case, you must submit the notification as soon
as practicable before startup but no later than July 10, 2002. This
deadline also applies to the application for approval of construction or
reconstruction and approval of construction or reconstruction based on
State preconstruction review required in Sec. Sec. 63.5(d)(1)(i) and
63.5(f)(2).
(2) You must submit the notification of intent to conduct a
performance test required in Sec. 63.7(b) at least 30 calendar days
before the performance test is scheduled to begin (instead of 60 days).
[[Page 123]]
(3) If you are required to conduct a performance test, performance
evaluation, design evaluation, opacity observation, visible emission
observation, or other initial compliance demonstration, you must submit
a notification of compliance status according to Sec. 63.9(h)(2)(ii).
You can submit this information in an operating permit application, in
an amendment to an operating permit application, in a separate
submission, or in any combination. In a State with an approved operating
permit program where delegation of authority under section 112(l) of the
CAA has not been requested or approved, you must provide a duplicate
notification to the applicable Regional Administrator. If the required
information has been submitted previously, you do not have to provide a
separate notification of compliance status. Just refer to the earlier
submissions instead of duplicating and resubmitting the previously
submitted information.
(i) For each initial compliance demonstration that does not include
a performance test, you must submit the Notification of Compliance
Status no later than 30 calendar days following completion of the
initial compliance demonstration.
(ii) For each initial compliance demonstration that includes a
performance test, you must submit the notification of compliance status,
including the performance test results, no later than 150 calendar days
after the compliance date specified for your affected source in Sec.
63.1563.
(b) As specified in Sec. 63.9(b)(2), if you startup your new
affected source before April 11, 2002, you must submit the initial
notification no later than August 9, 2002.
(c) If you startup your new or reconstructed affected source on or
after April 11, 2002, you must submit the initial notification no later
than 120 days after you become subject to this subpart.
(d) You also must include the information in Table 42 of this
subpart in your notification of compliance status.
(e) If you request an extension of compliance for an existing
catalytic cracking unit as allowed in Sec. 63.1563(c), you must submit
a notification to your permitting authority containing the required
information by October 13, 2003.
(f) As required by this subpart, you must prepare and implement an
operation, maintenance, and monitoring plan for each control system and
continuous monitoring system for each affected source. The purpose of
this plan is to detail the operation, maintenance, and monitoring
procedures you will follow.
(1) You must submit the plan to your permitting authority for review
and approval along with your notification of compliance status. While
you do not have to include the entire plan in your part 70 or 71 permit,
you must include the duty to prepare and implement the plan as an
applicable requirement in your part 70 or 71 operating permit. You must
submit any changes to your permitting authority for review and approval
and comply with the plan until the change is approved.
(2) Each plan must include, at a minimum, the information specified
in paragraphs (f)(2)(i) through (xii) of this section.
(i) Process and control device parameters to be monitored for each
affected source, along with established operating limits.
(ii) Procedures for monitoring emissions and process and control
device operating parameters for each affected source.
(iii) Procedures that you will use to determine the coke burn-rate,
the volumetric flow rate (if you use process data rather than direct
measurement), and the rate of combustion of liquid or solid fossil fuels
if you use an incinerator-waste heat boiler to burn the exhaust gases
from a catalyst regenerator.
(iv) Procedures and analytical methods you will use to determine the
equilibrium catalyst Ni concentration, the equilibrium catalyst Ni
concentration monthly rolling average, and the hourly or hourly average
Ni operating value.
(v) Procedures you will use to determine the pH of the water (or
scrubbing liquid) exiting a wet scrubber if you use pH strips.
(vi) Procedures you will use to determine the HCl concentration of
gases from a catalytic reforming unit when
[[Page 124]]
you use a colormetric tube sampling system, including procedures for
correcting for pressure (if applicable to the sampling equipment) and
the sampling locations that will be used for compliance monitoring
purposes.
(vii) Procedures you will use to determine the gas flow rate for a
catalytic cracking unit if you use the alternative procedure based on
air flow rate and temperature.
(viii) Monitoring schedule, including when you will monitor and when
you will not monitor an affected source (e.g., during the coke burn-off,
regeneration process).
(ix) Quality control plan for each continuous opacity monitoring
system and continuous emission monitoring system you use to meet an
emission limit in this subpart. This plan must include procedures you
will use for calibrations, accuracy audits, and adjustments to the
system needed to meet applicable requirements for the system.
(x) Maintenance schedule for each monitoring system and control
device for each affected source that is generally consistent with the
manufacturer's instructions for routine and long-term maintenance.
(xi) If you use a fixed-bed gas-solid adsorption system to control
emissions from a catalytic reforming unit, you must implement corrective
action procedures if the HCl concentration measured at the selected
compliance monitoring sampling location within the bed exceeds the
operating limit. These procedures must require, at minimum, repeat
measurement and recording of the HCl concentration in the adsorption
system exhaust gases and at the selected compliance monitoring sampling
location within the bed. If the HCl concentration at the selected
compliance monitoring location within the bed is above the operating
limit during the repeat measurement while the HCl concentration in the
adsorption system exhaust gases remains below the operating limit, the
adsorption bed must be replaced as soon as practicable. Your procedures
must specify the sampling frequency that will be used to monitor the HCl
concentration in the adsorption system exhaust gases subsequent to the
repeat measurement and prior to replacement of the sorbent material (but
not less frequent than once every 4 hours during coke burn-off). If the
HCl concentration of the adsorption system exhaust gases is above the
operating limit when measured at any time, the adsorption bed must be
replaced within 24 hours or before the next regeneration cycle,
whichever is longer.
(xii) Procedures that will be used for purging the catalyst if you
do not use a control device to comply with the organic HAP emission
limits for catalytic reforming units. These procedures will include, but
are not limited to, specification of the minimum catalyst temperature
and the minimum cumulative volume of gas per mass of catalyst used for
purging prior to uncontrolled releases (i.e., during controlled purging
events); the maximum purge gas temperature for uncontrolled purge
events; and specification of the monitoring systems that will be used to
monitor and record data during each purge event.
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6941, Feb. 9, 2005]
Sec. 63.1575 What reports must I submit and when?
(a) You must submit each report in Table 43 of this subpart that
applies to you.
(b) Unless the Administrator has approved a different schedule, you
must submit each report by the date in Table 43 of this subpart and
according to the requirements in paragraphs (b)(1) through (5) of this
section.
(1) The first compliance report must cover the period beginning on
the compliance date that is specified for your affected source in Sec.
63.1563 and ending on June 30 or December 31, whichever date is the
first date following the end of the first calendar half after the
compliance date that is specified for your affected source in Sec.
63.1563.
(2) The first compliance report must be postmarked or delivered no
later than July 31 or January 31, whichever date follows the end of the
first calendar half after the compliance date that is specified for your
affected source in Sec. 63.1563.
[[Page 125]]
(3) Each subsequent compliance report must cover the semiannual
reporting period from January 1 through June 30 or the semiannual
reporting period from July 1 through December 31.
(4) Each subsequent compliance report must be postmarked or
delivered no later than July 31 or January 31, whichever date is the
first date following the end of the semiannual reporting period.
(5) For each affected source that is subject to permitting
regulations pursuant to part 70 or 71 of this chapter, and if the
permitting authority has established dates for submitting semiannual
reports pursuant to Sec. 70.6(a)(3)(iii)(A) or Sec. 71.6(a)(3)(iii)(A)
of this chapter, you may submit the first and subsequent compliance
reports according to the dates the permitting authority has established
instead of according to the dates in paragraphs (b)(1) through (4) of
this section.
(c) The compliance report must contain the information required in
paragraphs (c)(1) through (4) of this section.
(1) Company name and address.
(2) Statement by a responsible official, with that official's name,
title, and signature, certifying the accuracy of the content of the
report.
(3) Date of report and beginning and ending dates of the reporting
period.
(4) If there are no deviations from any emission limitation that
applies to you and there are no deviations from the requirements for
work practice standards, a statement that there were no deviations from
the emission limitations or work practice standards during the reporting
period and that no continuous emission monitoring system or continuous
opacity monitoring system was inoperative, inactive, malfunctioning,
out-of-control, repaired, or adjusted.
(d) For each deviation from an emission limitation and for each
deviation from the requirements for work practice standards that occurs
at an affected source where you are not using a continuous opacity
monitoring system or a continuous emission monitoring system to comply
with the emission limitation or work practice standard in this subpart,
the compliance report must contain the information in paragraphs (c)(1)
through (3) of this section and the information in paragraphs (d)(1)
through (3) of this section.
(1) The total operating time of each affected source during the
reporting period.
(2) Information on the number, duration, and cause of deviations
(including unknown cause, if applicable), as applicable, and the
corrective action taken.
(3) Information on the number, duration, and cause for monitor
downtime incidents (including unknown cause, if applicable, other than
downtime associated with zero and span and other daily calibration
checks).
(e) For each deviation from an emission limitation occurring at an
affected source where you are using a continuous opacity monitoring
system or a continuous emission monitoring system to comply with the
emission limitation, you must include the information in paragraphs
(d)(1) through (3) of this section and the information in paragraphs
(e)(1) through (13) of this section.
(1) The date and time that each malfunction started and stopped.
(2) The date and time that each continuous opacity monitoring system
or continuous emission monitoring system was inoperative, except for
zero (low-level) and high-level checks.
(3) The date and time that each continuous opacity monitoring system
or continuous emission monitoring system was out-of-control, including
the information in Sec. 63.8(c)(8).
(4) The date and time that each deviation started and stopped, and
whether each deviation occurred during a period of startup, shutdown, or
malfunction or during another period.
(5) A summary of the total duration of the deviation during the
reporting period (recorded in minutes for opacity and hours for gases
and in the averaging period specified in the regulation for other types
of emission limitations), and the total duration as a percent of the
total source operating time during that reporting period.
(6) A breakdown of the total duration of the deviations during the
reporting period and into those that are due to startup, shutdown,
control equipment problems, process problems, other
[[Page 126]]
known causes, and other unknown causes.
(7) A summary of the total duration of downtime for the continuous
opacity monitoring system or continuous emission monitoring system
during the reporting period (recorded in minutes for opacity and hours
for gases and in the averaging time specified in the regulation for
other types of standards), and the total duration of downtime for the
continuous opacity monitoring system or continuous emission monitoring
system as a percent of the total source operating time during that
reporting period.
(8) A breakdown of the total duration of downtime for the continuous
opacity monitoring system or continuous emission monitoring system
during the reporting period into periods that are due to monitoring
equipment malfunctions, non-monitoring equipment malfunctions, quality
assurance/quality control calibrations, other known causes, and other
unknown causes.
(9) An identification of each HAP that was monitored at the affected
source.
(10) A brief description of the process units.
(11) The monitoring equipment manufacturer(s) and model number(s).
(12) The date of the latest certification or audit for the
continuous opacity monitoring system or continuous emission monitoring
system.
(13) A description of any change in the continuous emission
monitoring system or continuous opacity monitoring system, processes, or
controls since the last reporting period.
(f) You also must include the information required in paragraphs
(f)(1) through (2) of this section in each compliance report, if
applicable.
(1) A copy of any performance test done during the reporting period
on any affected unit. The report may be included in the next semiannual
report. The copy must include a complete report for each test method
used for a particular kind of emission point tested. For additional
tests performed for a similar emission point using the same method, you
must submit the results and any other information required, but a
complete test report is not required. A complete test report contains a
brief process description; a simplified flow diagram showing affected
processes, control equipment, and sampling point locations; sampling
site data; description of sampling and analysis procedures and any
modifications to standard procedures; quality assurance procedures;
record of operating conditions during the test; record of preparation of
standards; record of calibrations; raw data sheets for field sampling;
raw data sheets for field and laboratory analyses; documentation of
calculations; and any other information required by the test method.
(2) Any requested change in the applicability of an emission
standard (e.g., you want to change from the PM standard to the Ni
standard for catalytic cracking units or from the HCl concentration
standard to percent reduction for catalytic reforming units) in your
periodic report. You must include all information and data necessary to
demonstrate compliance with the new emission standard selected and any
other associated requirements.
(g) You may submit reports required by other regulations in place of
or as part of the compliance report if they contain the required
information.
(h) The reporting requirements in paragraphs (h)(1) and (2) of this
section apply to startups, shutdowns, and malfunctions:
(1) When actions taken to respond are consistent with the plan, you
are not required to report these events in the semiannual compliance
report and the reporting requirements in Sec. Sec. 63.6(e)(3)(iii) and
63.10(d)(5) do not apply.
(2) When actions taken to respond are not consistent with the plan,
you must report these events and the response taken in the semiannual
compliance report. In this case, the reporting requirements in
Sec. Sec. 63.6(e)(3)(iv) and 63.10(d)(5) do not apply.
(i) If the applicable permitting authority has approved a period of
planned maintenance for your catalytic cracking unit according to the
requirements in paragraph (j) of this section, you must include the
following information in your compliance report.
(1) In the compliance report due for the 6-month period before the
routine planned maintenance is to begin, you
[[Page 127]]
must include a full copy of your written request to the applicable
permitting authority and written approval received from the applicable
permitting authority.
(2) In the compliance report due after the routine planned
maintenance is complete, you must include a description of the planned
routine maintenance that was performed for the control device during the
previous 6-month period, and the total number of hours during those 6
months that the control device did not meet the emission limitations and
monitoring requirements as a result of the approved routine planned
maintenance.
(j) If you own or operate multiple catalytic cracking units that are
served by a single wet scrubber emission control device (e.g., a Venturi
scrubber), you may request the applicable permitting authority to
approve a period of planned routine maintenance for the control device
needed to meet requirements in your operation, maintenance, and
monitoring plan. You must present data to the applicable permitting
authority demonstrating that the period of planned maintenance results
in overall emissions reductions. During this pre-approved time period,
the emission control device may be taken out of service while
maintenance is performed on the control device and/or one of the process
units while the remaining process unit(s) continue to operate. During
the period the emission control device is unable to operate, the
emission limits, operating limits, and monitoring requirements
applicable to the unit that is operating and the wet scrubber emission
control device do not apply. The applicable permitting authority may
require that you take specified actions to minimize emissions during the
period of planned maintenance.
(1) You must submit a written request to the applicable permitting
authority at least 6 months before the planned maintenance is scheduled
to begin with a copy to the EPA Regional Administrator.
(2) Your written request must contain the information in paragraphs
(j)(2)(i) through (v) of this section.
(i) A description of the planned routine maintenance to be performed
during the next 6 months and why it is necessary.
(ii) The date the planned maintenance will begin and end.
(iii) A quantified estimate of the HAP and criteria pollutant
emissions that will be emitted during the period of planned maintenance.
(iv) An analysis showing the emissions reductions resulting from the
planned maintenance as opposed to delaying the maintenance until the
next unit turnaround.
(v) Actions you will take to minimize emissions during the period of
planned maintenance.
Sec. 63.1576 What records must I keep, in what form, and for how long?
(a) You must keep the records specified in paragraphs (a)(1) through
(3) of this section.
(1) A copy of each notification and report that you submitted to
comply with this subpart, including all documentation supporting any
initial notification or Notification of Compliance Status that you
submitted, according to the requirements in Sec. 63.10(b)(2)(xiv).
(2) The records in Sec. 63.6(e)(3)(iii) through (v) related to
startup, shutdown, and malfunction.
(3) Records of performance tests, performance evaluations, and
opacity and visible emission observations as required in Sec.
63.10(b)(2)(viii).
(b) For each continuous emission monitoring system and continuous
opacity monitoring system, you must keep the records required in
paragraphs (b)(1) through (5) of this section.
(1) Records described in Sec. 63.10(b)(2)(vi) through (xi).
(2) Monitoring data for continuous opacity monitoring systems during
a performance evaluation as required in Sec. 63.6(h)(7)(i) and (ii).
(3) Previous (i.e., superceded) versions of the performance
evaluation plan as required in Sec. 63.8(d)(3).
(4) Requests for alternatives to the relative accuracy test for
continuous emission monitoring systems as required in Sec.
63.8(f)(6)(i).
(5) Records of the date and time that each deviation started and
stopped, and whether the deviation occurred during a period of startup,
shutdown, or malfunction or during another period.
[[Page 128]]
(c) You must keep the records in Sec. 63.6(h) for visible emission
observations.
(d) You must keep records required by Tables 6, 7, 13, and 14 of
this subpart (for catalytic cracking units); Tables 20, 21, 27 and 28 of
this subpart (for catalytic reforming units); Tables 34 and 35 of this
subpart (for sulfur recovery units); and Table 39 of this subpart (for
bypass lines) to show continuous compliance with each emission
limitation that applies to you.
(e) You must keep a current copy of your operation, maintenance, and
monitoring plan onsite and available for inspection. You also must keep
records to show continuous compliance with the procedures in your
operation, maintenance, and monitoring plan.
(f) You also must keep the records of any changes that affect
emission control system performance including, but not limited to, the
location at which the vent stream is introduced into the flame zone for
a boiler or process heater.
(g) Your records must be in a form suitable and readily available
for expeditious review according to Sec. 63.10(b)(1).
(h) As specified in Sec. 63.10(b)(1), you must keep each record for
5 years following the date of each occurrence, measurement, maintenance,
corrective action, report, or record.
(i) You must keep each record on site for at least 2 years after the
date of each occurrence, measurement, maintenance, corrective action,
report, or record, according to Sec. 63.10(b)(1). You can keep the
records offsite for the remaining 3 years.
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942, Feb. 9, 2005]
Other Requirements and Information
Sec. 63.1577 What parts of the General Provisions apply to me?
Table 44 of this subpart shows which parts of the General Provisions
in Sec. Sec. 63.1 through 63.15 apply to you.
Sec. 63.1578 Who implements and enforces this subpart?
(a) This subpart can be implemented and enforced by us, the U.S.
EPA, or a delegated authority such as your State, local, or tribal
agency. If the U.S. EPA Administrator has delegated authority to your
State, local, or tribal agency, then that Agency has the authority to
implement and enforce this subpart. You should contact your U.S. EPA
Regional Office to find out if this subpart is delegated to your State,
local, or tribal agency.
(b) In delegating implementation and enforcement authority of this
subpart to a State, local, or tribal agency under 40 CFR part 63,
subpart E, the authorities contained in paragraph (c) of this section
are retained by the Administrator of the U.S. EPA and are not
transferred to the State, local, or tribal agency.
(c) The authorities that will not be delegated to State, local, or
tribal agencies are listed in paragraphs (c)(1) through (5) of this
section.
(1) Approval of alternatives to the non-opacity emission limitations
and work practice standards in Sec. Sec. 63.1564 through 63.1569 under
Sec. 63.6(g).
(2) Approval of alternative opacity emission limitations in
Sec. Sec. 63.1564 through 63.1569 under Sec. 63.6(h)(9).
(3) Approval of major alternatives to test methods under Sec.
63.7(e)(2)(ii) and (f) and as defined in Sec. 63.90.
(4) Approval of major alternatives to monitoring under Sec. 63.8(f)
and as defined in Sec. 63.90.
(5) Approval of major alternatives to recordkeeping and reporting
under Sec. 63.10(f) and as defined in Sec. 63.90.
Sec. 63.1579 What definitions apply to this subpart?
Terms used in this subpart are defined in the Clean Air Act (CAA),
in 40 CFR 63.2, the General Provisions of this part (Sec. Sec. 63.1
through 63.15), and in this section as listed.
Boiler means any enclosed combustion device that extracts useful
energy in the form of steam and is not an incinerator.
Catalytic cracking unit means a refinery process unit in which
petroleum derivatives are continuously charged; hydrocarbon molecules in
the presence of a catalyst suspended in a fluidized bed are fractured
into smaller molecules, or react with a contact material suspended in a
fluidized bed to improve
[[Page 129]]
feedstock quality for additional processing; and the catalyst or contact
material is continuously regenerated by burning off coke and other
deposits. The unit includes, but is not limited to, the riser, reactor,
regenerator, air blowers, spent catalyst or contact material stripper,
catalyst or contact material recovery equipment, and regenerator
equipment for controlling air pollutant emissions and equipment used for
heat recovery.
Catalytic cracking unit catalyst regenerator means one or more
regenerators (multiple regenerators) which comprise that portion of the
catalytic cracking unit in which coke burn-off and catalyst or contact
material regeneration occurs and includes the regenerator combustion air
blower(s).
Catalytic reforming unit means a refinery process unit that reforms
or changes the chemical structure of naphtha into higher octane
aromatics through the use of a metal catalyst and chemical reactions
that include dehydrogenation, isomerization, and hydrogenolysis. The
catalytic reforming unit includes the reactor, regenerator (if
separate), separators, catalyst isolation and transport vessels (e.g.,
lock and lift hoppers), recirculation equipment, scrubbers, and other
ancillary equipment.
Catalytic reforming unit regenerator means one or more regenerators
which comprise that portion of the catalytic reforming unit and
ancillary equipment in which the following regeneration steps typically
are performed: depressurization, purge, coke burn-off, catalyst
rejuvenation with a chloride (or other halogenated) compound(s), and a
final purge. The catalytic reforming unit catalyst regeneration process
can be done either as a semi-regenerative, cyclic, or continuous
regeneration process.
Coke burn-off means the coke removed from the surface of the
catalytic cracking unit catalyst or the catalytic reforming unit
catalyst by combustion in the catalyst regenerator. The rate of coke
burn-off is calculated using Equation 2 in Sec. 63.1564.
Combustion device means an individual unit of equipment such as a
flare, incinerator, process heater, or boiler used for the destruction
of organic HAP or VOC.
Combustion zone means the space in an enclosed combustion device
(e.g., vapor incinerator, boiler, furnace, or process heater) occupied
by the organic HAP and any supplemental fuel while burning. The
combustion zone includes any flame that is visible or luminous as well
as that space outside the flame envelope in which the organic HAP
continues to be oxidized to form the combustion products.
Contact material means any substance formulated to remove metals,
sulfur, nitrogen, or any other contaminants from petroleum derivatives.
Continuous regeneration reforming means a catalytic reforming
process characterized by continuous flow of catalyst material through a
reactor where it mixes with feedstock, and a portion of the catalyst is
continuously removed and sent to a special regenerator where it is
regenerated and continuously recycled back to the reactor.
Control device means any equipment used for recovering, removing, or
oxidizing HAP in either gaseous or solid form. Such equipment includes,
but is not limited to, condensers, scrubbers, electrostatic
precipitators, incinerators, flares, boilers, and process heaters.
Cyclic regeneration reforming means a catalytic reforming process
characterized by continual batch regeneration of catalyst in situ in any
one of several reactors (e.g., 4 or 5 separate reactors) that can be
isolated from and returned to the reforming operation while maintaining
continuous reforming process operations (i.e., feedstock continues
flowing through the remaining reactors without change in feed rate or
product octane).
Deviation means any instance in which an affected source subject to
this subpart, or an owner or operator of such a source:
(1) Fails to meet any requirement or obligation established by this
subpart, including but not limited to any emission limit, operating
limit, or work practice standard;
(2) Fails to meet any term or condition that is adopted to implement
an applicable requirement in this subpart and that is included in the
operating
[[Page 130]]
permit for any affected source required to obtain such a permit; or
(3) Fails to meet any emission limit, operating limit, or work
practice standard in this subpart during startup, shutdown, or
malfunction, regardless of whether or not such failure is permitted by
this subpart.
Emission limitation means any emission limit, opacity limit,
operating limit, or visible emission limit.
Flame zone means the portion of a combustion chamber of a boiler or
process heater occupied by the flame envelope created by the primary
fuel.
Flow indicator means a device that indicates whether gas is flowing,
or whether the valve position would allow gas to flow, in or through a
line.
Fuel gas system means the offsite and onsite piping and control
system that gathers gaseous streams generated by the source, may blend
them with sources of gas, if available, and transports the blended
gaseous fuel at suitable pressures for use as fuel in heaters, furnaces,
boilers, incinerators, gas turbines, and other combustion devices
located within or outside of the refinery. The fuel is piped directly to
each individual combustion device, and the system typically operates at
pressures over atmospheric. The gaseous streams can contain a mixture of
methane, light hydrocarbons, hydrogen, and other miscellaneous species.
HCl means for the purposes of this subpart, gaseous emissions of
hydrogen chloride that serve as a surrogate measure for total emissions
of hydrogen chloride and chlorine as measured by Method 26 or 26A in
appendix A to part 60 of this chapter or an approved alternative method.
Incinerator means an enclosed combustion device that is used for
destroying organic compounds, with or without heat recovery. Auxiliary
fuel may be used to heat waste gas to combustion temperatures. An
incinerator may use a catalytic combustion process where a substance is
introduced into an exhaust stream to burn or oxidize contaminants while
the substances itself remains intact, or a thermal process which uses
elevated temperatures as a primary means to burn or oxidize
contaminants.
Internal scrubbing system means a wet scrubbing, wet injection, or
caustic injection control device that treats (in-situ) the catalytic
reforming unit recirculating coke burn exhaust gases for acid (HCl)
control during reforming catalyst regeneration upstream of the
atmospheric coke burn vent.
Ni means, for the purposes of this subpart, particulate emissions of
nickel that serve as a surrogate measure for total emissions of metal
HAP, including but not limited to: antimony, arsenic, beryllium,
cadmium, chromium, cobalt, lead, manganese, nickel, and selenium as
measured by Method 29 in appendix A to part 60 of this chapter or by an
approved alternative method.
Nonmethane TOC means, for the purposes of this subpart, emissions of
total organic compounds, excluding methane, that serve as a surrogate
measure of the total emissions of organic HAP compounds including, but
not limited to, acetaldehyde, benzene, hexane, phenol, toluene, and
xylenes and nonHAP VOC as measured by Method 25 in appendix A to part 60
of this chapter, by the combination of Methods 18 and 25A in appendix A
to part 60 of this chapter, or by an approved alternative method.
Oxidation control system means an emission control system which
reduces emissions from sulfur recovery units by converting these
emissions to sulfur dioxide.
PM means, for the purposes of this subpart, emissions of particulate
matter that serve as a surrogate measure of the total emissions of
particulate matter and metal HAP contained in the particulate matter,
including but not limited to: antimony, arsenic, beryllium, cadmium,
chromium, cobalt, lead, manganese, nickel, and selenium as measured by
Methods 5B or 5F in appendix A to part 60 of this chapter or by an
approved alternative method.
Process heater means an enclosed combustion device that primarily
transfers heat liberated by burning fuel directly to process streams or
to heat transfer liquids other than water.
Process vent means, for the purposes of this subpart, a gas stream
that is continuously or periodically discharged during normal operation
of a
[[Page 131]]
catalytic cracking unit, catalytic reforming unit, or sulfur recovery
unit, including gas streams that are discharged directly to the
atmosphere, gas streams that are routed to a control device prior to
discharge to the atmosphere, or gas streams that are diverted through a
product recovery device line prior to control or discharge to the
atmosphere.
Reduced sulfur compounds means hydrogen sulfide, carbonyl sulfide,
and carbon disulfide.
Reduction control system means an emission control system which
reduces emissions from sulfur recovery units by converting these
emissions to hydrogen sulfide.
Responsible official means responsible official as defined in 40 CFR
70.2.
Semi-regenerative reforming means a catalytic reforming process
characterized by shutdown of the entire reforming unit (e.g., which may
employ three to four separate reactors) at specified intervals or at the
owner's or operator's convenience for in situ catalyst regeneration.
Sulfur recovery unit means a process unit that recovers elemental
sulfur from gases that contain reduced sulfur compounds and other
pollutants, usually by a vapor-phase catalytic reaction of sulfur
dioxide and hydrogen sulfide. This definition does not include a unit
where the modified reaction is carried out in a water solution which
contains a metal ion capable of oxidizing the sulfide ion to sulfur,
e.g., the LO-CAT II process.
TOC means, for the purposes of this subpart, emissions of total
organic compounds that serve as a surrogate measure of the total
emissions of organic HAP compounds including, but not limited to,
acetaldehyde, benzene, hexane, phenol, toluene, and xylenes and nonHAP
VOC as measured by Method 25A in appendix A to part 60 of this chapter
or by an approved alternative method.
TRS means, for the purposes of this subpart, emissions of total
reduced sulfur compounds, expressed as an equivalent sulfur dioxide
concentration, that serve as a surrogate measure of the total emissions
of sulfide HAP carbonyl sulfide and carbon disulfide as measured by
Method 15 in appendix A to part 60 of this chapter or by an approved
alternative method.
Work practice standard means any design, equipment, work practice,
or operational standard, or combination thereof, that is promulgated
pursuant to section 112(h) of the CAA.
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942, Feb. 9, 2005]
Table 1 to Subpart UUU of Part 63--Metal HAP Emission Limits for
Catalytic Cracking Units
As stated in Sec. 63.1564(a)(1), you shall meet each emission
limitation in the following table that applies to you.
------------------------------------------------------------------------
You shall meet the following
For each new or existing catalytic emission limits for each catalyst
cracking unit . . . regenerator vent . . .
------------------------------------------------------------------------
1. Subject to new source PM emissions must not the exceed 1.0
performance standard (NSPS) for kilogram (kg) per 1,000 kg (1.0 lb/
PM in 40 CFR 60.102. 1,000 lb) of coke burn-off in the
catalyst regenerator; if the
discharged gases pass through an
incinerator or waste heat boiler in
which you burn auxiliary or in
supplemental liquid or solid fossil
fuel, the incremental rate of PM
emissions must not exceed 43.0
grams per Gigajoule (g/GJ) or 0.10
pounds per million British thermal
units (lb/million Btu) of heat
input attributable to the liquid or
solid fossil fuel; and the opacity
of emissions must not exceed 30
percent, except for one 6-minute
average opacity reading in any 1-
hour period.
2. Option 1: NSPS requirements not PM emissions must not exceed 1.0 kg/
subject to the NSPS for PM in 40 1,000 kg (1.0 lb/1,000 lb) of coke
CFR 60.102. burn-off in the catalyst
regenerator; if the discharged
gases pass through an incinerator
or waste heat boiler in which you
burn auxiliary or supplemental
liquid or solid fossil fuel, the
incremental rate of PM must not
exceed 43.0 g/GJ (0.10 lb/million
Btu) of heat input attributable to
the liquid or solid fossil fuel;
and the opacity of emissions must
not exceed 30 percent, except for
one 6-minute average opacity
reading in any 1-hour period.
3. Option 2: PM limit not subject PM emissions must not exceed 1.0 kg/
to the NSPS for PM in 40 CFR 1,000 kg (1.0 lb/1,000 lbs) of coke
60.102. burn-off in the catalyst
regenerator.
[[Page 132]]
4. Option 3: Ni lb/hr not subject Nickel (Ni) emissions must not
to the NSPS for PM in 40 CFR exceed 13,000 milligrams per hour
60.102. (mg/hr) (0.029 lb/hr).
5. Option 4: Ni Lb/1,000 lbs of Ni emissions must not exceed 1.0 mg/
coke burn-off not subject to the kg (0.001 lb/1,000 lbs) of coke
NSPS for PM in 40 CFR 60.102. burn-off in the catalyst
regenerator.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942, Feb. 9, 2005]
Table 2 to Subpart UUU of Part 63--Operating Limits for Metal HAP
Emissions From Catalytic Cracking Units
As stated in Sec. 63.1564(a)(2), you shall meet each operating
limit in the following table that applies to you.
----------------------------------------------------------------------------------------------------------------
For this type of
For each new or existing catalytic continuous monitoring For this type of You shall meet this
cracking unit . . . system . . . control device . . . operating limit . . .
----------------------------------------------------------------------------------------------------------------
1. Subject to the NSPS for PM in 40 Continuous opacity Not applicable......... Not applicable.
CFR 60.102. monitoring system.
2. Option 1: NSPS requirements not Continuous opacity Not applicable......... Not applicable.
subject to the NSPS for PM in 40 CFR monitoring system.
60.102.
3. Option 2: PM limit not subject to a. Continuous opacity Electrostatic Maintain the hourly
the NSPS for PM in 40 CFR 60.102. monitoring system. precipitator. average opacity of
emissions from your
catalyst regenerator
vent no higher than
the site-specific
opacity limit
established during the
performance test.
b. Continuous parameter Electrostatic Maintain the daily
monitoring systems. precipitator. average gas flow rate
no higher than the
limit established in
the performance test;
and maintain the daily
average voltage and
secondary current (or
total power input)
above the limit
established in the
performance test.
c. Continuous parameter Wet scrubber........... Maintain the daily
monitoring systems. average pressure drop
above the limit
established in the
performance test (not
applicable to a wet
scrubber of the non-
venturi jet-ejector
design); and maintain
the daily average
liquid-to-gas ratio
above the limit
established in the
performance test.
4. Option 3: Ni lb/hr not subject to a. Continuous opacity Electrostatic Maintain the daily
the NSPS for PM in 40 CFR 60.102. monitoring system. precipitator. average Ni operating
value no higher than
the limit established
during the performance
test.
b. Continuous parameter i. Electrostatic Maintain the daily
monitoring systems. precipitator. average gas flow rate
no higher than the
limit established
during the performance
test; maintain the
monthly rolling
average of the
equilibrium catalyst
Ni concentration no
higher than the limit
established during the
performance test; and
maintain the daily
average voltage and
secondary current (or
total power input)
above the established
during the performance
test.
[[Page 133]]
ii. Wet scrubber....... Maintain the monthly
rolling average of the
equilibrium catalyst
Ni concentration no
higher than the limit
established during the
performance test;
maintain the daily
average pressure drop
above the limit
established during the
performance test (not
applicable to a non-
venturi wet scrubber
of the jet-ejector
design); and maintain
the daily average
liquid-to-gas ratio
above the limit
established during the
performance test.
5. Option 4: Ni lb/1,000 lbs of coke a. Continuous opacity Electrostatic Maintain the daily
burn-off not subject to the NSPS for monitoring system precipitator. average Ni operating
PM in 40 CFR 60.102. value no higher than
the Ni operating limit
established during the
performance test.
b. Continuous parameter i. Electrostatic Maintain the monthly
monitoring systems. precipitator. rolling average of the
equilibrium catalyst
Ni concentration no
higher than the limit
established during the
performance test; and
maintain the daily
average voltage and
secondary current for
total power input)
above the limit
established during the
performance test.
ii. Wet scrubber....... Maintain the monthly
rolling average of the
equilibrium catalyst
Ni concentration no
higher than the limit
established during the
performance test;
maintain the daily
average pressure drop
above the limit
established during the
performance test (not
applicable to a non-
venturi wet scrubber
of the jet-ejector
design); and maintain
the daily average
liquid-to-gas ratio
above the limit
established during the
performance test.
----------------------------------------------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942, Feb. 9, 2005]
Table 3 to Subpart UUU of Part 63--Continous Monitoring Systems for
Metal HAP Emissions From Catalytic Cracking Units
As stated in Sec. 63.1564(b)(1), you shall meet each requirement in
the following table that applies to you.
----------------------------------------------------------------------------------------------------------------
And you use this type You shall install,
For each new or existing catalytic If your catalytic of control device for operate, and maintain a
cracking unit . . . cracking unit is . . . your vent . . . . . .
----------------------------------------------------------------------------------------------------------------
1. Subject to the NSPS for PM in 40 Any size............... Electrostatic Continuous opacity
CFR 60.102. precipitator or wet monitoring system to
scrubber or no control measure and record the
device. opacity of emissions
from each catalyst
regenerator vent.
2. Option 1: NSPS limits not subject Any size............... Electrostatic Continuous opacity
to the NSPS for PM in 40 CFR 60.102. precipitator or wet monitoring system to
scrubber or no control measure and record the
device. opacity of emissions
from each catalyst
regenerator vent.
[[Page 134]]
3. Option 2: PM limit not subject to a. Over 20,000 barrels Electrostatic Continuous opacity
the NSPS for PM in 40 CFR 60.102. per day fresh feed precipitator. monitoring system to
capacity. measure and record the
opacity of emissions
from each catalyst
regenerator vent.
b. Up to 20,000 barrels Electrostatic Continuous opacity
per day fresh feed precipitator. monitoring system to
capacity. measure and record the
opacity of emissions
from each catalyst
regenerator vent; or
continuous parameter
monitoring systems to
measure and record the
gas flow rate entering
or exiting the control
device \1\ and the
voltage and secondary
current (or total
power input) to the
control device.
c. Any size............ i. Wet scrubber........ (1) Continuous
parameter monitoring
system to measure and
record the pressure
drop across the
scrubber, gas flow
rate entering or
exiting the control
device \1\, and total
liquid (or scrubbing
liquor) flow rate to
the control device.
(2) If you use a wet
scrubber of the non-
venturi jet-ejector
design, you're not
required to install
and operate a
continuous parameter
monitoring system for
pressure drop.
d. Any size............ No electrostatic Continuous opacity
precipitator or wet monitoring system to
scrubber. measure and record the
opacity of emissions
from each catalyst
regnerator vent.
4. Option 3: Ni lb/hr not subject to a. Over 20,000 barrels Electrostatic Continuous opacity
the NSPS for PM in 40 CFR 60.102. per day fresh feed precipitator. monitoring system to
capacity. measure and record the
opacity of emissions
from each catalyst
regenerator vent and
continuous parameter
monitoring system to
measure and record the
gas flow rate entering
or exiting the control
device \1\.
b. Up to 20,000 barrels Electrostatic Continuous opacity
per day fresh feed precipitator. monitoring system to
capacity. measure and record the
opacity of emissions
from each catalyst
regenerator vent and
continuous parameter
monitoring system to
measure and record the
gas flow rate entering
or exiting the control
device \1\; or
continuous parameter
monitoring systems to
measure and record the
gas flow rate entering
or exiting the control
device \1\ and the
voltage and secondary
current (or total
power input) to the
control device.
[[Page 135]]
c. Any size............ Wet scrubber........... (1) Continuous
parameter monitoring
system to measure and
record the pressure
drop across the
scrubber, gas flow
rate entering or
exiting the control
device \1\, and total
liquid (or scrubbing
liquor) flow rate to
the control device.
(2) If you use a wet
scrubber of the non-
venturi jet-ejector
design, you're not
required to install
and operate a
continuous parameter
monitoring system for
pressure drop.
d. Any size............ No electrostatic Continuous opacity
precipitator or wet monitoring system to
scrubber. measure and record the
opacity of emissions
from each catalyst
regenerator vent and
continuous parameter
monitoring system to
measure and record the
gas flow rate \1\.
5. Option 4: Ni lb/1,000 lbs of coke a. Over 20,000 barrels Electrostatic Continuous opacity
burn-off not subject to the NSPS for per day fresh feed precipitator. monitoring system to
PM in 40 CFR 60.102. capacity. measure and record the
opacity of emissions
from each catalyst
regenerator vent and
continuous parameter
monitoring system to
measure and record the
gas flow rate entering
or exiting the control
device \1\.
b. Up to 20,000 barrels Electrostatic Continuous opacity
per day fresh feed precipitator. monitoring system to
capacity. measure and record the
opacity of emissions
from each catalyst
regenerator vent and
continuous parameter
monitoring system to
measure and record the
gas flow rate entering
or exiting the control
device \1\; or
continuous parameter
monitoring systems to
measure and record the
gas flow rate entering
or exiting the control
device \1\ and the
voltage and secondary
current (or total
power input) to the
control device.
c. Any size............ Wet scrubber........... Continuous parameter
monitoring system to
measure and record the
pressure drop across
the scrubber, gas flow
rate entering or
exiting the control
device \1\, and total
liquid (or scrubbing
liquor) flow rate to
the control device.
d. Any size............ No electrostatic Continuous opacity
precipitator or wet monitoring system to
scrubber. measure and record the
opacity of emissions
from each catalyst
regenerator vent and
continuous parameter
monitoring system to
measure and record the
gas flow rate \1\.
----------------------------------------------------------------------------------------------------------------
\1\ If applicable, you can use the alternative in Sec. 63.1573(a)(1) instead of a continuous parameter
monitoring system for gas flow rate.
[[Page 136]]
[70 FR 6942, Feb. 9, 2005]
Table 4 to Subpart UUU of Part 63--Requirements for Performance Tests
for Metal HAP Emissions From Catalytic Cracking Units Not Subject to the
New Source Performance Standard (NSPS) for Particulate Matter (PM)
As stated in Sec. 63.1564(b)(2), you shall meet each requirement in
the following table that applies to you.
----------------------------------------------------------------------------------------------------------------
For each new or existing catalytic
cracking unit catalyst regenerator You must . . . Using . . . According to these
vent . . . requirements . . .
----------------------------------------------------------------------------------------------------------------
1. If you elect Option 1 in item 2 of a. Select sampling Method 1 or 1A in Sampling sites must be
Table 1, Option 2 in item 3 of Table port's location and appendix A to part 60 located at the outlet
1, Option 3 in item 4 of Table 1, or the number of traverse of this chapter. of the control device
Option 4 in item 5 of Table 1 of ports. or the outlet of the
this subpart. regenerator, as
applicable, and prior
to any releases to the
atmosphere.
b. Determine velocity Method 2, 2A, 2C, 2D,
and volumetric flow 2F, or 2G in appendix
rate. A to part 60 of this
chapter, as
applicable.
c. Conduct gas Method 3, 3A, or 3B in
molecular weight appendix A to part 60
analysis. of this chapter, as
applicable.
d. Measure moisture Method 4 in appendix A
content of the stack to part 60 of this
gas. chapter.
e. If you use an
electro-static
precipitator, record
the total number of
fields in the control
system and how many
operated during the
applicable performance
test.
f. If you use a wet
scrubber, record the
total amount (rate) of
water (or scrubbing
liquid) and the amount
(rate) of make-up
liquid to the scrubber
during each test run.
2. Option 1: Elect NSPS.............. a. Measure PM Method 5B or 5F (40 CFR You must maintain a
emissions. part 60, appendix A) sampling rate of at
to determine PM least 0.15 dry
emissions and standard cubic meters
associated moisture per minute (dscm/min)
content for units (0.53 dry standard
without wet scrubbers. cubic feet per minute
Method 5B (40 CFR part (dscf/min).
60, appendix A) to
determine PM emissions
and associated
moisture content for
unit with wet
scrubber.
b. Compute PM emission Equations 1, 2, and 3
rate (lbs/1,000 lbs) of Sec. 63.1564 (if
of coke burn-off. applicable).
c. Measure opacity of Continuous opacity You must collect
emissions. monitoring system. opacity monitoring
data every 10 seconds
during the entire
period of the Method
5B or 5F performance
test and reduce the
data to 6-minute
averages.
3. Option 2: PM limit................ a. Measure PM See item 2. of this See item 2. of this
emissions. table. table.
b. Compute coke burn- Equations 1 and 2 of
off rate and PM Sec. 63.1564.
emission rate.
[[Page 137]]
c. Establish your site- Data from the You must collect
specific opacity continuous opacity opacity monitoring
operating limit if you monitoring system. data every 10 seconds
use a continuous during the entire
opacity monitoring period of the Method
system. 5B or 5F performance
test and reduce the
data to 6-minute
averages; determine
and record the hourly
average opacity from
all the 6-minute
averages; and compute
the site-specific
limit using Equation 4
of Sec. 63.1564.
4. Option 3: Ni lb/hr................ a. Measure Method 29 (40 CFR part
concentration of Ni 60, appendix A).
and total metal HAP.
b. Compute Ni emission Equation 5 of Sec.
rate (lb/hr). 63.1564.
c. Determine the XRF procedure in You must obtain 1
equilibrium catalyst appendix A to this sample for each of the
Ni concentration. subpart\1\; or EPA 3 runs; determine and
Method 6010B or 6020 record the equilibrium
or EPA Method 7520 or catalyst Ni
7521 in SW-846\2\; or concentration for each
an alternative to the of the 3 samples; and
SW-846 method you may adjust the
satisfactory to the laboratory results to
Administrator. the maximum value
using Equation 2 of
Sec. 63.1571.
d. If you use a i. Equations 6 and 7 of (1) You must collect
continuous opacity Sec. 63.1564 using opacity monitoring
monitoring system, data from continuous data every 10 seconds
establish your site- opacity monitoring during the entire
specific Ni operating system, gas flow rate, period of the initial
limit. results of equilibrium Ni performance test;
catalyst Ni reduce the data to 6-
concentration minute averages; and
analysis, and Ni determine and record
emission rate from the hourly average
Method 29 test. opacity from all the 6-
minute averages.
(2) You must collect
gas flow rate
monitoring data every
15 minutes during the
entire period of the
initial Ni performance
test; measure the gas
flow as near as
practical to the
continuous opacity
monitoring system; and
determine and record
the hourly average
actual gas flow rate
from all the readings.
5. Option 4: Ni lbs/1,000 lbs of coke a. Measure Method 29 (40 CFR part
burn-off. concentration of Ni 60, appendix A).
and total HAP.
b. Compute Ni emission Equations 1 and 8 of .......................
rate (lb/1,000 lbs of Sec. 63.1564.
coke burn-off).
c. Determine the See item 4.c. of this You must obtain 1
equilibrium catalyst table. sample for each of the
Ni concentration. 3 runs; determine and
record the equilibrium
catalyst Ni
concentration for each
of the 3 samples; and
you may adjust the
laboratory results to
the maximum value
using Equation 2 of
Sec. 63.1571.
d. If you use a i. Equations 9 and 10 (1) You must collect
continuous opacity of Sec. 63.1564 with opacity monitoring
monitoring system, data from continuous data every 10 seconds
establish your site- opacity monitoring during the entire
specific Ni operating system, coke burn-off period of the initial
limit. rate, results of Ni performance test;
equilibrium catalyst reduce the data to 6-
Ni concentration minute averages; and
analysis, and Ni determine and record
emission rate from the hourly average
Method 29 test. opacity from all the 6-
minute averages.
[[Page 138]]
(2) You must collect
gas flow rate
monitoring data every
15 minutes during the
entire period of the
initial Ni performance
test; measure the gas
flow rate as near as
practical to the
continuous opacity
monitoring system; and
determine and record
the hourly average
actual gas flow rate
from all the readings.
e. Record the catalyst
addition rate for each
test and schedule for
the 10- day period
prior to the test.
6. If you elect Option 2 in Entry 3 a. Establish each Data from the
in Table 1, Option 3 in Entry 4 in operating limit in continuous parameter
Table 1, or Option 4 in Entry 5 in Table 2 of this monitoring systems and
Table 1 of this subpart and you use subpart that applies applicable performance
continuous parameter monitoring to you. test methods.
systems.
b. Electrostatic Data from the You must collect gas
precipitator or wet continuous parameter flow rate monitoring
scrubber: gas flow monitoring systems and data every 15 minutes
rate. applicable performance during the entire
test methods. period of the initial
performance test; and
determine and record
the maximum hourly
average gas flow rate
from all the readings.
c. Electrostatic Data from the You must collect
precipitator: voltage continuous parameter voltage and secondary
and secondary current monitoring systems and current (or total
(or total power applicable performance power input)
input). test methods. monitoring data every
15 minutes during the
entire period of the
initial performance
test; and determine
and record the minimum
hourly average voltage
and secondary current
(or total power input)
from all the readings.
d. Electrostatic Results of analysis for You must determine and
precipitator or wet equilibrium catalyst record the average
scrubber: equilibrium Ni concentration. equilibrium catalyst
catalyst Ni Ni concentration for
concentration. the 3 runs based on
the laboratory
results. You may
adjust the value using
Equation 1 or 2 of
Sec. 63.1571 as
applicable.
e. Wet scrubber: Data from the You must collect
pressure drop (not continuous parameter pressure drop
applicable to non- monitoring systems and monitoring data every
venturi scrubber of applicable performance 15 minutes during the
jet ejector design). test methods. entire period of the
initial performance
test; and determine
and record the minimum
hourly average
pressure drop from all
the readings.
f. Wet scrubber: liquid- Data from the You must collect gas
to-gas ratio. continuous parameter flow rate and total
monitoring systems and water (or scrubbing
applicable performance liquid) flow rate
test methods. monitoring data every
15 minutes during the
entire period of the
initial performance
test; determine and
record the hourly
average gas flow rate
and total water (or
scrubbing liquid) flow
rate from all the
readings; and
determine and record
the minimum liquid-to-
gas ratio.
[[Page 139]]
g. Alternative Data from the You must collect air
procedure for gas flow continuous parameter flow rate monitoring
rate. monitoring systems and data or determine the
applicable performance air flow rate using
test methods. control room
instrumentation every
15 minutes during the
entire period of the
initial performance
test; determine and
record the hourly
average rate of all
the readings; and
determine and record
the maximum gas flow
rate using Equation 1
of Sec. 63.1573.
----------------------------------------------------------------------------------------------------------------
\1\Determination of Metal Concentration on Catalyst Particles (Instrumental Analyzer Procedure).
\2\ EPA Method 6010B, Inductively Coupled Plasma-Atomic Emission Spectrometry, EPA Method 6020, Inductively
Coupled Plasma-Mass Spectrometry, EPA Method 7520, Nickel Atomic Absorption, Direct Aspiration, and EPA Method
7521, Nickel Atomic Absorption, Direct Aspiration are included in ``Test Methods for Evaluating Solid Waste,
Physical/Chemical Methods,'' EPA Publication SW-846, Revision 5 (April 1998). The SW-846 and Updates (document
number 955-001-00000-1) are available for purchase from the Superintendent of Documents, U.S. Government
Printing Office, Washington, DC 20402, (202) 512-1800; and from the National Technical Information Services
(NTIS), 5285 Port Royal Road, Springfield, VA 22161, (703) 487-4650. Copies may be inspected at the EPA Docket
Center (Air Docket), EPA West, Room B-108, 1301 Constitution Ave., NW., Washington, DC; or at the Office of
the Federal Register, 800 North Capitol Street, NW., Suite 700, Washington, DC.
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6944, Feb. 9,
2005]
Table 5 to Subpart UUU of Part 63--Initial Compliance With Metal HAP
Emission Limits for Catalytic Cracking Units
As stated in Sec. 63.1564(b)(5), you shall meet each requirement in
the following table that applies to you.
[[Page 140]]
----------------------------------------------------------------------------------------------------------------
For each new and existing catalytic
cracking unit catalyst regenerator vent For the following emission limit . You have demonstrated initial
. . . . . compliance if . . .
----------------------------------------------------------------------------------------------------------------
1. Subject to the NSPS for PM in 40 CFR PM emissions must not exceed 1.0 kg/ You have already conducted a
60.102. 1,000 kg (1.0 lb/1,000 lb) of coke performance test to demonstrate
burn-off in the catalyst initial compliance with the NSPS
regenerator; if the discharged and the measured PM emission rate
gases pass through an incinerator is less than or equal to 1.0 kg/
or waste heat boiler in which you 1,000 kg (1.0 lb/1,000 lb) of
burn auxiliary or supplemental coke burn-off in the catalyst
liquid or solid fossil fuel, the regenerator. As part of the
incremental rate of PM must not Notification of Compliance
exceed 43.0 grams per Gigajoule (g/ Status, you must certify that
GJ) or 0.10 pounds per million your vent meets the PM limit. You
British thermal units (lb/million are not required to do another
Btu) of heat input attributable to performance test to demonstrate
the liquid or solid fossil fuel; initial compliance. If
and the opacity of emissions must applicable, you have already
not exceed 30 percent, except for conducted a performance test to
one 6-minute average opacity demonstrate initial compliance
reading in any 1-hour period. with the NSPS and the measured PM
rate is less than or equal to
43.0 g/GJ (0.10 lb/million Btu)
of heat input attributable to the
liquid or solid fossil fuel. As
part of the Notification of
Compliance Status, you must
certify that your vent meets the
PM emission limit. You are not
required to do another
performance test to demonstrate
initial compliance. You have
already conducted a performance
test to demonstrate initial
compliance with the NSPS and the
average hourly opacity is no more
than 30 percent. Except: One 6-
minute average in any 1-hour
period can exceed 30 percent. As
part of the Notification of
Compliance Status, you must
certify that your vent meets the
opacity limit. You are not
required to do another
performance test to demonstrate
initial compliance. You have
already conducted a performance
evaluation to demonstrate initial
compliance with the applicable
performance specification. As
part of your Notification of
Compliance Status, you certify
that your continuous opacity
monitoring system meets the
requirements in Sec. 63.1572.
You are not required to do a
performance evaluation to
demonstrate initial compliance.
2. Option 1: Elect NSPS not subject to PM emission must not exceed 1.0 kg/ The average PM emission rate,
the NSPS for PM. 1,000 kg (1.0 lb/1,000 lb) of coke measured using EPA Method 5B or
burn-off in the catalyst 5F (for a unit without a wet
regenerator; if the discharged scrubber) or 5B (for a unit with
gases pass through an incinerator a wet scrubber), over the period
or waste heat boiler in which you of the initial performance test,
burn auxiliary or supplemental is no higher than 1.0 kg/1,000 kg
liquid or solid fossil fuel, the (1.0 lb/1,000 lb of coke burn-off
incremental rate of PM must not in the catalyst regenerator. The
exceed 43.0 g/GJ (0.10 lb/million PM emission rate is calculated
Btu) of heat input attributable to using Equations 1 and 2 of Sec.
the liquid or solid fossil fuel; 63.1564. If applicable, the
and the opacity of emissions must average PM emission rate,
not exceed 30 percent, except for measured using EPA Method 5B
one 6-minute average opacity emission rate, measured using EPA
reading in any 1-hour period. Method 5B or 5F (for a unit
without a wet scrubber) or Method
5B (for a unit with a wet
scrubber) over the period of the
initial performance test, is no
higher than 43.0 g/GJ (0.10 lb/
million Btu) of heat input
attributable to the liquid or
solid fossil fuel. The PM
emission rate is calculated using
Equation 3 of Sec. 63.1564; no
more than one 6-minute average
measured by the continuous
opacity monitoring system exceeds
30 percent opacity in any 1-hour
period over the period of the
performance test; and your
performance evaluation shows the
continuous opacity monitoring
system meets the applicable
requirements in Sec. 63.1572.
[[Page 141]]
3. Option 2: Not subject to the NSPS PM emissions must not exceed 1.0 kg/ The average PM emission rate,
for PM. 1,000 kg (1.0 lb/1,000 lb) of coke measured using EPA Method 5B or
burn-off in the catalyst 5F (for a unit without a wet
regenerator. scrubber) or Method 5B (for a
unit with a wet scrubber), over
the period of the initial
performance test, is less than or
equal to 1.0 kg/1,000 kg (1.0 lb/
1,000 lb) of coke burn-off in the
catalyst regenerator. The PM
emission rate is calculated using
Equations 1 and 2 of Sec.
63.1564; and if you use a
continuous opacity monitoring
system, your performance
evaluation shows the system meets
the applicable requirements in
Sec. 63.1572.
4. Option 3: not subject to the NSPS Nickel (Ni) emissions from your The average Ni emission rate,
for PM. catalyst regenerator vent must not measured using Method 29 over the
exceed 13,000 mg/hr (0.029 lb/hr). period of the initial performance
test, is not more than 13,000 mg/
hr (0.029 lb/hr). The Ni emission
rate is calculated using Equation
5 of Sec. 63.1564; and if you
use a continuous opacity
monitoring system, your
performance evaluation shows the
system meets the applicable
requirements in Sec. 63.1572.
5. Option 4: Ni lb/1,000 lbs of coke Ni emissions from your catalyst The average Ni emission rate,
burn-off not subject to the NSPS for regenerator vent must not exceed measured using Method 29 over the
PM. 1.0 mg/kg (0.001 lb/1,000 lbs) of period of the initial performance
coke burn-off in the catalyst test, is not more than 1.0 mg/kg
regenerator. (0.001 lb/1,000 lbs) of coke burn-
off in the catalyst regenerator.
The Ni emission rate is
calculated using Equation 8 of
Sec. 63.1564; and if you use a
continuous opacity monitoring
system, your performance
evaluation shows the system meets
the applicable requirements in
Sec. 63.1572.
----------------------------------------------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6946, Feb. 9,
2005]
Table 6 to Subpart UUU of Part 63--Continuous Compliance With Metal HAP
Emission Limits for Catalytic Cracking Units
As stated in Sec. 63.1564(c)(1), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
Subject to this
For each new and existing emission limit for You shall
catalytic cracking unit . . your catalyst demonstrate
. regenerator vent . . continuous
. compliance by . . .
------------------------------------------------------------------------
1. Subject to the NSPS for a. PM emissions must i. Determining and
PM in 40 CFR 60.102. not exceed 1.0 kg/ recording each day
1,000 kg (1.0 lb/ the average coke
1,000 lb) of coke burn-off rate
burn-off in the (thousands of
catalyst kilograms per hour)
regenerator; if the using Equation 1 in
discharged gases Sec. 63.1564 and
pass through an the hours of
incinerator or operation for each
waste heat boiler catalyst
in which you burn regenerator;
auxiliary or maintaining PM
supplemental liquid emission rate below
or solid fossil 1.0 kg/1,000 kg
fuel, the (1.0 lb/1,000 lbs)
incremental rate of of coke burn-off;
PM must not exceed if applicable,
43.0 g/GJ (0.10 lb/ determining and
million Btu) of recording each day
heat input the rate of
attributable to the combustion of
liquid or solid liquid or solid
fossil fuel; and fossil fuels
the opacity of (liters/hour or
emissions must not kilograms/hour) and
exceed 30 percent, the hours of
except for one 6- operation during
minute average which liquid or
opacity reading in solid fossil-fuels
any 1-hour period. are combusted in
the incinerator-
waste heat boiler;
if applicable,
maintaining the PM
rate incinerator
below 43 g/GJ (0.10
lb/million Btu) of
heat input
attributable to the
solid or liquid
fossil fuel;
collecting the
continuous opacity
monitoring data for
each catalyst
regenerator vent
according to Sec.
63.1572; and
maintaining each 6-
minute average at
or below 30 percent
except that one 6-
minute average
during a 1-hour
period can exceed
30 percent.
[[Page 142]]
2. Option 1: Elect NSPS not See item 1.a. of See item 1.a.i. of
subject to the NSPS for PM this table. this table.
in 40 CFR 60.102.
3. Option 2: PM limit not PM emissions must Determining and
subject to the NSPS for PM. not exceed 1.0 kg/ recording each day
1,000 kg (1.0 lb/ the average coke
1,000 lb) of coke burn-off rate
burn-off in the (thousands of
catalyst kilograms per hour)
regenerator. and the hours of
operation for each
catalyst
regenerator by
Equation 1 of Sec.
63.1564 (you can
use process data to
determine the
volumetric flow
rate); and
maintaining the PM
emission rate below
1.0 kg/1,000 kg
(1.0 lb/1,000 lb)
of coke burn-off.
4. Option 3: Ni lb/hr not Ni emissions must Maintaining Ni
subject to the NSPS for PM. not exceed 13,000 emission rate below
mg/hr (0.029 lb/ 13,000 mg/hr (0.029
hr). lb/hr).
5. Option 4: Ni lb/1,000 lbs Ni emissions must Determining and
of coke burn-off not not exceed 1.0 mg/ recording each day
subject to the NSPS for PM. kg (0.001 lb/1,000 the average coke
lbs) of coke burn- burn-off rate
off in the catalyst (thousands of
regenerator. kilograms per hour)
and the hours of
operation for each
catalyst
regenerator by
Equation 1 of Sec.
63.1564 (you can
use process data to
determine the
volumetric flow
rate); and
maintaining Ni
emission rate below
1.0 mg/kg (0.001 lb/
1,000 lbs) of coke
burn-off in the
catalyst
regenerator.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6948, Feb. 9,
2005]
Table 7 to Subpart UUU of Part 63--Continuous Compliance With Operating
Limits for Metal HAP Emissions From Catalytic Cracking Units
As stated in Sec. 63.1564(c)(1), you shall meet each requirement in
the following table that applies to you.
Table 7 to Subpart UUU of Part 63--Continuous Compliance With Operating Limits for Metal HAP Emissions From
Catalytic Cracking Units
[As stated in Sec. 63.1564(c)(1), you shall meet each requirement in the following table that applies to you.]
----------------------------------------------------------------------------------------------------------------
You shall demonstrate
For each new or existing catalytic If you use . . . For this operating continuous compliance
cracking unit . . . limit . . . by . . .
----------------------------------------------------------------------------------------------------------------
1. Subject to NSPS for PM in 40 CFR Continuous opacity Not applicable. Complying with Table 6
60.102. monitoring system. of this subpart.
2. Option 1: Elect NSPS not subject Continuous opacity Not applicable. Complying with Table 6
to the NSPS for PM in 40 CFR 60.102. monitoring system. of this subpart.
3. Option 2: PM limit not subject to a. Continuous opacity The opacity of Collecting the hourly
the NSPS for PM in 40 CFR 60.102. monitoring system. emissions from your average continuous
catalyst regenerator opacity monitoring
vent must not exceed system data according
the site-specific to Sec. 63.1572; and
opacity operating maintaining the hourly
limit established average opacity at or
during the performance below the site-
test. specific limit.
b. Continuous parameter i. The daily average Collecting the hourly
monitoring systems-- gas flow rate entering and daily average gas
electrostatic or exiting the control flow rate monitoring
precipitator. device must not exceed data according to Sec.
the operating limit 63.1572 \1\; and
established during the maintaining the daily
performance test. average gas flow rate
at or below the limit
established during the
performance test.
[[Page 143]]
ii. The daily average Collecting the hourly
voltage and secondary and daily average
current (or total voltage and secondary
power input) to the current (or total
control device must power input)
not fall below the monitoring data
operating limit according to Sec.
established during the 63.1572; and
performance test. maintaining the daily
average voltage and
secondary current (or
total power input) at
or above the limit
established during the
performance test.
c. Continuous parameter i. The daily average Collecting the hourly
monitoring systems-- pressure drop across and daily average
wet scrubber. the scrubber must not pressure drop
fall below the monitoring data
operating limit according to Sec.
established during the 63.1572; and
performance test. maintaining the daily
average pressure drop
above the limit
established during the
performance test.
ii. The daily average Collecting the hourly
liquid-to-gas ratio average gas flow rate
must not fall below and water (or
the operating limit scrubbing liquid) flow
established during the rate monitoring data
performance test. according to Sec.
63.1572 \1\;
determining and
recording the hourly
average liquid-to-gas
ratio; determining and
recording the daily
average liquid-to-gas
ratio; and maintaining
the daily average
liquid-to-gas ratio
above the limit
established during the
performance test.
4. Option 3: Ni lb/hr not subject to a. Continuous opacity The daily average Ni Collecting the hourly
the NSPS for PM in 40 CFR 60.102. monitoring system. operating value must average continuous
not exceed the site- opacity monitoring
specific Ni operating system data according
limit established to Sec. 63.1572;
during the performance determining and
test. recording equilibrium
catalyst Ni
concentration at least
once a week \2\;
collecting the hourly
average gas flow rate
monitoring data
according to Sec.
63.1572 \1\;
determining and
recording the hourly
average Ni operating
value using Equation
11 of Sec. 63.1564;
determining and
recording the daily
average Ni operating
value; and maintaining
the daily average Ni
operating value below
the site-specific Ni
operating limit
established during the
performance test.
b. Continuous parameter i. The daily average See item 3.b.i. of this
monitoring systems-- gas flow rate entering table.
electrostatic or exiting the control
precipitator. device must not exceed
the operating limit
established during the
performance test.
[[Page 144]]
ii. The daily average See item 3.b.ii. of
voltage and secondary this table.
current (or total
power input) must not
fall below the level
established in the
performance test.
iii. The monthly Determining and
rolling average of the recording the
equilibrium catalyst equilibrium catalyst
Ni concentration must Ni concentration at
not exceed the level least once a week \2\;
established during the determining and
performance test. recording the monthly
rolling average of the
equilibrium catalyst
Ni concentration once
each week using the
weekly or most recent
value; and maintaining
the monthly rolling
average below the
limit established in
the performance test.
c. Continuous parameter i. The daily average See item 3.c.i. of this
monitoring systems-- pressure drop must not table.
wetscrubber. fall below the
operating limit
established in the
performance test.
ii. The daily average See item 3.c.ii. of
liquid-to-gas ratio this table.
must not fall below
the operating limit
established during the
performance test.
iii. The monthly Determining and
rolling average recording the
equilibrium catalyst equilibrium catalyst
Ni concentration must Ni concentration at
not exceed the level least once a week\2\;
established during the determining and
performance test. recording the monthly
rolling average of
equilibrium catalyst
Ni concentration once
each week using the
weekly or most recent
value; and maintaining
the monthly rolling
average below the
limit established in
the performance test.
5. Option 4: Ni lb/ton of coke burn- a. Continuous opacity The daily average Ni Collecting the hourly
off not subject to the NSPS for PM monitoring system. operating value must average continuous
in 40 CFR 60.102. not exceed the site- opacity monitoring
specific Ni operating system data according
limit established to Sec. 63.1572;
during the performance collecting the hourly
test. average gas flow rate
monitoring data
according to Sec.
63.1572 \1\;
determining and
recording equilibrium
catalyst Ni
concentration at least
once a week \2\;
determining and
recording the hourly
average Ni operating
value using Equation
12 of Sec. 63.1564;
determining and
recording the daily
average Ni operating
value; and maintaining
the daily average Ni
operating value below
the site-specific Ni
operating limit
established during the
performance test.
[[Page 145]]
b. Continuous parameter i. The daily average See item 3.b.i. of this
monitoring systems-- gas flow rate to the table.
electrostatic control device must
precipitator. not exceed the level
established in the
performance test.
ii. The daily average See item 3.b.ii. of
voltage and secondary this table.
current (or total
power input) must not
fall below the level
established in the
performance test.
iii. The monthly See item 4.b.iii. of
rolling average this table.
equilibrium catalyst
Ni concentration must
not exceed the level
established during the
performance test.
c. Continuous parameter i. The daily average See item 3.c.i. of this
monitoring systems-- pressure drop must not table.
wet scrubber. fall below the
operating limit
established in the
performance test.
ii. The daily average See item 3.c.ii. of
liquid-to-gas ratio this table.
must not fall below
the operating limit
established during the
performance test.
iii. The monthly See item 4.c.iii. of
rolling average this table.
equilibrium catalyst
Ni concentration must
not exceed the level
established during the
performance test.
----------------------------------------------------------------------------------------------------------------
\1\ If applicable, you can use the alternative in Sec. 63.1573(a)(1) for gas flow rate instead of a continuous
parameter monitoring system if you used the alternative method in the initial performance test.
\2\ The equilibrium catalyst Ni concentration must be measured by the procedure, Determination of Metal
Concentration on Catalyst Particles (Instrumental Analyzer Procedure) in appendix A to this subpart; or by EPA
Method 6010B, Inductively Coupled Plasma-Atomic Emission Spectrometry, EPA Method 6020, Inductively Coupled
Plasma-Mass Spectrometry, EPA Method 7520, Nickel Atomic Absorption, Direct Aspiration, or EPA Method 7521,
Nickel Atomic Absorption, Direct Aspiration; or by an alternative to EPA Method 6010B, 6020, 7520, or 7521
satisfactory to the Administrator. The EPA Methods 6010B, 6020, 7520, and 7521 are included in ``Test Methods
for Evaluating Solid Waste, Physical/Chemical Methods,'' EPA Publication SW-846, Revision 5 (April 1998). The
SW-846 and Updates (document number 955-001-00000-1) are available for purchase from the Superintendent of
Documents, U.S. Government Printing Office, Washington, DC 20402, (202) 512-1800; and from the National
Technical Information Services (NTIS), 5285 Port Royal Road, Springfield, VA 22161, (703) 487-4650. Copies may
be inspected at the EPA Docket Center (Air Docket), EPA West, Room B-108, 1301 Constitution Ave., NW.,
Washington, DC; or at the Office of the Federal Register, 800 North Capitol Street, NW., Suite 700,
Washington, DC. These methods are also available at http://www.epa.gov/epaoswer/hazwaste/test/main.htm.
[70 FR 6948, Feb. 9, 2005]
Table 8 to Subpart UUU of Part 63--Organic HAP Emission Limits for
Catalytic Cracking Units
As stated in Sec. 63.1565(a)(1), you shall meet each emission
limitation in the following table that applies to you.
------------------------------------------------------------------------
You shall meet the
following emission
For each new and existing catalytic cracking unit limit for each
. . . catalyst regenerator
vent . . .
------------------------------------------------------------------------
1. Subject to the NSPS for carbon monoxide (CO) in CO emissions from
40 CFR 60.103. the catalyst
regenerator vent or
CO boiler serving
the catalytic
cracking unit must
not exceed 500
parts per million
volume (ppmv) (dry
basis).
2. Not subject to the NSPS for CO in 40 CFR 60.103 a. CO emissions from
the catalyst
regenerator vent or
CO boiler serving
the catalytic
cracking unit must
not exceed 500 ppmv
(dry basis).
b. If you use a
flare to meet the
CO limit, the flare
must meet the
requirements for
control devices in
Sec. 63.11(b):
visible emissions
must not exceed a
total of 5 minutes
during any 2
consecutive hours.
------------------------------------------------------------------------
[[Page 146]]
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6948, Feb. 9,
2005]
Table 9 to Subpart UUU of Part 63--Operating Limits for Organic HAP
Emissions From Catalytic Cracking Units
As stated in Sec. 63.1565(a)(2), you shall meet each operating
limit in the following table that applies to you.
----------------------------------------------------------------------------------------------------------------
For this type of
For each new or existing catalytic continuous monitoring For this type of You shall meet this
cracking unit . . . system . . . control device . . . operating limit . . .
----------------------------------------------------------------------------------------------------------------
1. Subject to the NSPS for carbon Continuous emission Not applicable......... Not applicable.
monoxide (CO) in 40 CFR 60.103. monitoring system.
2. Not subject to the NSPS for CO in a. Continuous emission Not applicable......... Not applicable.
40 CFR 60.103. monitoring system.
b. Continuous parameter i. Thermal incinerator. Maintain the daily
monitoring systems. average combustion
zone temperature above
the limit established
during the performance
test; and maintain the
daily average oxygen
concentration in the
vent stream (percent,
dry basis) above the
limit established
during the performance
test.
ii. Boiler or process Maintain the daily
heater with a design average combustion
heat input capacity zone temperature above
under 44 MW or a the limit established
boiler or process in the performance
heater in which all test.
vent streams are not
introduced into the
flame zone.
iii. Flare............. The flare pilot light
must be present at all
times and the flare
must be operating at
all times that
emissions may be
vented to it.
----------------------------------------------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6948, Feb. 9,
2005]
Table 10 to Subpart UUU of Part 63--Continuous Monitoring Systems for
Organic HAP Emissions From Catalytic Cracking Units
As stated in Sec. 63.1565(b)(1), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
You shall install,
And you use this operate, and
For each new or existing type of control maintain this type
catalytic cracking unit . . device for your vent of continuous
. . . . monitoring system .
. .
------------------------------------------------------------------------
1. Subject to the NSPS for Not applicable...... Continuous emission
carbon monoxide (CO) in 40 monitoring system
CFR 60.103. to measure and
record the
concentration by
volume (dry basis)
of CO emissions
from each catalyst
regenerator vent.
2. Not subject to the NSPS a. Thermal Continuous emission
for CO in 40 CFR 60.103. incinerator. monitoring system
to measure and
record the
concentration by
volume (dry basis)
of CO emissions
from each catalyst
regenerator vent;
or continuous
parameter
monitoring systems
to measure and
record the
combustion zone
temperature and
oxygen content
(percent, dry
basis) in the
incinerator vent
stream.
b. Process heater or Continuous emission
boiler with a monitoring system
design heat input to measure and
capacity under 44 record the
MW or process concentration by
heater or boiler in volume (dry basis)
which all vent of CO emissions
streams are not from each catalyst
introduced into the regenerator vent;
flame zone. or continuous
parameter
monitoring systems
to measure and
record the
combustion zone
temperature.
[[Page 147]]
c. Flare............ Monitoring device
such as a
thermocouple, an
ultraviolet beam
sensor, or infrared
sensor to
continuously detect
the presence of a
pilot flame.
d. No control device Continuous emission
monitoring system
to measure and
record the
concentration by
volume (dry basis)
of CO emissions
from each catalyst
regenerator vent.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6948, Feb. 9,
2005]
Table 11 to Subpart UUU of Part 63--Requirements for Performance Tests
for Organic HAP Emissions From Catalytic Cracking Units Not Subject to
New Source Performance Standard (NSPS) for Carbon Monoxide (CO)
As stated in Sec. 63.1565(b)(2) and (3), you shall meet each
requirement in the following table that applies to you.
----------------------------------------------------------------------------------------------------------------
According to these
For . . . You must . . . Using . . . requirements . . .
----------------------------------------------------------------------------------------------------------------
1. Each new or existing catalytic a. Select sampling Method 1 or 1A in Sampling sites must be
cracking unit catalyst regenerator port's location and appendix A to part 60 located at the outlet
vent. the number of traverse of this chapter. of the control device
ports. or the outlet of the
regenerator, as
applicable, and prior
to any releases to the
atmosphere.
b. Determine velocity Method 2, 2A, 2D, 2F,
and volumetric flow or 2G in appendix A to
rate. part 60 of this
chapter, as
applicable.
c. Conduct gas Method 3, 3A, or 3B in
molecular weight appendix A to part 60
analysis. of this chapter, as
applicable.
d. Measure moisture Method 4 in appendix A
content of the stack to part 60 of this
gas. chapter.
2. For each new or existing catalytic Measure CO emissions... Data from your Collect CO monitoring
cracking unit catalyst regenerator continuous emission data for each vent for
vent if you use a continuous monitoring system. 24 consecutive
emission monitoring system. operating hours; and
reduce the continuous
emission monitoring
data to 1-hour
averages computed from
four or more data
points equally spaced
over each 1-hour
period.
3. Each catalytic cracking unit a. Measure the CO Method 10, 10A, or 10B
catalyst regenerator vent if you use concentration (dry in appendix A to part
continuous parameter monitoring basis) of emissions 60 of this chapter, as
systems. exiting the control applicable.
device.
b. Establish each Data from the
operating limit in continuous parameter
Table 9 of this monitoring systems.
subpart that applies
to you.
c. Thermal incinerator Data from the Collect temperature
combustion zone continuous parameter monitoring data every
temperature. monitoring systems. 15 minutes during the
entire period of the
CO initial performance
test; and determine
and record the minimum
hourly average
combustion zone
temperature from all
the readings.
[[Page 148]]
d. Thermal incinerator: Data from the Collect oxygen
oxygen, content continuous parameter concentration
(percent, dry basis) monitoring systems. (percent, dry basis)
in the incinerator monitoring data every
vent stream. 15 minutes during the
entire period of the
CO initial performance
test; and determine
and record the minimum
hourly average percent
excess oxygen
concentration from all
the readings.
e. If you use a process Data from the Collect the temperature
heater or boiler with continuous parameter monitoring data every
a design heat input monitoring systems. 15 minutes during the
capacity under 44 MW entire period of the
or process heater or CO initial performance
boiler in which all test; and determine
vent streams are not and record the minimum
introduced into the hourly average
flame zone, establish combustion zone
operating limit for temperature from all
combustion zone the readings.
temperature.
f. If you use a flare, Method 22 (40 CFR part Maintain a 2-hour
conduct visible 60, appendix A). observation period;
emission observations. and record the
presence of a flame at
the pilot light over
the full period of the
test.
g. If you use a flare, 40 CFR
determine that the 60.11(b)(6)through(8).
flare meets the
requirements for net
heating value of the
gas being combusted
and exit velocity.
----------------------------------------------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6948, Feb. 9,
2005]
Table 12 to Subpart UUU of Part 63--Initial Compliance With Organic HAP
Emission Limits for Catalytic Cracking Units
As stated in Sec. 63.1565(b)(4), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
For each new and existing You have
catalytic cracking unit . . For the following demonstrated initial
. emission limit . . . compliance if . . .
------------------------------------------------------------------------
1. Subject to the NSPS for CO emissions from You have already
carbon monoxide (CO) in 40 your catalyst conducted a
CFR 60.103. regenerator vent or performance test to
CO boiler serving demonstrate initial
the catalytic compliance with the
cracking unit must NSPS and the
not exceed 500 ppmv measured CO
(dry basis). emissions are less
than or equal to
500 ppm (dry
basis). As part of
the Notification of
Compliance Status,
you must certify
that your vent
meets the CO limit.
You are not
required to conduct
another performance
test to demonstrate
initial compliance.
You have already
conducted a
performance
evaluation to
demonstrate initial
compliance with the
applicable
performance
specification. As
part of your
Notification of
Compliance Status,
you must certify
that your
continuous emission
monitoring system
meets the
applicable
requirements in
Sec. 63.1572. You
are not required to
conduct another
performance
evaluation to
demonstrate initial
compliance.
2. Not subject to the NSPS a. CO emissions from i. If you use a
for CO in 40 CFR 60.103. your catalyst continuous
regenerator vent or parameter
CO boiler serving monitoring system,
the catalytic the average CO
cracking unit must emissions measured
not exceed 500 ppmv by Method 10 over
(dry basis). the period of the
initial performance
test are less than
or equal to 500
ppmv (dry basis).
[[Page 149]]
ii. If you use a
continuous emission
monitoring system,
the hourly average
CO emissions over
the 24-hour period
for the initial
performance test
are not more than
500 ppmv (dry
basis); and your
performance
evaluation shows
your continuous
emission monitoring
system meets the
applicable
requirements in
Sec. 63.1572.
b. If you use a Visible emissions,
flare, visible measured by Method
emissions must not 22 during the 2-
exceed a total of 5 hour observation
minutes during any period during the
2 operating hours. initial performance
test, are no higher
than 5 minutes.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6948, Feb. 9,
2005]
Table 13 to Subpart UUU of Part 63--Continuous Compliance With Organic
HAP Emission Limits for Catalytic Cracking Units
As stated in Sec. 63.1565(c)(1), you shall meet each requirement in
the following table that applies to you.
----------------------------------------------------------------------------------------------------------------
Subject to this
For each new and existing catalytic emission limit for your You shall demonstrate
cracking unit . . . catalyst regenerator If you must . . . continuous compliance
vent . . . by . . .
----------------------------------------------------------------------------------------------------------------
1. Subject to the NSPS for carbon CO emissions from your Continuous emission Collecting the hourly
monoxide (CO) in 40 CFR 60.103. catalyst regenerator monitoring system. average CO monitoring
vent or CO boiler data according to Sec.
serving the catalytic 63.1572; and
cracking unit must not maintaining the hourly
exceed 500 ppmv (dry average CO
basis). concentration at or
below 500 ppmv (dry
basis).
2. Not subject to the NSPS for CO in i. CO emissions from Continuous emission Same as above.
40 CFR 60.103. your catalyst monitoring system.
regenerator vent or CO
boiler serving the
catalytic cracking
unit must not exceed
500 ppmv (dry basis).
ii. CO emissisons from Continuous parameter Maintaining the hourly
your catalyst monitoring system. average CO
regenerator vent or CO concentration below
boiler serving the 500 ppmv (dry basis).
catalytic cracking
unit must not exceed
500 ppmv (dry basis).
iii. Visible emissions Control device-flare... Maintaining visible
from a flare must not emissions below a
exceed a total of 5 total of 5 minutes
minutes during any 2- during any 2-hour
hour period. operating period.
----------------------------------------------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6948, Feb. 9,
2005]
Table 14 to Subpart UUU of Part 63--Continuous Compliance With Operating
Limits for Organic HAP Emissions From Catalytic Cracking Units
As stated in Sec. 63.1565(c)(1), you shall meet each requirement in
the following table that applies to you.
----------------------------------------------------------------------------------------------------------------
You shall demonstrate
For each new existing catalytic If you use . . . For this operating continuous compliance
cracking unit . . . limit . . . by . . .
----------------------------------------------------------------------------------------------------------------
1. Subject to NSPS for carbon Continuous emission Not applicable......... Complying with Table 13
monoxide (CO) in 40 CFR 60.103. monitoring system. of this subpart.
2. Not subject to the NSPS for CO in a. Continuous emission Not applicable......... Complying with Table 13
40 CFR 60.103. monitoring system. of this subpart.
[[Page 150]]
b. Continuous parameter i. The daily average Collecting the hourly
monitoring systems-- combustion zone and daily average
thermal incinerator. temperature must not temperature monitoring
fall below the level data according to Sec.
established during the 63.1572; and
performance test. maintaining the daily
average combustion
zone temperature above
the limit established
during the performance
test.
ii. The daily average Collecting the hourly
oxygen concentration and daily average
in the vent stream oxygen concentration
(percent, dry basis) monitoring data
must not fall below according to Sec.
the level established 63.1572; and
during the performance maintaining the daily
test. average oxygen
concentration above
the limit established
during the performance
test.
c. Continuous parameter The daily combustion Collecting the average
monitoring systems-- zone temperature must hourly and daily
boiler or process not fall below the temperature monitoring
heater with a design level established in data according to Sec.
heat input capacity the performance test. 63.1572; and
under 44 MW or boiler maintaining the daily
or process heater in average combustion
which all vent streams zone temperature above
are not introduced the limit established
into the flame zone. during the performance
test.
d. Continuous parameter The flare pilot light Collecting the flare
monitoring system-- must be present at all monitoring data
flare. times and the flare according to Sec.
must be operating at 63.1572; and recording
all times that for each 1-hour period
emissions may be whether the monitor
vented to it. was continuously
operating and the
pilot light was
continuously present
during each 1-hour
period.
----------------------------------------------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6948, Feb. 9,
2005]
Table 15 to Subpart UUU of Part 63--Organic HAP Emission Limits for
Catalytic Reforming Units
As stated in Sec. 63.1566(a)(1), you shall meet each emission
limitation in the following table that applies to you.
------------------------------------------------------------------------
You shall meet this emission
For each applicable process vent for a new limit during initial
or existing catalytic reforming unit . . . catalyst depressuring and
catalyst purging operations
. . .
------------------------------------------------------------------------
1. Option 1............................... Vent emissions to a flare
that meets the requirements
for control devices in Sec.
63.11(b). Visible
emissions from a flare must
not exceed a total of 5
minutes during any 2-hour
operating period.
2. Option 2............................... Reduce uncontrolled
emissions of total organic
compounds (TOC) or
nonmethane TOC from your
process vent by 98 percent
by weight using a control
device or to a
concentration of 20 ppmv
(dry basis as hexane),
corrected to 3 percent
oxygen, whichever is less
stringent. If you vent
emissions to a boiler or
process heater to comply
with the percent reduction
or concentration emission
limitation, the vent stream
must be introduced into the
flame zone, or any other
location that will achieve
the percent reduction or
concentration standard.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6951, Feb. 9,
2005]
Table 16 to Subpart UUU of Part 63--Operating Limits for Organic HAP
Emissions From Catalytic Reforming Units
As stated in Sec. 63.1566(a)(2), you shall meet each operating
limit in the following table that applies to you.
[[Page 151]]
------------------------------------------------------------------------
You shall meet this
operating limit
For each new or existing during initial
catalytic reforming unit . . For this type of catalyst
. control device . . . depressuring and
purging operations.
. .
------------------------------------------------------------------------
1. Option 1: vent to flare.. Flare that meets the The flare pilot
requirements for light must be
control devices in present at all
Sec. 63.11(b). times and the flare
must be operating
at all times that
emissions may be
vented to it.
2. Option 2: Percent a. Thermal The daily average
reduction or concentration incinerator, boiler combustion zone
limit. or process heater temperature must
with a design heat not fall below the
input capacity limit established
under 44 MW, or during the
boiler or process performance test.
heater in which all
vent streams are
not introduced into
the flame zone.
b. No control device Operate at all times
according to your
operation,
maintenance, and
monitoring plan
regarding minimum
catalyst purging
conditions that
must be met prior
to allowing
uncontrolled purge
releases.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6951, Feb. 9,
2005]
Table 17 to Subpart UUU of Part 63--Continuous Monitoring Systems for
Organic HAP Emissions From Catalytic Reforming Units
As stated in Sec. 63.1566(b)(1), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
You shall install
For each applicable process If you use this type and operate this
vent for a new or existing of control device . type of continuous
catalytic reforming unit . . . . monitoring system .
. . .
------------------------------------------------------------------------
1. Option 1: vent to a flare Flare that meets the Monitoring device
requirements for such as a
control devices in thermocouple, an
Sec. 63.11(b). ultraviolet beam
sensor, or infrared
sensor to
continuously detect
the presence of a
pilot flame.
2. Option 2: percent Thermal incinerator, Continuous parameter
reduction or concentration process heater or monitoring systems
limit. boiler with a to measure and
design heat input record the
capacity under 44 combustion zone
MW, or process temperature.
heater or boiler in
which all vent
streams are not
introduced into the
flame zone.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6952, Feb. 9,
2005]
Table 18 to Subpart UUU of Part 63--Requirements for Performance Tests
for Organic HAP Emissions From Catalytic Reforming Units
As stated in Sec. 63.1566(b)(2) and (3), you shall meet each
requirement in the following table that applies to you.
----------------------------------------------------------------------------------------------------------------
For each new or exiting catalytic According to these
reforming unit . . . You must . . . Using . . . requirements . . .
----------------------------------------------------------------------------------------------------------------
1. Option 1: Vent to a flare......... a. Conduct visible Method 22 (40 CFR part 2-hour observation
emission observations. 60, appendix A). period. Record the
presence of a flame at
the pilot light over
the full period of the
test.
b. Determine that the Not applicable. 40 CFR 63.11(b)(6)
flare meets the through (8).
requirements for net
heating value of the
gas being combusted
and exit velocity.
2. Option 2: Percent reduction or a. Select sampling site Method 1 or 1A (40 CFR Sampling sites must be
concentration limit. part 60, appendix A). located at the inlet
No traverse site (if you elect the
selection method is emission reduction
needed for vents standard) and outlet
smaller than 0.10 of the control device
meter in diameter. and prior to any
releases to the
atmosphere.
b. Measure gas Method 2, 2A, 2C, 2D,
volumetric flow rate. 2F, or 2G (40 CFR part
60, appendix A), as
applicable.
[[Page 152]]
c. Measure TOC Method 25 (40 part 60, Take either an
concentration (for appendix A) to measure integrated sample or
percent reduction nonmethane TOC four grab samples
standard). concentration (in during each run. If
carbon equivalents) at you use a grab
inlet and outlet of sampling technique,
the control device. If take the samples at
the nonmethane TOC approximately equal
outlet concentration intervals in time,
is expected to be less such as 15-minute
than 50 ppm (as intervals during the
carbon), you can use run.
Method 25A to measure
TOC concentration (as
hexane) at the inlet
and the outlet of the
control device. If you
use Method 25A, you
may use Method 18 (40
CFR part 60, appendix
A) to measure the
methane concentration
to determine the
nonmethane TOC
concentration.
d. Calculate TOC or ....................... Calculate emission rate
nonmethane TOC by Equation 1 of Sec.
emission rate and mass 63.1566 (if you use
emission reduction. Method 25) or Equation
2 of Sec. 63.1566
(if you use Method
25A). Calculate mass
emission reduction by
Equation 3 of Sec.
63.1566.
e. For concentration Method 25A (40 CFR part
standard, measure TOC 60, appendix A) to
concentration. measure TOC
(Optional: Measure concentration (as
methane hexane) at the outlet
concentration.) of the control device.
You may elect to use
Method 18 (40 CFR part
60, appendix A) to
measure the methane
concentration.
f. Determine oxygen Method 3A or 3B (40 CFR
content in the gas part 60, appendix A),
stream at the outlet as applicable.
of the control device.
g. Calculate the TOC or Equation 4 of Sec.
nonmethane TOC 63.1566.
concentration
corrected for oxygen
content (for
concentration
standard).
h. Establish each Data from the Collect the temperature
operating limit in continuous parameter monitoring data every
Table 16 of this monitoring systems. 15 minutes during the
subpart that applies entire period of the
to you for a thermal initial TOC
incinerator, or performance test.
process heater or Determine and record
boiler with a design the minimum hourly
heat input capacity average combustion
under 44 MW, or zone temperature.
process heater or
boiler in which all
vent streams are not
introduced into flame
zone.
i. If you do not use a Data from monitoring Procedures in the
control device, systems as identified operation,
document the purging in the operation, maintenance, and
conditions used prior maintenance, and monitoring plan.
to testing following monitoring plan.
the minimum
requirements in the
operation,
maintenance, and
monitoring plan.
----------------------------------------------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6952, Feb. 9,
2005]
[[Page 153]]
Table 19 to Subpart UUU of Part 63--Initial Compliance With Organic HAP
Emission Limits for Catalytic Reforming Units
As stated in Sec. 63.1566(b)(7), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
For each applicable process
vent for a new or existing For the following You have
catalytic reforming unit . . emission limit . . . demonstrated initial
. compliance if . . .
------------------------------------------------------------------------
Option 1.................... Visible emissions Visible emissions,
from a flare must measured using
not exceed a total Method 22 over the
of 5 minutes during 2-hour observation
any 2 consecutive period of the
hours. performance test,
do not exceed a
total of 5 minutes.
Option 2.................... Reduce uncontrolled The mass emission
emissions of total reduction of
organic compounds nonmethane TOC
(TOC) or nonmethane measured by Method
TOC from your 25 over the period
process vent by 98 of the performance
percent by weight test is at least 98
using a control percent by weight
device or to a as calculated using
concentration of 20 Equations 1 and 3
ppmv (dry basis as of Sec. 63.1566;
hexane), corrected or the mass
to 3 percent emission reduction
oxygen, whichever of TOC measured by
is less stringent. Method 25A (or
nonmethane TOC
measured by Methods
25A and 18) over
the period of the
performance test is
at least 98 percent
by weight as
calculated using
Equations 2 and 3
of Sec. 63.1566;
or the TOC
concentration
measured by Method
25A (or the
nonmethane TOC
concentration
measured by Methods
25A and 18) over
the period of the
performance test
does not exceed 20
ppmv (dry basis as
hexane) corrected
to 3 percent oxygen
as calculated using
Equation 4 of Sec.
63.1566.
------------------------------------------------------------------------
[70 FR 6953, Feb. 9, 2005]
Table 20 to Subpart UUU of Part 63--Continuous Compliance With Organic
HAP Emission Limits for Catalytic Reforming Units
As stated in Sec. 63.1566(c)(1), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
You shall
demonstrate
For each applicable process continuous
vent for a new or existing For this emission compliance during
catalytic reforming unit . . limit . . . initial catalyst
. depressuring and
catalyst purging
operations by . . .
------------------------------------------------------------------------
1. Option 1................. Vent emissions from Maintaining visible
your process vent emissions from a
to a flare that flare below a total
meets the of 5 minutes during
requirements in any 2 consecutive
Sec. 63.11(b). hours.
2. Option 2................. Reduce uncontrolled Maintaining a 98
emissions of total percent by weight
organic compounds emission reduction
(TOC) or nonmethane of TOC or
TOC from your nonmethane TOC; or
process vent by 98 maintaining a TOC
percent by weight or nonmethane TOC
using a control concentration of
device or to a not more than 20
concentration of 20 ppmv (dry basis as
ppmv (dry basis as hexane), corrected
hexane), corrected to 3 percent
to 3 percent oxygen, whichever
oxygen, whichever is less stringent.
is less stringent.
------------------------------------------------------------------------
[70 FR 6954, Feb. 9, 2005]
Table 21 to Subpart UUU of Part 63--Continuous Compliance With Operating
Limits for Organic HAP Emissions From Catalytic Reforming Units
As stated in Sec. 63.1566(c)(1), you shall meet each requirement in
the following table that applies to you.
[[Page 154]]
Table 21 to Subpart UUU of Part 63--Continuous Compliance With Operating Limits for Organic HAP Emissions From
Catalytic Reforming Units
[As stated in Sec. 63.1566(c)(1), you shall meet each requirement in the following table that applies to you.]
----------------------------------------------------------------------------------------------------------------
You shall demonstrate
continuous compliance
For each applicable process vent for For this operating during initial catalyst
a new or existing catalytic reforming If you use . . . limit . . . depressuring and
unit . . . purging operations by .
. .
----------------------------------------------------------------------------------------------------------------
1. Option 1.......................... Flare that meets the The flare pilot light Collecting flare
requirements in Sec. must be present at all monitoring data
63.11(b). times and the flare according to Sec.
must be operating at 63.1572; and recording
all times that for each 1-hour period
emissions may be whether the monitor
vented to it. was continuously
operating and the
pilot light was
continuously present
during each 1-hour
period.
2. Option 2.......................... a. Thermal incinerator Maintain the daily Collecting, the hourly
boiler or process average combustion and daily temperature
heater with a design zone temperature above monitoring data
input capacity under the limit established according to Sec.
44 MW or boiler or during the performance 63.1572; and
process heater in test. maintaining the daily
which not all vent average combustion
streams are not zone temperature above
introduced into the the limit established
flame zone. during the performance
test.
b. No control device... Operate at all times Recording information
according to your to document compliance
operation, with the procedures in
maintenance, and your operation,
monitoring plan maintenance, and
regarding minimum monitoring plan.
purging conditions
that must be met prior
to allowing
uncontrolled purge
releases.
----------------------------------------------------------------------------------------------------------------
[70 FR 6954, Feb. 9, 2005]
Table 22 to Subpart UUU of Part 63--Inorganic HAP Emission Limits for
Catalytic Reforming Units
As stated in Sec. 63.1567(a)(1), you shall meet each emission
limitation in the following table that applies to you.
------------------------------------------------------------------------
You shall meet this emission
limit for each applicable
catalytic reforming unit
For . . . process vent during coke burn-
off and catalyst rejuvenation .
. .
------------------------------------------------------------------------
1. Each existing semi-regenerative Reduce uncontrolled emissions
catalytic reforming unit. of hydrogen chloride (HCl) by
92 percent by weight or to a
concentration of 30 ppmv (dry
basis), corrected to 3 percent
oxygen.
2. Each existing cyclic or continous Reduce uncontrolled emissions
catalytic reforming unit. of HCl by 97 percent by weight
or to a concentration of 10
ppmv (dry basis), corrected to
3 percent oxygen.
3. Each new semi-regenerative, cyclic, Reduce uncontrolled emissions
or continous catalytic reforming unit. of HCl by 97 percent by weight
or to a concentration of 10
ppmv (dry basis), corrected to
3 percent oxygen.
------------------------------------------------------------------------
[70 FR 6955, Feb. 9, 2005]
Table 23 to Subpart UUU of Part 63--Operating Limits for Inorganic HAP
Emission Limitations for Catalytic Reforming Units
As stated in Sec. 63.1567(a)(2), you shall meet each operating
limit in the following table that applies to you.
------------------------------------------------------------------------
For each applicable process vent
for a new or existing catalytic You shall meet this operating limit
reforming unit with this type of during coke burn-off and catalyst
control device . . . rejuvenation . . .
------------------------------------------------------------------------
1. Wet scrubber................... The daily average pH or alkalinity
of the water (or scrubbing liquid)
exiting the scrubber must not fall
below the limit established during
the performance test; and the daily
average liquid-to-gas ratio must
not fall below the limit
established during the performance
test.
2. Internal scrubbing system or no The daily average HCl concentration
control device (e.g., hot regen in the catalyst regenerator exhaust
system) meeting outlet HCl gas must not exceed the limit
concentration limit. established during the performance
test.
[[Page 155]]
3. Internal scrubbing system The daily average pH or alkalinity
meeting HCl percent reduction of the water (or scrubbing liquid)
standard. exiting the internal scrubbing
system must not fall below the
limit established during the
performance test; and the daily
average liquid-to-gas ratio must
not fall below the limit
established during the performance
test.
4. Fixed-bed gas-solid adsorption The daily average temperature of the
system. gas entering or exiting the
adsorption system must not exceed
the limit established during the
performance test; and the HCl
concentration in the adsorption
system exhaust gas must not exceed
the limit established during the
performance test.
5. Moving-bed gas-solid adsorption The daily average temperature of the
system (e.g., Chlorsorb \TM\ gas entering or exiting the
System). adsorption system must not exceed
the limit established during the
performance test; and the weekly
average chloride level on the
sorbent entering the adsorption
system must not exceed the design
or manufacturer's recommended limit
(1.35 weight percent for the
Chlorsorb \TM\ System); and the
weekly average chloride level on
the sorbent leaving the adsorption
system must not exceed the design
or manufacturer's recommended limit
(1.8 weight percent for the
Chlorsorb \TM\ System).
------------------------------------------------------------------------
[70 FR 6955, Feb. 9, 2005]
Table 24 to Subpart UUU of Part 63--Continuous Monitoring Systems for
Inorganic HAP Emissions From Catalytic Reforming Units
As stated in Sec. 63.1567(b)(1), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
You shall install and operate
If you use this type of control device this type of continuous
for your vent . . . monitoring system . . .
------------------------------------------------------------------------
1. Wet scrubber........................ Continuous parameter monitoring
system to measure and record
the total water (or scrubbing
liquid) flow rate entering the
scrubber during coke burn-off
and catalyst rejuvenation; and
continuous parameter
monitoring system to measure
and record gas flow rate
entering or exiting the
scrubber during coke burn-off
and catalyst rejuvenation \1\;
and continuous parameter
monitoring system to measure
and record the pH or
alkalinity of the water (or
scrubbing liquid) exiting the
scrubber during coke burn-off
and catalyst rejuvenation. \2\
2. Internal scrubbing system or no Colormetric tube sampling
control device (e.g., hot regen system to measure the HC1
system) to meet HC1 outlet concentration in the catalyst
concentration limit. regenerator exhaust gas during
coke burn-off and catalyst
rejuvenation. The colormetric
tube sampling system must meet
the requirements in Table 41
of this subpart.
3. Internal scrubbing system to meet Continuous parameter monitoring
HC1 percent reduction standard. system to measure and record
the gas flow rate entering or
exiting the internal scrubbing
system during coke burn-off
and catalyst rejuvenation; and
continuous parameter
monitoring system to measure
and record the total water (or
scrubbing liquid) flow rate
entering the internal
scrubbing system during coke
burn-off and catalyst
rejuvenation; and continuous
parameter monitoring system to
measure and record the pH or
alkalinity of the water (or
scrubbing liquid) exiting the
internal scrubbing system
during coke burn-off and
catalyst rejuvenation. \2\
4. Fixed-bed gas-solid adsorption Continuous parameter monitoring
system. system to measure and record
the temperature of the gas
entering or exiting the
adsorption system during coke
burn-off and catalyst
rejuvenation; and colormetric
tube sampling system to
measure the gaseous HC1
concentration in the
adsorption system exhaust and
at a point within the
absorbent bed not to exceed 90
percent of the total length of
the absorbent bed during coke
burn-off and catalyst
rejuvenation. The colormetric
tube sampling system must meet
the requirements in Table 41
of this subpart.
5. Moving-bed gas-solid adsorption Continuous parameter monitoring
system (e.g., Chlorsorb \TM\ System).. system to measure and record
the temperature of the gas
entering or exiting the
adsorption system during coke
burn-off and catalyst
rejuvenation.
------------------------------------------------------------------------
\1\ If applicable, you can use the alternative in Sec. 63.1573 (a)(1)
instead of a continuous parameter monitoring system for gas flow rate
or instead of a continuous parameter monitoring system for the
cumulative volume of gas.
[[Page 156]]
\2\ If applicable, you can use the alternative in Sec. 63.1573(b)(1)
instead of a continuous parameter monitoring system for pH of the
water (or scrubbing liquid) or the alternative in Sec. 63.1573(b)(2)
instead of a continuous parameter monitoring system for alkalinity of
the water (or scrubbing liquid).
[70 FR 6956, Feb. 9, 2005]
Table 25 to Subpart UUU of Part 63--Requirements for Performance Tests
for Inorganic HAP Emissions From Catalytic Reforming Units
As stated in Sec. 63.1567(b)(2) and (3), you shall meet each
requirement in the following table that applies to you.
----------------------------------------------------------------------------------------------------------------
For each new and existing catalytic
reforming unit using . . . You shall . . . Using . . . According to these
requirements . . .
----------------------------------------------------------------------------------------------------------------
1. Any or no control system........ a. Select sampling Method 1 or 1A (40 CFR (1) If you operate a
port location(s) and part 60, appendix A), control device and you
the number of as applicable. elect to meet an
traverse points. applicable HCl percent
reduction standard,
sampling sites must be
located at the inlet of
the control device or
internal scrubbing system
and at the outlet of the
control device or internal
scrubber system prior to
any release to the
atmosphere. For a series
of fixed-bed systems, the
outlet sampling site
should be located at the
outlet of the first fixed-
bed, prior to entering the
second fixed-bed in the
series.
(2) If you elect to meet an
applicable HCl outlet
concentration limit,
locate sampling sites at
the outlet of the control
device or internal
scrubber system prior to
any release to the
atmosphere. For a series
of fixed-bed systems, the
outlet sampling site
should be located at the
outlet of the first fixed-
bed, prior to entering the
second fixed-bed in the
series. If there is no
control device, locate
sampling sites at the
outlet of the catalyst
regenerator prior to any
release to the atmosphere.
b. Determine velocity Method 2, 2A, 2C, 2D,
and volumetric flow 2F, or 2G (40 CFR
rate. part 60, appendix A),
as applicable..
c. Conduct gas Method 3, 3A, or 3B
molecular weight (40 CFR part 60,
analysis. appendix A), as
applicable.
d. Measure moisture Method 4 (40 CFR part
content of the stack 60, appendix A).
gas.
e. Measure the HCl Method 26 or 26A (40 (1) For semi-regenerative
concentration at the CFR part 60, appendix and cyclic regeneration
selected sampling A). If your control units, conduct the test
locations. device is a wet during the coke burn-off
scrubber or internal and catalyst rejuvenation
scrubbing system, you cycle, but collect no
must use Method 26A. samples during the first
hour or the last 6 hours
of the cycle (for semi-
regenerative units) or
during the first hour or
the last 2 hours of the
cycle (for cyclic
regeneration units). For
continuous regeneration
units, the test should be
conducted no sooner than 3
days after process unit or
control system start up.
(2) Determine and record
the HCl concentration
corrected to 3 percent
oxygen (using Equation 1
of Sec. 63.1567) for
each sampling location for
each test run.
(3) Determine and record
the percent emission
reduction, if applicable,
using Equation 3 of Sec.
63.1567 for each test run.
(4) Determine and record
the average HCl
concentration (corrected
to 3 percent oxygen) and
the average percent
emission reduction, if
applicable, for the
overall source test from
the recorded test run
values.
[[Page 157]]
2. Wet scrubber.................... a. Establish operating i. Data from Measure and record the pH
limit for pH level or continuous parameter or alkalinity of the water
alkalinity. monitoring systems. (or scrubbing liquid)
exiting scrubber every 15
minutes during the entire
period of the performance
test. Determine and record
the minimum hourly average
pH or alkalinity level
from the recorded values.
ii. Alternative pH Measure and record the pH
procedure in Sec. of the water (or scrubbing
63.1573 (b)(1). liquid) exiting the
scrubber during coke burn-
off and catalyst
rejuvenation using pH
strips at least three
times during each test
run. Determine and record
the average pH level for
each test run. Determine
and record the minimum
test run average pH level.
iii. Alternative Measure and record the
alkalinity method in alkalinity of the water
Sec. 63.1573(b)(2). (or scrubbing liquid)
exiting the scrubber
during coke burn-off and
catalyst rejuvenation
using discrete titration
at least three times
during each test run.
Determine and record the
average alkalinity level
for each test run.
Determine and record the
minimum test run average
alkalinity level.
b. Establish operating i. Data from Measure and record the gas
limit for liquid-to- continuous parameter flow rate entering or
gas ratio. monitoring systems. exiting the scrubber and
the total water (or
scrubbing liquid) flow
rate entering the scrubber
every 15 minutes during
the entire period of the
performance test.
Determine and record the
hourly average gas flow
rate and total water (or
scrubbing liquid) flow
rate. Determine and record
the minimum liquid-to-gas
ratio from the recorded,
paired values.
ii. Alternative Collect air flow rate
procedure for gas monitoring data or
flow rate in Sec. determine the air flow
63.1573(a)(1). rate using control room
instruments every 15
minutes during the entire
period of the initial
performance test.
Determine and record the
hourly average rate of all
the readings. Determine
and record the maximum gas
flow rate using Equation 1
of Sec. 63.1573.
3. Internal scrubbing system or no Establish operating Data from continuous Measure and record the HCl
control device (e.g., hot regen limit for HCl parameter monitoring concentration in the
system) meeting HCl outlet concentration. system. catalyst regenerator
concentration limit. exhaust gas using the
colormetric tube sampling
system at least three
times during each test
run. Determine and record
the average HCl
concentration for each
test run. Determine and
record the average HCl
concentration for the
overall source test from
the recorded test run
averages. Determine and
record the operating limit
for HCl concentration
using Equation 4 of Sec.
63.1567.
4. Internal scrubbing system a. Establish operating i. Data from Measure and record the pH
meeting HCl percent reduction limit for pH level or continuous parameter alkalinity of the water
standard. alkalinity. monitoring system. (or scrubbing liquid)
exiting the internal
scrubbing system every 15
minutes during the entire
period of the performance
test. Determine and record
the minimum hourly average
pH or alkalinity level
from the recorded values.
ii. Alternative pH Measure and in record pH of
method in Sec. the water (or scrubbing
63.1573(b)(1). liquid) exiting the
internal scrubbing system
during coke burn-off and
catalyst rejuvenation
using pH strips at least
three times during each
test run. Determine and
record the average pH
level for each test run.
Determine and record the
minimum test run average
pH level.
iii. Alternative Measure and record the
alkalinity method in alkalinity water (or
Sec. 63.1573(b)(2). scrubbing liquid) exiting
the internal scrubbing
system during coke burn-
off and catalyst
rejuvenation using
discrete titration at
least three times during
each test run. Determine
and record the average
alkalinity level for each
test run. Determine and
record the minimum test
run average alkalinity
level.
[[Page 158]]
b. Establish operating Data from continuous Measure and record the gas
limit for liquid-to- parameter monitoring entering or exiting the
gas ratio. systems. internal scrubbing system
and the total water (or
scrubbing liquid) flow
rate entering the internal
scrubbing system every 15
minutes during the entire
period of the performance
test. Determine and record
the hourly average gas
flow rate and total water
(or scrubbing liquid) flow
rate. Determine and record
the minimum liquid-to-gas
ratio from the recorded,
paired values.
5. Fixed-bed gas-solid adsorption a. Establish operating Data from continuous Measure and record the
system. Gas-solid. limit for temperature. parameter monitoring temperature of gas
system. entering or exiting the
adsorption system every 15
minutes. Determine and
record the maximum hourly
average temperature.
b. Establish operating i. Data from (1) Measure and record the
limit for HCl continuous parameter HCl concentration in the
concentration. monitoring systems. exhaust gas from the fixed-
bed adsorption system
using the colormetric tube
sampling system at least
three times during each
test run. Determine and
record the average HCl
concentration for each
test run. Determine and
record the average HCl
concentration for the
overall source test from
the recorded test run
averages.
(2) If you elect to comply
with the HCl outlet
concentration limit
(Option 2), determine and
record the operating limit
for HCl concentration
using Equation 4 of Sec.
63.1567. If you elect to
comply with the HCl
percent reduction standard
(Option 1), determine and
record the operating limit
for HCl concentration
using Equation 5 of Sec.
63.1567.
6. Moving-bed gas-solid adsorption a. Establish operating Data from continuous Measure and record the
system (e.g., Chlorsorb \TM\ limit for temperature. parameter monitoring temperature of gas
System). systems. entering or exiting the
adsorption system every 15
minutes. Determine and
record the maximum hourly
average temperature.
b. Measure the Determination of Metal Measure and record the
chloride level on the Concentration on chloride concentration of
sorbent entering and Catalyst Particles the sorbent material
exiting the (Instrumental entering and exiting the
adsorption system. Analyzer Procedure) adsorption system at least
in appendix A to three times during each
subpart UUU; or EPA test run. Determine and
Method 5050 combined record the average weight
either with EPA percent chloride
Method 9056, or with concentration of the
EPA Method 9253; or sorbent entering the
EPA Method 9212 with adsorption system for each
the soil extraction test run. Determine and
procedures listed record the average weight
within the method.\1\ percent chloride
concentration of the
sorbent exiting the
adsorption system for each
test run.
----------------------------------------------------------------------------------------------------------------
\1\ The EPA Methods 5050, 9056, 9212 and 9253 are included in ``Test Methods for Evaluating Solid Waste,
Physical/Chemical Methods,'' EPA Publication SW-846, Revision 5 (April 1998). The SW-846 and Updates (document
number 955-001-00000-1) are available for purchase from the Superintendent of Documents, U.S. Government
Printing Office, Washington, DC 20402, (202) 512-1800; and from the National Technical Information Services
(NTIS), 5285 Port Royal Road, Springfield, VA 22161, (703) 487-4650. Copies may be inspected at the EPA Docket
Center (Air Docket), EPA West, Room B-108, 1301 Constitution Ave., NW., Washington, DC; or at the Office of
the Federal Register, 800 North Capitol Street, NW., Suite 700, Washington, DC. These methods are also
available at http://www.epa.gov/epaoswer/hazwaste/test/main.htm.
[70 FR 6956, Feb. 9, 2005]
Table 26 to Subpart UUU of Part 63--Initial Compliance With Inorganic
HAP Emission Limits for Catalytic Reforming Units
As stated in Sec. 63.1567(b)(4), you shall meet each requirement in
the following table that applies to you.
[[Page 159]]
------------------------------------------------------------------------
You have
For the following demonstrated
For . . . emission limit . . initial compliance
. if . . .
------------------------------------------------------------------------
1. Each existing semi- Reduce Average emissions
regenerative catalytic uncontrolled HCl measured
reforming unit. emissions of HCl using Method 26
by 92 percent by or 26A, as
weight or to a applicable, over
concentration of the period of the
30 ppmv, (dry performance test,
basis), corrected are reduced by 92
to 3 percent percent or to a
oxygen. concentration
less than or
equal to 30 ppmv
(dry basis)
corrected to 3
percent oxygen.
2. Each existing cyclic or Reduce Average emissions
continuous catalytic reforming uncontrolled of HCl measured
unit and each new semi- emissions of HCl using Method 26
regenerative, cyclic, or by 97 percent by or 26A, as
continuous catalytic reforming weight or to a applicable, over
unit. concentration of the period of the
10 ppmv (dry performance test,
basis), corrected are reduced by 97
to 3 percent percent or to a
oxygen. concentration
less than or
equal to 10 ppmv
(dry basis)
corrected to 3
percent oxygen.
------------------------------------------------------------------------
[70 FR 6959, Feb. 9, 2005]
Table 27 to Subpart UUU of Part 63--Continuous Compliance With Inorganic
HAP Emission Limits for Catalytic Reforming Units
As stated in Sec. 63.1567(c)(1), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
You shall
demonstrate
continuous
For this emission compliance during
For . . . limit . . . coke burn-off and
catalyst
rejuvenation by .
. .
------------------------------------------------------------------------
1. Each existing semi- Reduce Maintaining a 92
regenerative catalytic uncontrolled percent HCl
reforming unit. emissions of HCl emission
by 92 percent by reduction or an
weight or to a HCl concentration
concentration of no more than 30
30 ppmv (dry ppmv (dry basis),
basis), corrected corrected to 3
to 3 percent percent oxygen.
oxygen..
2. Each existing cyclic or Reduce Maintaining a 97
continuous catalytic reforming uncontrolled percent HCl
unit. emissions of HCl control
by 97 percent by efficiency or an
weight or to a HCl concentration
concentration of no more than 10
10 ppmv (dry ppmv (dry basis),
basis), corrected corrected to 3
to 3 percent percent oxygen.
oxygen.
3. Each new semi-regenerative, Reduce Maintaining a 97
cyclic, or continuous catalytic uncontrolled percent HCl
reforming unit. emissions of HCl control
by 97 percent by efficiency or an
weight or to a HCl concentration
concentration of no more than 10
10 ppmv (dry ppmv (dry basis),
basis), corrected corrected to 3
to 3 percent percent oxygen.
oxygen.
------------------------------------------------------------------------
[70 FR 6960, Feb. 9, 2005]
Table 28 to Subpart UUU of Part 63--Continuous Compliance With Operating
Limits for Inorganic HAP Emissions From Catalytic Reforming Units
As stated in Sec. 63.1567(c)(1), you shall meet each requirement in
the following table that applies to you.
[[Page 160]]
Table 28 to Subpart UUU of Part 63--Continuous Compliance With Operating
Limits for Inorganic Hap Emissions From Catalytic Reforming Units
[As stated in Sec. 63.1567(c)(1), you shall meet each requirement in
the following table that applies to you.]
------------------------------------------------------------------------
You shall
demonstrate
For each new and existing continuous
catalytic reforming unit For this operating compliance during
using this type of control limit . . . coke burn-off and
device or system . . . catalyst
rejuvenation by . .
.
------------------------------------------------------------------------
1. Wet scrubber............. a. The daily average Collecting the
pH or alkalinity of hourly and daily
the water (or average pH or
scrubbing liquid) alkalinity
exiting the monitoring data
scrubber must not according to Sec.
fall below the 63.1572 \1\; and
level established maintaining the
during the daily average pH or
performance test. alkalinity above
the operating limit
established during
the performance
test.
b. The daily average Collecting the
liquid-to-gas ratio hourly average gas
must not fall below flow rate \2\ and
the level total water (or
established during scrubbing liquid)
the performance flow rate
test. monitoring data
according to Sec.
63.1572; and
determining and
recording the
hourly average
liquid-to-gas
ratio; and
determining and
recording the daily
average liquid-to-
gas ratio; and
maintaining the
daily average
liquid-to-gas ratio
above the limit
established during
the performance
test.
2. Internal scrubbing system The daily average Measuring and
or no control device (e.g., HCl concentration recording the HCl
hot regen system) meeting in the catalyst concentration at
HCl concentration limit. regenerator exhaust least 4 times
gas must not exceed during a
the limit regeneration cycle
established during (equally spaced in
the performance time) or every 4
test. hours, whichever is
more frequent,
using a colormetric
tube sampling
system; calculating
the daily average
HCl concentration
as an arithmetic
average of all
samples collected
in each 24-hour
period from the
start of the coke
burn-off cycle or
for the entire
duration of the
coke burn-off cycle
if the coke burn-
off cycle is less
than 24 hours; and
maintaining the
daily average HCl
concentration below
the applicable
operating limit.
3. Internal scrubbing system a. The daily average Collecting the
meeting percent HCl pH or alkalinity of hourly and daily
reduction standard. the water (or average pH or
scrubbing liquid) alkalinity
exiting the monitoring data
internal scrubbing according to Sec.
system must not 63.1572 \1\ and
fall below the maintaining the
limit established daily average pH or
during the alkalinity above
performance test. the operating limit
established during
the performance
test.
b. The daily average Collecting the
liquid-to-gas ratio hourly average gas
must not fall below flow rate \2\ and
the level total water (or
established during scrubbing liquid)
the performance flow rate
test. monitoring data
according to Sec.
63.1572; and
determining and
recording the
hourly average
liquid-to-gas
ratio; and
determining and
recording the daily
average liquid-to-
gas ratio; and
maintaining the
daily average
liquid-to-gas ratio
above the limit
established during
the performance
test.
4. Fixed-bed gas-solid a. The daily average Collecting the
adsorption systems. temperature of the hourly and daily
gas entering or average temperature
exiting the monitoring data
adsorption system according to Sec.
must not exceed the 63.1572; and
limit established maintaining the
during the daily average
performance test. temperature below
the operating limit
established during
the performance
test.
b. The HCl Measuring and
concentration in recording the
the exhaust gas concentration of
from the fixed-bed HCl weekly or
gas-solid during each
adsorption system regeneration cycle,
must not exceed the whichever is less
limit established frequent, using a
during the colormetric tube
performance test. sampling system at
a point within the
adsorbent bed not
to exceed 90
percent of the
total length of the
adsorption bed
during coke-burn-
off and catalyst
rejuvenation;
implementing
procedures in the
operating and
maintenance plan if
the HCl
concentration at
the sampling
location within the
adsorption bed
exceeds the
operating limit;
and maintaining the
HCl concentration
in the gas from the
adsorption system
below the
applicable
operating limit.
5. Moving-bed gas-solid a. The daily average Collecting the
adsorption system (e.g., temperature of the hourly and daily
Chlorsorb \TM\ System. gas entering or average temperature
exiting the monitoring data
adsorption system according to Sec.
must not exceed the 63.1572; and
limit established maintaining the
during the daily average
performance test. temperature below
the operating limit
established during
the performance
test.
[[Page 161]]
b. The weekly Collecting samples
average chloride of the sorbent
level on the exiting the
sorbent entering adsorption system
the adsorption three times per
system must not week (on non-
exceed the design consecutive days);
or manufacturer's and analyzing the
recommended limit samples for total
(1.35 weight chloride \3\; and
percent for the determining and
Clorsorb \TM\. recording the
weekly average
chloride
concentration; and
maintaining the
chloride
concentration below
the design or
manufacturer's
recommended limit
(1.35 weight
percent for the
Chlorsorb \TM\
System).
c. The weekly Collecting samples
average chloride of the sorbent
level on the exiting the
sorbent exiting the adsorption system
adsorption system three times per
must not exceed the week (on non-
design or consecutive days);
manufacturer's and analyzing the
recommended limit samples for total
(1.8 weight percent chloride
for the Clorsorb concentration; and
\TM\ System). determining and
recording the
weekly average
chloride
concentration; and
maintaining the
chloride
concentration below
the design or
manufacturer's
recommended limit
(1.8 weight percent
Chlorsorb \TM\
System).
------------------------------------------------------------------------
\1\ If applicable, you can use either alternative in Sec. 63.1573(b)
instead of a continuous parameter monitoring system for pH or
alkalinity if you used the alternative method in the initial
performance test.
\2\ If applicable, you can use the alternative in Sec. 63.1573(a)(1)
instead of a continuous parameter monitoring system for the gas flow
rate or cumulative volume of gas entering or exiting the system if you
used the alternative method in the initial performance test.
\3\ The total chloride concentration of the sorbent material must be
measured by the procedure, ``Determination of Metal Concentration on
Catalyst Particles (Instrumental Analyzer Procedure)'' in appendix A
to this subpart; or by using EPA Method 5050, Bomb Preparation Method
for Solid Waste, combined either with EPA Method 9056, Determination
of Inorganic Anions by Ion Chromatography, or with EPA Method 9253,
Chloride (Titrimetric, Silver Nitrate); or by using EPA Method 9212,
Potentiometric Determination of Chloride in Aqueous Samples with Ion-
Selective Electrode, and using the soil extraction procedures listed
within the method. The EPA Methods 5050, 9056, 9212 and 9253 are
included in ``Test Methods for Evaluating Solid Waste, Physical/
Chemical Methods,'' EPA Publication SW-846, Revision 5 (April 1998).
The SW-846 and Updates (document number 955-001-00000-1) are available
for purchase from the Superintendent of Documents, U.S. Government
Printing Office, Washington, DC 20402, (202) 512-1800; and from the
National Technical Information Services (NTIS), 5285 Port Royal Road,
Springfield, VA 22161, (703) 487-4650. Copies may be inspected at the
EPA Docket Center (Air Docket), EPA West, Room B-108, 1301
Constitution Ave., NW., Washington, DC; or at the Office of the
Federal Register, 800 North Capitol Street, NW., Suite 700,
Washington, DC. These methods are also available at http://www.epa.gov/
epaoswer/hazwaste/test/main.htm.
[70 FR 6954, Feb. 9, 2005]
Table 29 to Subpart UUU of Part 63--HAP Emission Limits for Sulfur
Recovery Units
As stated in Sec. 63.1568(a)(1), you shall meet each emission
limitation in the following table that applies to you.
------------------------------------------------------------------------
You shall meet this emission
For . . . limit for each process vent . .
.
------------------------------------------------------------------------
1. Each new or existing Claus sulfur a. 250 ppmv (dry basis) of
recovery unit part of a sulfur sulfur dioxide (SO2) at zero
recovery plant of 20 long tons per day percent excess air if you use
or more and subject to the NSPS for an oxidation or reduction
sulfur oxides in 40 CFR 60.104(a)(2). control system followed by
incineration.
b. 300 ppmv of reduced sulfur
compounds calculated as ppmv
SO2 (dry basis) at zero
percent excess air if you use
a reduction control system
without incineration.
2. Each new or existing sulfur recovery a. 250 ppmv (dry basis) of SO2
unit (Claus or other type, regardless at zero percent excess air if
of size) not subject to the NSPS for you use an oxidation or
sulfur oxides in 40 CFR 60.104(a)(2): reduction control system
Option 1 (Elect NSPS). followed by incineration.
b. 300 ppmv of reduced sulfur
compounds calculated as ppmv
SO2 (dry basis) at zero
percent excess air if you use
a reduction control system
without incineration.
3. Each new or existing sulfur recovery 300 ppmv of total reduced
unit (Claus or other type, regardless sulfur (TRS) compounds,
of size) not subject to the NSPS for expressed as an equivalent SO2
sulfur oxides in paragraph (a)(2) of concentration (dry basis) at
40 CFR 60.104: Option 2 (TRS limit). zero percent oxygen.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942, Feb. 9, 2005]
[[Page 162]]
Table 30 to Subpart UUU of Part 63--Operating Limits for HAP Emissions
From Sulfur Recovery Units
As stated in Sec. 63.1568(a)(2), you shall meet each operating
limit in the following table that applies to you.
------------------------------------------------------------------------
If use this type of You shall meet this
For . . . control device operating limit. . .
------------------------------------------------------------------------
1. Each new or existing Not applicable...... Not applicable.
Claus sulfur recovery unit
part of a sulfur recovery
plant of 20 long tons per
day or more and subject to
the NSPS for sulfur oxides
in 40 CFR 60.104(a)(2).
2. Each new or existing Not applicable...... Not applicable.
sulfur recovery unit (Claus
or other type, regardless
of size) not subject to the
NSPS for sulfur oxides in
40 CFR 60.104(a)(2): Option
1 (Elect NSPS).
3. Each new or existing Thermal incinerator. Maintain the daily
sulfur recovery unit (Claus average combustion
or other type, regardless zone temperature
of size) not subject to the above the limit
NSPS for sulfur oxides in established during
40 CFR 60.104(a)(2): Option the performance
2 (TRS limit). test; and maintain
the daily average
oxygen
concentration in
the vent stream
(percent, dry
basis) above the
limit established
during the
performance test.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942, Feb. 9, 2005]
Table 31 to Subpart UUU of Part 63--Continuous Monitoring Systems for
HAP Emissions From Sulfur Recovery Units
As stated in Sec. 63.1568(b)(1), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
You shall install
and operate this
For . . . For this limit . . . continuous
monitoring system .
. .
------------------------------------------------------------------------
1. Each new or existing a. 250 ppmv (dry Continuous emission
Claus sulfur recovery unit basis) of SO2 at monitoring system
part of a sulfur recovery zero percent excess to measure and
plant of 20 long tons per air if you use an record the hourly
day or more and subject to oxidation or average
the NSPS for sulfur oxides reduction control concentration of
in 40 CFR 60.104(a)(2). system followed by SO2 (dry basis) at
incineration. zero percent excess
air for each
exhaust stack. This
system must include
an oxygen monitor
for correcting the
data for excess
air.
b. 300 ppmv of Continuous emission
reduced sulfur monitoring system
compounds to measure and
calculated as ppmv record the hourly
SO2 (dry basis) at average
zero percent excess concentration of
air if you use a reduced sulfur and
reduction control oxygen (O2)
system without emissions.
incineration. Calculate the
reduced sulfur
emissions as SO2
(dry basis) at zero
percent excess air.
Exception: You can
use an instrument
having an air or
SO2 dilution and
oxidation system to
convert the reduced
sulfur to SO2 for
continuously
monitoring and
recording the
concentration (dry
basis) at zero
percent excess air
of the resultant
SO2 instead of the
reduced sulfur
monitor. The
monitor must
include an oxygen
monitor for
correcting the data
for excess oxygen.
2. Option 1: Elect NSPS. a. 250 ppmv (dry Continuous emission
Each new or existing sulfur basis) of SO2 at monitoring system
recovery unit (Claus or zero percent excess to measure and
other type, regardless of air if you use an record the hourly
size) not subject to the oxidation or average
NSPS for sulfur oxides in reduction control concentration of
paragraph (a) (2) of 40 CFR system followed by SO2 (dry basis), at
60.104. incineration. zero percent excess
air for each
exhaust stack. This
system must include
an oxygen monitor
for correcting the
data for excess
air.
[[Page 163]]
b. 300 ppmv of Continuous emission
reduced sulfur monitoring system
compounds to measure and
calculated as ppmv record the hourly
SO2 (dry basis) at average
zero percent excess concentration of
air if you use a reduced sulfur and
reduction control O2 emissions for
system without each exhaust stack.
incineration. Calculate the
reduced sulfur
emissions as SO2
(dry basis), at
zero percent excess
air. Exception: You
can use an
instrument having
an air or O2
dilution and
oxidation system to
convert the reduced
sulfur to SO2 for
continuously
monitoring and
recording the
concentration (dry
basis) at zero
percent excess air
of the resultant
SO2 instead of the
reduced sulfur
monitor. The
monitor must
include an oxygen
monitor for
correcting the data
for excess oxygen.
3. Option 2: TRS limit. Each 300 ppmv of total i. Continuous
new or existing sulfur reduced sulfur emission monitoring
recovery unit (Claus or (TRS) compounds, system to measure
other type, regardless of expressed as an and record the
size) not subject to the equivalent SO2 hourly average
NSPS for sulfur oxides in concentration (dry concentration of
40 CFR 60.104(a)(2). basis) at zero TRS for each
percent oxygen. exhaust stack; this
monitor must
include an oxygen
monitor for
correcting the data
for excess oxygen;
or
ii. Continuous
parameter
monitoring systems
to measure and
record the
combustion zone
temperature of each
thermal incinerator
and the oxygen
content (percent,
dry basis) in the
vent stream of the
incinerator.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6961, Feb. 9,
2005]
Table 32 to Subpart UUU of Part 63--Requirements for Performance Tests
for HAP Emissions From Sulfur Recovery Units Not Subject to the New
Source Performance Standards for Sulfur Oxides
As stated in Sec. 63.1568(b)(2) and (3), you shall meet each
requirement in the following table that applies to you.
----------------------------------------------------------------------------------------------------------------
According to these
For . . . You must . . . Using . . . requirements . . .
----------------------------------------------------------------------------------------------------------------
1. Each new and existing sulfur Measure SO2 Data from continuous Collect SO2 monitoring
recovery unit: Option 1 (Elect concentration (for an emission monitoring data every 15 minutes
NSPS). oxidation or reduction system. for 24 consecutive
system followed by operating hours.
incineration) or the Reduce the data to 1-
concentration of hour averages computed
reduced sulfur (or SO2 from four or more data
if you use an points equally spaced
instrument to convert over each 1-hour
the reduced sulfur to period.
SO2) for a reduction
control system without
incineration.
2. Each new and existing sulfur a. Select sampling Method 1 or 1A appendix Sampling sites must be
recovery unit: Option 2 (TRS limit). port's location and A to part 60 of this located at the outlet
the number of traverse chapter. of the control device
ports. and prior to any
releases to the
atmosphere.
b. Determine velocity Method 2, 2A, 2C, 2D,
and volumetric flow 2F, or 2G in appendix
rate. A to part 60 of this
chapter, as
applicable.
c. Conduct gas Method 3, 3A, or 3B in Take the samples
molecular weight appendix A to part 60 simultaneously with
analysis; obtain the of this chapter, as reduced sulfur or
oxygen concentration applicable. moisture samples.
needed to correct the
emission rate for
excess air.
d. Measure moisture Method 4 in appendix A Make your sampling time
content of the stack to part 60 of this for each Method 4
gas. chapter. sample equal to that
for 4 Method 15
samples.
[[Page 164]]
e. Measure the Method 15 or 15A in If the cross-sectional
concentration of TRS. appendix A to part 60 area of the duct is
of this chapter, as less than 5 square
applicable. meters (m\2\) or 54
square feet, you must
use the centroid of
the cross section as
the sampling point. If
the cross-sectional
area is 5 m\2\ or more
and the centroid is
more than 1 meter (m)
from the wall, your
sampling point may be
at a point no closer
to the walls than 1 m
or 39 inches. Your
sampling rate must be
at least 3 liters per
minute or 0.10 cubic
feet per minute to
ensure minimum
residence time for the
sample inside the
sample lines.
f. Calculate the SO2 The arithmetic average
equivalent for each of the SO2 equivalent
run after correcting for each sample during
for moisture and the run.
oxygen.
g. Correct the reduced Equation 1 of Sec.
sulfur samples to zero 63.1568.
percent excess air.sa
h. Establish each Data from the
operating limit in continuous parameter
Table 30 of this monitoring system.
subpart that applies
to you.
i. Measure thermal Data from the Collect temperature
incinerator: continuous parameter monitoring data every
combustion zone monitoring system. 15 minutes during the
temperature. entire period of the
performance test; and
determine and record
the minimum hourly
average temperature
from all the readings.
j. Measure thermal Data from the Collect oxygen
incinerator: oxygen continuous parameter concentration
concentration monitoring system. (percent, dry basis)
(percent, dry basis) data every 15 minutes
in the vent stream. during the entire
period of the
performance test; and
determine and record
the minimum hourly
average percent excess
oxygen concentration.
k. If you use a Data from continuous Collect TRS data every
continuous emission emission monitoring 15 minutes for 24
monitoring system, system. consecutive operating
measure TRS hours. Reduce the data
concentration. to 1-hour averages
computed from four or
more data points
equally spaced over
each 1-hour period.
----------------------------------------------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942, Feb. 9, 2005]
Table 33 to Subpart UUU of Part 63--Initial Compliance With HAP Emission
Limits for Sulfur Recovery Units
As stated in Sec. 63.1568(b)(5), you shall meet each requirement in
the following table that applies to you.
[[Page 165]]
Table 33 to Subpart UUU of Part 63--Initial Compliance With HAP Emission
Limits for Sulfur Recovery Units
[As stated in Sec. 63.1568(b)(5), you shall meet each requirement in
the following table that applies to you.]
------------------------------------------------------------------------
You have
For . . . For the following demonstrated initial
emission limit . . . compliance if . . .
------------------------------------------------------------------------
1. Each new or existing a. 250 pmv (dry You have already
Claus sulfur recovery unit basis) SO2 at zero conducted a
part of a sulfur recovery percent excess air performance test to
plant of 20 long tons per if you use an demonstrate initial
day or more and subject to oxidation or compliance with the
the NSPS for sulfur oxides reduction control NSPS and each 12-
in 40 CFR 60.104(a)(2). system followed by hour rolling
incineration. average
concentration of
SO2 emissions
measured by the
continuous emission
monitoring system
is less than or
equal to 250 ppmv
(dry basis) at zero
percent excess air.
As part of the
Notification of
Compliance Status,
you must certify
that your vent
meets the SO2
limit. You are not
required to do
another performance
test to demonstrate
initial compliance.
You have already
conducted a
performance
evaluation to
demonstrate initial
compliance with the
applicable
performance
specification. As
part of your
Notification of
Compliance Status,
you must certify
that your
continuous emission
monitoring system
meets the
applicable
requirements in
Sec. 63.1572. You
are not required to
do another
performance
evaluation to
demonstrate initial
compliance.
b. 300 ppmv of You have already
reduced sulfur conducted a
compounds performance test to
calculated as ppmv demonstrate initial
SO2 (dry basis) at compliance with the
zero percent excess NSPS and each 12-
air if you use a hour rolling
reduction control average
system without concentration of
incineration. reduced sulfur
compounds measured
by your continuous
emission monitoring
system is less than
or equal to 300
ppmv, calculated as
ppmv SO2 (dry
basis) at zero
percent excess air.
As part of the
Notification of
Compliance Status,
you must certify
that your vent
meets the SO2
limit. You are not
required to do
another performance
test to demonstrate
initial compliance.
You have already
conducted a
performance
evaluation to
demonstrate initial
compliance with the
applicable
performance
specification. As
part of your
Notification of
Compliance Status,
you must certify
that your
continuous emission
monitoring system
meets the
applicable
requirements in
Sec. 63.1572. You
are not required to
do another
performance
evaluation to
demonstrate initial
compliance.
2. Option 1: Elect NSPS. a. 250 ppmv (dry Each 12-hour rolling
Each new or existing sulfur basis) of SO2 at average
recovery unit (Claus or zero percent excess concentration of
other type, regardless of air if you use an SO2 emissions
size) not subject to the oxidation or measured by the
NSPS for sulfur oxides in reduction control continuous emission
40 CFR 60.104(a)(2). system followed by monitoring system
incineration. during the initial
performance test is
less than or equal
to 250 ppmv (dry
basis) at zero
percent excess air;
and your
performance
evaluation shows
the monitoring
system meets the
applicable
requirements in
Sec. 63.1572.
[[Page 166]]
b. 300 ppmv of Each 12-hour rolling
reduced sulfur average
compounds concentration of
calculated as ppmv reduced sulfur
SO2 (dry basis) at compounds measured
zero percent excess by the continuous
air if you use a emission monitoring
reduction control system during the
system without initial performance
incineration. test is less than
or equal to 300
ppmv, calculated as
ppmv SO2 (dry
basis) at zero
percent excess air;
and your
performance
evaluation shows
the continuous
emission monitoring
system meets the
applicable
requirements in
Sec. 63.1572.
3. Option 2: TRS limit. Each 300 ppmv of TRS If you use
new or existing sulfur compounds expressed continuous
recovery unit (Claus or as an equivalent parameter
other type, regardless of SO2 concentration monitoring systems,
size) not subject to the (dry basis) at zero the average
NSPS for sulfur oxides in percent oxygen. concentration of
40 CFR 60.104(a)(2). TRS emissions
measured using
Method 15 during
the initial
performance test is
less than or equal
to 300 ppmv
expressed as
equivalent SO2
concentration (dry
basis) at zero
percent oxygen. If
you use a
continuous emission
monitoring system,
each 12-hour
rolling average
concentration of
TRS emissions
measured by the
continuous emission
monitoring system
during the initial
performance test is
less than or equal
to 300 ppmv
expressed as an
equivalent SO2 (dry
basis) at zero
percent oxygen; and
your performance
evaluation shows
the continuous
emission monitoring
system meets the
applicable
requirements in
Sec. 63.1572.
------------------------------------------------------------------------
[70 FR 6962, Feb. 9, 2005]
Table 34 to Subpart UUU of Part 63--Continuous Compliance With HAP
Emission Limits for Sulfur Recovery Units
As stated in Sec. 63.1568(c)(1), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
You shall
For this emission demonstrate
For . . . limit . . . continuous
compliance by . . .
------------------------------------------------------------------------
1. Each new or existing a. 250 ppmv (dry Collecting the
Claus sulfur recovery unit basis) of SO2 at hourly average SO2
part of a sulfur recovery zero percent excess monitoring data
plant of 20 long tons per air if you use an (dry basis, percent
day or more and subject to oxidation or excess air)
the NSPS for sulfur oxides reduction control according to Sec.
in 40 CFR 60.104(a)(2). system followed by 63.1572;
incineration. determining and
recording each 12-
hour rolling
average
concentration of
SO2; maintaining
each 12-hour
rolling average
concentration of
SO2 at or below the
applicable emission
limitation; and
reporting any 12-
hour rolling
average
concentration of
SO2 greater than
the applicable
emission limitation
in the compliance
report required by
Sec. 63.1575.
[[Page 167]]
b. 300 ppmv of Collecting the
reduced sulfur hourly average
compounds reduced sulfur (and
calculated as ppmv air or O2 dilution
SO2 (dry basis) at and oxidation)
zero percent excess monitoring data
air if you use a according to Sec.
reduction control 63.1572;
system without determining and
incineration. recording each 12-
hour rolling
average
concentration of
reduced sulfur;
maintaining each 12-
hour rolling
average
concentration of
reduced sulfur at
or below the
applicable emission
limitation; and
reporting any 12-
hour rolling
average
concentration of
reduced sulfur
greater than the
applicable emission
limitation in the
compliance report
required by Sec.
63.1575.
2. Option 1: Elect NSPS. a. 250 ppmv (dry Collecting the
Each new or existing sulfur basis) of SO2 at hourly average SO2
recovery unit (Claus or zero percent excess data (dry basis,
other type, regardless of air if you use an percent excess air)
size) not subject to the oxidation or according to Sec.
NSPS for sulfur oxides in reduction control 63.1572;
40 CFR 60.104(a)(2). system followed by determining and
incineration. recording each 12-
hour rolling
average
concentration of
SO2; maintaining
each 12-hour
rolling average
concentration of
SO2 at or below the
applicable emission
limitation; and
reporting any 12-
hour rolling
average
concentration of
SO2 greater than
the applicable
emission limitation
in the compliance
report required by
Sec. 63.1575.
b. 300 ppmv of Collecting the
reduced sulfur hourly average
compounds reduced sulfur (and
calculated as ppmv air or O2 dilution
SO2 (dry basis) at and oxidation)
zero percent excess monitoring data
air if you use a according to Sec.
reduction control 63.1572;
system without determining and
incineration. recording each 12-
hour rolling
average
concentration of
reduced sulfur;
maintaining each 12-
hour rolling
average
concentration of
reduced sulfur at
or below the
applicable emission
limitation; and
reporting any 12-
hour rolling
average
concentration of
reduced sulfur
greater than the
applicable emission
limitation in the
compliance report
required by Sec.
63.1575.
3. Option 2: TRS limit. Each 300 ppmv of TRS i. If you use
new or existing sulfur compounds, continuous
recovery unit (Claus or expressed as an SO2 parameter
other type, regardless of concentration (dry monitoring systems,
size) not subject to the basis) at zero collecting the
NSPS for sulfur oxides in percent oxygen or hourly average TRS
40 CFR 60.104(a)(2). reduced sulfur monitoring data
compounds according to Sec.
calculated as ppmv 63.1572 and
SO2 (dry basis) at maintaining each 12-
zero percent excess hour average
air. concentration of
TRS at or below the
applicable emission
limitation; or
ii. If you use a
continuous emission
monitoring system,
collecting the
hourly average TRS
monitoring data
according to Sec.
63.1572,
determining and
recording each 12-
hour rolling
average
concentration of
TRS; maintaining
each 12-hour
rolling average
concentration of
TRS at or below the
applicable emission
limitation; and
reporting any 12-
hour rolling
average TRS
concentration
greater than the
applicable emission
limitation in the
compliance report
required by Sec.
63.1575.
------------------------------------------------------------------------
[70 FR 6963, Feb. 9, 2005]
Table 35 to Subpart UUU of Part 63--Continuous Compliance With Operating
Limits for HAP Emissions From Sulfur Recovery Units
As stated in Sec. 63.1568(c)(1), you shall meet each requirement in
the following table that applies to you.
[[Page 168]]
------------------------------------------------------------------------
You shall
For this operating demonstrate
For . . . limit . . . continuous
compliance by . . .
------------------------------------------------------------------------
1. Each new or existing Not applicable...... Meeting the
Claus sulfur recovery unit requirements of
part of a sulfur recovery Table 34 of this
plant of 20 long tons per subpart.
day or more and subject to
the NSPS for sulfur oxides
in paragraph 40 CFR
60.104(a)(2).
2. Option 1: Elect NSPS Each Not applicable...... Meeting the
new or existing sulfur requirements of
recovery unit (Claus or Table 34 of this
other type, regardless of subpart.
size) not subject to the
NSPS for sulfur oxides in
40 CFR 60.104(a)(2).
3. Option 2: TRS limit Each a. Maintain the Collecting the
new or existing sulfur daily average hourly and daily
recovery unit (Claus or combustion zone average temperature
other type, regardless of temperature above monitoring data
size) not subject to the the level according to Sec.
NSPS for sulfur oxides in established during 63.1572; and
40 CFR 60.104(a)(2) the performance maintaining the
test. daily average
combustion zone
temperature at or
above the limit
established during
the performance
test.
b. The daily average Collecting the
oxygen hourly and daily
concentration in average O2
the vent stream monitoring data
(percent, dry according to Sec.
basis) must not 63.1572; and
fall below the maintaining the
level established average O2
during the concentration above
performance test. the level
established during
the performance
test.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942, Feb. 9, 2005]
Table 36 to Subpart UUU of Part 63--Work Practice Standards for HAP
Emissions From Bypass Lines
As stated in Sec. 63.1569(a)(1), you shall meet each work practice
standard in the following table that applies to you.
------------------------------------------------------------------------
You shall meet one of these equipment
Option standards . . .
------------------------------------------------------------------------
1. Option 1..................... Install and operate a device
(including a flow indicator, level
recorder, or electronic valve
position monitor) to demonstrate,
either continuously or at least every
hour, whether flow is present in the
by bypass line. Install the device at
or as near as practical to the
entrance to any bypass line that
could divert the vent stream away
from the control device to the
atmosphere.
2. Option 2..................... Install a car-seal or lock-and-key
device placed on the mechanism by
which the bypass device flow position
is controlled (e.g., valve handle,
damper level) when the bypass device
is in the closed position such that
the bypass line valve cannot be
opened without breaking the seal or
removing the device.
3. Option 3..................... Seal the bypass line by installing a
solid blind between piping flanges.
4. Option 4..................... Vent the bypass line to a control
device that meets the appropriate
requirements in this subpart.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6964, Feb. 9,
2005]
Table 37 to Subpart UUU of Part 63--Requirements for Performance Tests
for Bypass Lines
As stated in Sec. 63.1569(b)(1), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
For this standard . . . You shall . . .
------------------------------------------------------------------------
1. Option 1: Install and operate a flow Record during the performance
indicator, level recorder, or test for each type of control
electronic valve position monitor. device whether the flow
indicator, level recorder, or
electronic valve position
monitor was operating and
whether flow was detected at
any time during each hour of
level the three runs
comprising the performance
test.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942, Feb. 9, 2005]
Table 38 to Subpart UUU of Part 63--Initial Compliance With Work
Practice Standards for HAP Emissions from Bypass Lines
As stated in Sec. 63.1569(b)(2), you shall meet each requirement in
the following table that applies to you.
[[Page 169]]
Table 38 to Subpart UUU of Part 63--Initial Compliance With Work
Practice Standards for HAP Emissions From Bypass Lines
[As stated in Sec. 63.1569(b)(2), you shall meet each requirement in
the following table that applies to you.]
------------------------------------------------------------------------
For this work You have
Option . . . practice standard . demonstrated initial
. . compliance if . . .
------------------------------------------------------------------------
1. Each new or existing a. Option 1: Install The installed
bypass line associated with and operate a equipment operates
a catalytic cracking unit, device (including a properly during
catalytic reforming unit, flow indicator, each run of the
or sulfur recovery unit. level recorder, or performance test
electronic valve and no flow is
position monitor) present in the line
to demonstrate, during the test.
either continuously
or at least every
hour, whether flow
is present in
bypass line.
Install the device
at or as near as
practical to the
entrance to any
bypass line that
could divert the
vent stream away
from the control
device to the
atmosphere.
b. Option 2: Install As part of the
a car-seal or lock- notification of
and-key device compliance status,
placed on the you certify that
mechanism by which you installed the
the bypass device equipment, the
flow position is equipment was
controlled (e.g., operational by your
valve handle, compliance date,
damper level) when and you identify
the bypass device what equipment was
is in the closed installed.
position such that
the bypass line
valve cannot be
opened without
breaking the seal
or removing the
device.
c. Option 3: Seal See item 1.b of this
the bypass line by table.
installing a solid
blind between
piping flanges.
d. Option 4: Vent See item 1.b of this
the bypass line to table.
a control device
that meets the
appropriate
requirements in
this subpart.
------------------------------------------------------------------------
[70 FR 6965, Feb. 9, 2005]
Table 39 to Subpart UUU of Part 63--Continuous Compliance With Work
Practice Standards for HAP Emissions From Bypass Lines
As stated in Sec. 63.1569(c)(1), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
You shall demonstrate
If you elect this standard . . . continuous compliance by . . .
------------------------------------------------------------------------
1. Option 1: Flow indicator, level Monitoring and recording on a
recorder, or electronic valve position continuous basis or at least
monitor. every hour whether flow is
present in the bypass line;
visually inspecting the device
at least once every hour if
the device is not equipped
with a recording system that
provides a continuous record;
and recording whether the
device is operating properly
and whether flow is present in
the bypass line.
2. Option 2: Car-seal or lock-and-key Visually inspecting the seal or
device. closure mechanism at least
once every month; and
recording whether the bypass
line valve is maintained in
the closed position and
whether flow is present in the
line.
3. Option 3: Solid blind flange........ Visually inspecting the blind
at least once a month; and
recording whether the blind is
maintained in the correct
position such that the vent
stream cannot be diverted
through the bypass line.
4. Option 4: Vent to control device.... Monitoring the control device
according to appropriate
subpart requirements.
5. Option 1, 2, 3, or 4................ Recording and reporting the
time and duration of any
bypass.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6965, Feb. 9,
2005]
Table 40 to Subpart UUU of Part 63--Requirements for Installation,
Operation, and Maintenance of Continuous Opacity Monitoring Systems and
Continuous Emission Monitoring Systems
As stated in Sec. 63.1572(a)(1) and (b)(1), you shall meet each
requirement in the following table that applies to you.
------------------------------------------------------------------------
This type of continuous opacity or Must meet these requirements .
emission monitoring system . . . . .
------------------------------------------------------------------------
1. Continuous opacity monitoring system Performance specification 1 (40
CFR part 60, appendix B).
[[Page 170]]
2. CO continuous emission monitoring Performance specification 4 (40
system. CFR part 60, appendix B); span
value of 1,000 ppm; and
procedure 1 (40 CFR part 60,
appendix F) except relative
accuracy test audits are
required annually instead of
quarterly.
3. CO continuous emission monitoring Performance specification 4 (40
system used to demonstrate emissions CFR part 60, appendix B); and
average under 50 ppm (dry basis). span value of 100 ppm.
4. SO2 continuous emission monitoring Performance specification 2 (40
system for sulfur recovery unit with CFR part 60, appendix B); span
oxidation control system or reduction value of 500 ppm SO2; use
control system; this monitor must Methods 6 or 6C and 3A or 3B
include an O2 monitor for correcting (40 CFR part 60, appendix A)
the data for excess air. for certifying O2 monitor; and
procedure 1 (40 CFR part 60,
appendix F) except relative
accuracy test audits are
required annually instead of
quarterly.
5. Reduced sulfur and O2 continuous Performance specification 5 (40
emission monitoring system for sulfur CFR part 60, appendix B),
recovery unit with reduction control except calibration drift
system not followed by incineration; specification is 2.5 percent
this monitor must include an O2 of the span value instead of 5
monitor for correcting the data for percent; 450 ppm reduced
excess air unless exempted. sulfur; use Methods 15 or 15A
and 3A or 3B (40 CFR part 60,
appendix A) for certifying
O2monitor; if Method 3A or 3B
yields O2 concentrations below
0.25 percent during the
performance evaluation, the O2
concentration can be assumed
to be zero and the O2 monitor
is not required; and procedure
1 (40 CFR part 60, appendix
F), except relative accuracy
test audits, are required
annually instead of quarterly.
6. Instrument with an air or O2 Performance specification 5 (40
dilution and oxidation system to CFR part 60, appendix B); span
convert reduced sulfur to SO2 for value of 375 ppm SO2; use
continuously monitoring the Methods 15 or 15A and 3A or 3B
concentration of SO2 instead of for certifying O2 monitor; and
reduced sulfur monitor and O2 monitor. procedure 1 (40 CFR part 60,
appendix F), except relative
accuracy test audits, are
required annually instead of
quarterly.
7. TRS continuous emission monitoring Performance specification 5 (40
system for sulfur recovery unit; this CFR part 60, appendix B).
monitor must include an O2 monitor for
correcting the data for excess air.
8. O2 monitor for oxygen concentration. If necessary due to
interferences, locate the
oxygen sensor prior to the
introduction of any outside
gas stream; performance
specification 3 (40 CFR part
60, appendix B; and procedure
1 (40 CFR part 60, appendix
F), except relative accuracy
test audits, are required
annually instead of quarterly.
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942 and 6965, Feb. 9,
2005]
Table 41 to Subpart UUU of Part 63--Requirements for Installation,
Operation, and Maintenance of Continuous Parameter Monitoring Systems
As stated in Sec. 63.1572(c)(1), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
If you use . . . You shall . . .
------------------------------------------------------------------------
1. pH strips.............................. Use pH strips with an
accuracy of 10 percent.
2. Colormetric tube sampling system....... Use a colormetric tube
sampling system with a
printed numerical scale in
ppmv, a standard
measurement range of 1 to
10 ppmv (or 1 to 30 ppmv if
applicable), and a standard
deviation for measured
values of no more than
15
percent. System must
include a gas detection
pump and hot air probe if
needed for the measurement
range.
------------------------------------------------------------------------
[70 FR 6966, Feb. 9, 2005]
Table 42 to Subpart UUU of Part 63--Additional Information for Initial
Notification of Compliance Status
As stated in Sec. 63.1574(d), you shall meet each requirement in
the following table that applies to you.
[[Page 171]]
------------------------------------------------------------------------
You shall provide this additional
For . . . information . . .
------------------------------------------------------------------------
1. Identification of affected Nature, size, design, method of
sources and emission points. operation, operating design capacity of
each affected source; identify each
emission point for each HAP; identify
any affected source or vent associated
with an affected source not subject to
the requirements of subpart UUU.
2. Initial compliance........ Identification of each emission
limitation you will meet for each
affected source, including any option
you select (i.e., NSPS, PM or Ni, flare,
percent reduction, concentration,
options for bypass lines); if
applicable, certification that you have
already conducted a performance test to
demonstrate initial compliance with the
NSPS for an affected source;
certification that the vents meet the
applicable emission limit and the
continuous opacity or that the emission
monitoring system meets the applicable
performance specification; if
applicable, certification that you have
installed and verified the operational
status of equipment by your compliance
date for each bypass line that meets the
requirements of Option 2, 3, or 4 in
Sec. 63.1569 and what equipment you
installed; identification of the
operating limit for each affected
source, including supporting
documentation; if your affected source
is subject to the NSPS, certification of
compliance with NSPS emission
limitations and performance
specifications; a brief description of
performance test conditions (capacity,
feed quality, catalyst, etc.); an
engineering assessment (if applicable);
and if applicable, the flare design
(e.g., steam-assisted, air-assisted, or
non-assisted), all visible emission
readings, heat content determinations,
flow rate measurements, and exit
velocity determinations made during the
Method 22 test.
3. Continuous compliance..... Each monitoring option you elect; and
identification of any unit or vent for
which monitoring is not required; and
the definition of ``operating day.''
(This definition, subject to approval by
the applicable permitting authority,
must specify the times at which a 24-hr
operating day begins and ends.)
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942, Feb. 9, 2005]
Table 43 to Subpart UUU of Part 63--Requirements for Reports
As stated in Sec. 63.1575(a), you shall meet each requirement in
the following table that applies to you.
------------------------------------------------------------------------
The report must You shall submit
You must submit a(n) . . . contain . . . the report . . .
------------------------------------------------------------------------
1. Compliance report.......... If there are not Semiannually
deviations from any according to
emission limitation the
or work practice requirements in
standard that applies Sec.
to you, a statement 63.1575(b).
that there were no
deviations from the
standards during the
reporting period and
that no continuous
opacity monitoring
system or continuous
emission monitoring
system was
inoperative,
inactive, out-of-
control, repaired, or
adjusted;
and if you have a
deviation from any
emission limitation
or work practice
standard during the
reporting period, the
report must contain
the information in
Sec. 63.1575(d) or
(e)
------------------------------------------------------------------------
[67 FR 17773, Apr. 11, 2002, as amended at 70 FR 6942, Feb. 9, 2005]
Table 44 to Subpart UUU of Part 63--Applicability of NESHAP General
Provisions to Subpart UUU
As stated in Sec. 63.1577, you shall meet each requirement in the
following table that applies to you.
----------------------------------------------------------------------------------------------------------------
Citation Subject Applies to supbart UUU Explanation
----------------------------------------------------------------------------------------------------------------
Sec. 63.1........................ Applicability......... Yes................... Except that subpart UUU
specifies calendar or
operating day.
Sec. 63.2........................ Definitions........... Yes...................
Sec. 63.3........................ Units and Yes...................
Abbreviations.
Sec. 63.4........................ Prohibited Activities. Yes...................
Sec. 63.5(A)-(C)................. Construction and Yes................... In Sec. 63.5(b)(4),
Reconstruction. replace the reference to
Sec. 63.9 with Sec.
63.9(b)(4) and (5).
Sec. 63.5(d)(1)(i)............... Application for Yes................... Except, subpart UUU
Approval of specifies the application
Construction or is submitted as soon as
Reconstruction--Gener practicable before startup
al Application but not later than 90 days
Requirements. (rather then 60) after the
promulgation date where
construction or
reconstruction had
commenced and initial
startup had not occurred
before promulgation.
[[Page 172]]
Sec. 63.5(d)(1)(ii).............. ...................... Yes................... Except that emission
estimates specified in
Sec. 63.5(d)(1)(ii)(H)
are not required.
Sec. 63.5(d)(1)(iii)............. ...................... No.................... Subpart UUU specifies
submission of notification
of compliance status.
Sec. 63.5(d)(2).................. ...................... No....................
Sec. 63.5(d)(3).................. ...................... Yes................... Except that Sec.
63.5(d)(3)(ii) does not
apply.
Sec. 63.5(d0(4).................. ...................... Yes...................
Sec. 63.5(e)..................... Approval of Yes...................
Construction or
Reconstruction.
Sec. 63.5(f)(1).................. Approval of
Construction or
Reconstruction Based
on State Review.
Sec. 63.5(f)(2).................. ...................... Yes................... Except that 60 days is
changed to 90 days and
cross-reference to
53.9(B)(2) does not apply.
Sec. 63.6(a)..................... Compliance with Yes...................
Standards and
Maintenance--Applicab
ility.
Sec. 63.6(b)(1)-(4).............. Compliance Dates for Yes...................
New and Reconstructed
Sources.
Sec. 63.6(b)(5).................. ...................... Yes................... Except that subpart UUU
specifies different
compliance dates for
sources.
Sec. 63.6(b)(6).................. [Reserved]............ Not applicable........
Sec. 63.6(b)(7).................. Compliance Dates for Yes...................
New and Reconstructed
Area Sources That
Become Major.
Sec. 63.6(c)(1)-(2).............. Compliance Dates for Yes................... Except that subpart UUU
Existing Sources. specifies different
compliance dates for
sources subject to Tier II
gasoline sulfur control
requirements.
Sec. 63.6(c)(3)-(4).............. [Reserved]............ Not applicable........
Sec. 63.6(c)(5).................. Compliance Dates for Yes...................
Existing Area Sources
That Become Major.
Sec. 63.6(d)..................... [Reserved]............ Not applicable........
Sec. 63.6(e)(1)-(2).............. Operation and Yes...................
Maintenance
Requirements.
Sec. 63.6(e)(3)(i)-(iii)......... Startup, Shutdown, and Yes...................
Malfunction Plan.
Sec. 63.6(e)(3)(iv).............. ...................... Yes................... Except that reports of
actions not consistent
with plan are not required
within 2 and 7 days of
action but rather must be
included in next periodic
report.
Sec. 63.6(e)(3)(v)-(viii)........ ...................... Yes................... The owner or operator is
only required to keep the
latest version of the
plan.
Sec. 63.6(e)(3)(ix).............. ...................... Yes...................
Sec. 63.6(f)(1)-(2)(iii)(C)...... Compliance with Yes...................
Emission Standards.
Sec. 63.6(f)(2)(iii)(D).......... ...................... No....................
Sec. 63.6(f)(2)(iv)-(v).......... ...................... Yes...................
Sec. 63.6(f)(3).................. ...................... Yes...................
Sec. 63.6(g)..................... Alternative Standard.. Yes...................
Sec. 63.6(h)..................... Opacity/VE Standards.. Yes...................
Sec. 63.6(h)(2)(i)............... Determining Compliance No.................... Subpart UUU specifies
with Opacity/VE methods.
Standards.
Sec. 63.6(h)(2)(ii).............. [Reserved]............ Not applicable........
Sec. 63.6(h)(2)(iii)............. ...................... Yes...................
Sec. 63.6(h)(3).................. [Reserved]............ Not applicable........
Sec. 63.6(h)(4).................. Notification of Yes................... Applies to Method 22 tests.
Opacity/VE
Observation Date.
Sec. 63.6(h)(5).................. Conducting Opacity/VE No....................
Observations.
Sec. 63.6(h)(6).................. Records of Conditions Yes................... Applies to Method 22
During Opacity/VE observations.
Observations.
Sec. 63.6(h)(7)(i)............... Report COM Monitoring Yes...................
Data from Performance
Test.
Sec. 63.6(h)(7)(ii).............. Using COM Instead of No....................
Method 9.
[[Page 173]]
Sec. 63.6(h)(7)(iii)............. Averaging Time for COM Yes...................
during Performance
Test.
Sec. 63.6(h)(7)(iv).............. COM Requirements...... Yes...................
Sec. 63.6(h)(8).................. Determining Compliance Yes...................
with Opacity/VE
Standards.
Sec. 63.6(h)(9).................. Adjusted Opacity Yes...................
Standard.
Sec. 63.6(i)(1)-(14)............. Extension of Yes................... Extension of compliance
Compliance. under Sec. 63.6(i)(4)
not applicable to a
facility that installs
catalytic cracking feed
hydrotreating and receives
an extended compliance
date under Sec.
63.1563(c).
Sec. 63.6(i)(15)................. [Reserved]............ Not applicable........
Sec. 63.6(i)(16)................. ...................... Yes...................
Sec. 63.6(j)..................... Presidential Yes...................
Compliance Exemption.
Sec. 63.7(a)(1).................. Performance Test Yes................... Except that subpart UUU
Requirements specifies the applicable
Applicability. test and demonstration
procedures.
Sec. 63.7(a)(2).................. Performance Test Dates No.................... Test results must be
submitted in the
Notification of Compliance
Status report due 150 days
after the compliance date.
Sec. 63.7(a)(3).................. Section 114 Authority. Yes...................
Sec. 63.7(b)..................... Notifications......... Yes................... Except that subpart UUU
specifies notification at
least 30 days prior to the
scheduled test date rather
than 60 days.
Sec. 63.7(c)..................... Quality Assurance Yes...................
Program/Site-Specific
Test Plan.
Sec. 63.7(d)..................... Performance Test Yes...................
Facilities.
Sec. 63.7(e)..................... Conduct of Tests...... Yes...................
Sec. 63.7(f)..................... Alternative Test Yes...................
Method.
Sec. 63.7(g)..................... Data Analysis, Yes................... Except performance test
Recordkeeping, reports must be submitted
Reporting. with notification of
compliance status due 150
days after the compliance
date.
Sec. 63.7(h)..................... Waiver of Tests Yes...................
Sec. 63.8(a)(1).................. Monitoring Yes...................
Requirements-
Applicability.
Sec. 63.8(a)(2).................. Performance Yes...................
Specifications.
Sec. 63.8(a)(3).................. [Reserved]............ Not applicable........
Sec. 63.8(a)(4).................. Monitoring with Flares Yes...................
Sec. 63.8(b)(1).................. Conduct of Monitoring. Yes...................
Sec. 63.8(b)(2)-(3).............. Multiple Effluents and Yes................... Subpart UUU specifies the
Multiple Monitoring required monitoring
Systems. locations.
Sec. 63.8(c)(1).................. Monitoring System Yes...................
Operation and
Maintenance.
Sec. 63.8(c)(1)(i)-(ii).......... Startup, Shutdown, and Yes................... Except that subpart UUU
Malfunctions. specifies that reports are
not required if actions
are consistent with the
SSM plan, unless requested
by the permitting
authority. If actions are
not consistent, actions
must be described in next
compliance report.
Sec. 63.8(c)(1)(iii)............. Compliance with Yes...................
Operation and
Maintenance
Requirements.
Sec. 63.8(c)(2)-(3).............. Monitoring System Yes................... Except that subpart UUU
Installation. specifies that for
continuous parameter
monitoring systems,
operational status
verification includes
completion of manufacturer
written specifications or
installation, operation,
and calibration of the
system or other written
procedures that provide
adequate assurance that
the equipment will monitor
accurately.
Sec. 63.8(c)(4).................. Continuous Monitoring No.................... Subpart UUU specifies
System Requirements. operational requirements.
[[Page 174]]
Sec. 63.8(c)(4)(i)-(ii).......... Continuous Monitoring Yes................... Except that these
System Requirements. requirements apply only to
a continuous opacity
monitoring system or a
continuous emission
monitoring system if you
are subject to the NSPS or
elect to comply with the
NSPS opacity, CO, or SO2
limits.
Sec. 63.8(c)(5).................. COM Minimum Procedures Yes...................
Sec. 63.8(c)(6).................. CMS Requirements...... No.................... Except that these
requirements apply only to
a continuous opacity
monitoring system or
continuous emission
monitoring system if you
are subject to the NSPS or
elect to comply with the
NSPS opacity, CO, or SO2
limits.
Sec. 63.8(c)(7)-(8).............. CMS Requirements...... Yes...................
Sec. 63.8(d)..................... Quality Control Yes................... Except that these
Program. requirements apply only to
a continuous opacity
monitoring system or
continuous emission
monitoring system if you
are subject to the NSPS or
elect to comply with the
NSPS opacity, CO, or SO2
limits.
Sec. 63.8(e)..................... CMS Performance Yes................... Except that these
Evaluation. requirements apply only to
a continuous opacity
monitoring system or
continuous emission
monitoring system if you
are subject to the NSPS or
elect to comply with the
NSPS opacity, CO, or SO2
limits. Results are to be
submitted as part of the
Notification Compliance
Status due 150 days after
the compliance date.
Sec. 63.8(f)(1)-(5).............. Alternative Monitoring Yes................... Except that subpart UUU
Methods. specifies procedures for
requesting alternative
monitoring systems and
alternative parameters.
Sec. 63.8(f)(6).................. Alternative to Yes................... Applicable to continuous
Relative Accuracy emission monitoring
Test. systems if performance
specification requires a
relative accuracy test
audit.
Sec. 63.8(g)(1)-(4).............. Reduction of Yes................... Applies to continuous
Monitoring Data. opacity monitoring system
or continuous emission
monitoring system.
Sec. 63.8(g)(5).................. Data Reduction........ No.................... Subpart UUU specifies
requirements.
Sec. 63.9(a)..................... Notification Yes................... Duplicate Notification of
Requirements--Applica Compliance Status report
bility. to the Regional
Administrator may be
required.
Sec. 63.9(b)(1)-(2), (4)-(5)..... Initial Notifications. Yes................... Except that notification of
construction or
reconstruction is to be
submitted as soon as
practicable before startup
but no later than 30 days
(rather than 60 days)
after the effective date
if construction or
reconstruction had
commenced but startup had
not occurred before the
effective date.
Sec. 63.9(b)(3).................. [Reserved]............
Sec. 63.9(c)..................... Request for Extension Yes...................
of Compliance.
Sec. 63.9(d)..................... New Source Yes...................
Notification for
Special Compliance
Requirements.
Sec. 63.9(e)..................... Notification of Yes................... Except that notification is
Performance Test. required at least 30 days
before test.
Sec. 63.9(f)..................... Notification of VE/ Yes...................
Opacity Test.
Sec. 63.9(g)..................... Additional Yes................... Except that these
Notification requirements apply only to
Requirements for a continuous opacity
Sources with monitoring system or
Continuous Monitoring continuous emission
Systems. monitoring system if you
are subject to the NSPS or
elect to comply with the
NSPS opacity, CO, or SO2
limits.
Sec. 63.9(h)..................... Notification of Yes................... Except that subpart UUU
Compliance Status. specifies the notification
is due no later than 150
days after compliance
date.
Sec. 63.9(i)..................... Adjustment of Yes...................
Deadlines.
Sec. 63.9(j)..................... Change in Previous Yes...................
Information.
63. 10(a).......................... Recordkeeping and Yes...................
Reporting
Applicability.
[[Page 175]]
Sec. 63.10(b).................... Records............... Yes................... Except that Sec.
63.10(b)(2)(xiii) applies
if you use a continuous
emission monitoring system
to meet the NSPS or you
select to meet the NSPS,
CO, or SO2 reduced sulfur
limit and the performance
evaluation requires a
relative accuracy test
audit.
Sec. 63.10(c)(1)-(6), (9)-(15)... Additional Records for Yes................... Except that these
Continuous Monitoring requirements apply if you
Systems. use a continuous opacity
monitoring system or a
continuous emission
monitoring system to meet
the NSPS or elect to meet
the NSPS opacity, CO, or
SO2 limits.
Sec. 63.10(c)(7)-(8)............. Records of Excess No.................... Subpart UUU specifies
Emissions and requirements.
Exceedances.
Sec. 63.10(d)(1)................. General Reporting Yes...................
Requirements.
Sec. 63.10(d)(2)................. Performance Test No.................... Subpart UUU requires
Results. performance test results
to be reported as part of
the Notification of
Compliance Status due 150
days after the compliance
date.
Sec. 63.10(d)(3)................. Opacity or VE Yes...................
Observations.
Sec. 63.10(d)(4)................. Progress Reports...... Yes...................
Sec. 63.10(d)(5)(i).............. Startup, Shutdown, and Yes................... Except that reports are not
Malfunction Reports. required if actions are
consistent with the SSM
plan, unless requested by
permitting authority.
Sec. 63.10(d)(5)(ii)............. ...................... Yes................... Except that actions taken
during a startup,
shutdown, or malfunction
that are not consistent
with the plan do not need
to be reported within 2
and 7 days of commencing
and completing the action,
respectively, but must be
included in the next
periodic report.
Sec. 63.10(e)(1)-(2)............. Additional CMS Reports Yes................... Except that these
requirements apply only to
a continuous opacity
monitoring system or
continuous emission
monitoring system if you
are subject to the NSPS or
elect to comply with the
NSPS opacity, CO, or SO2
limits. Reports of
performance evaluations
must be submitted in
Notification of Compliance
Status.
Sec. 63.10(e)(3)................. Excess Emissions/CMS No.................... Subpart UUU specifies the
Performance Reports. applicable requirements.
Sec. 63.10(e)(4)................. COMS Data Reports..... Yes...................
Sec. 63.10(f).................... Recordkeeping/ Yes...................
Reporting Waiver.
Sec. 63.11....................... Control Device Yes................... Applicable to flares.
Requirements.
Sec. 63.13....................... Addresses............. Yes...................
Sec. 63.14....................... Incorporation by Yes...................
Reference.
Sec. 63.15....................... Available of Yes...................
Information.
----------------------------------------------------------------------------------------------------------------
[70 FR 6966, Feb. 9, 2005, as amended at 71 FR 20462, Apr. 20, 2006]
Appendix A to Subpart UUU of Part 63--Determination of Metal
Concentration on Catalyst Particles (Instrumental Analyzer Procedure)
1.0 Scope and Application.
1.1 Analytes. The analytes for which this method is applicable
include any elements with an atomic number between 11 (sodium) and 92
(uranium), inclusive. Specific analytes for which this method was
developed include:
------------------------------------------------------------------------
Minimum detectable
Analyte CAS No. limit
------------------------------------------------------------------------
Nickel compounds.................. 7440-02-0 <2 % of span.
Total chlorides................... 16887-00-6 <2 % of span.
------------------------------------------------------------------------
[[Page 176]]
1.2 Applicability. This method is applicable to the determination of
analyte concentrations on catalyst particles. This method is applicable
for catalyst particles obtained from the fluid catalytic cracking unit
(FCCU) regenerator (i.e., equilibrium catalyst), from air pollution
control systems operated for the FCCU catalyst regenerator vent (FCCU
fines), from catalytic reforming units (CRU), and other processes as
specified within an applicable regulation. This method is applicable
only when specified within the regulation.
1.3 Data Quality Objectives. Adherence to the requirements of this
method will enhance the quality of the data obtained from the analytical
method.
2.0 Summary of Method.
2.1 A representative sample of catalyst particles is collected,
prepared, and analyzed for analyte concentration using either energy or
wavelength dispersive X-ray flourescent (XRF) spectrometry instrumental
analyzers. In both types of XRF spectrometers, the instrument irradiates
the sample with high energy (primary) x-rays and the elements in the
sample absorb the x-rays and then re-emit secondary (fluorescent) x-rays
of characteristic wavelengths for each element present. In energy
dispersive XRF spectrometers, all secondary x-rays (of all wavelengths)
enter the detector at once. The detector registers an electric current
having a height proportional to the photon energy, and these pulses are
then separated electronically, using a pulse analyzer. In wavelength
dispersive XRF spectrometers, the secondary x-rays are dispersed
spatially by crystal diffraction on the basis of wavelength. The crystal
and detector are made to synchronously rotate and the detector then
receives only one wavelength at a time. The intensity of the x-rays
emitted by each element is proportional to its concentration, after
correcting for matrix effects. For nickel compounds and total chlorides,
the XRF instrument response is expected to be linear to analyte
concentration. Performance specifications and test procedures are
provided to ensure reliable data.
3.0 Definitions.
3.1 Measurement System. The total equipment required for the
determination of analyte concentration. The measurement system consists
of the following major subsystems:
3.1.1 Sample Preparation. That portion of a system used for one or
more of the following: sample acquisition, sample transport, sample
conditioning, or sample preparation prior to introducing the sample into
the analyzer.
3.1.2 Analyzer. That portion of the system that senses the analyte
to be measured and generates an output proportional to its
concentration.
3.1.3 Data Recorder. A digital recorder or personal computer used
for recording measurement data from the analyzer output.
3.2 Span. The upper limit of the gas concentration measurement range
displayed on the data recorder.
3.3 Calibration Standards. Prepared catalyst samples or other
samples of known analyte concentrations used to calibrate the analyzer
and to assess calibration drift.
3.4 Energy Calibration Standard. Calibration standard, generally
provided by the XRF instrument manufacturer, used for assuring accuracy
of the energy scale.
3.5 Accuracy Assessment Standard. Prepared catalyst sample or other
sample of known analyte concentrations used to assess analyzer accuracy
error.
3.6 Zero Drift. The difference in the measurement system output
reading from the initial value for zero concentration level calibration
standard after a stated period of operation during which no unscheduled
maintenance, repair, or adjustment took place.
3.7 Calibration Drift. The difference in the measurement system
output reading from the initial value for the mid-range calibration
standard after a stated period of operation during which no unscheduled
maintenance, repair, or adjustment took place.
3.8 Spectral Interferences. Analytical interferences and excessive
biases caused by elemental peak overlap, escape peak, and sum peak
interferences between elements in the samples.
3.9 Calibration Curve. A graph or other systematic method of
establishing the relationship between the analyzer response and the
actual analyte concentration introduced to the analyzer.
3.10 Analyzer Accuracy Error. The difference in the measurement
system output reading and the ideal value for the accuracy assessment
standard.
4.0 Interferences.
4.1 Spectral interferences with analyte line intensity determination
are accounted for within the method program. No action is required by
the XRF operator once these interferences have been addressed within the
method.
4.2 The X-ray production efficiency is affected by particle size for
the very lightest elements. However, particulate matter (PM) 2.5
particle size effects are substantially < 1 percent for most elements.
The calibration standards should be prepared with material of similar
particle size or be processed (ground) to produce material of similar
particle size as the catalyst samples to be analyzed. No additional
correction for particle size is performed. Alternatively, the sample can
be fused in order to eliminate any potential particle size effects.
[[Page 177]]
5.0 Safety.
5.1 Disclaimer. This method may involve hazardous materials,
operations, and equipment. This test method may not address all of the
safety problems associated with its use. It is the responsibility of the
user of this test method to establish appropriate safety and health
practices and determine the applicability of regulatory limitations
prior to performing this test method.
5.2 X-ray Exposure. The XRF uses X-rays; XRF operators should follow
instrument manufacturer's guidelines to protect from accidental exposure
to X-rays when the instrument is in operation.
5.3 Beryllium Window. In most XRF units, a beryllium (Be) window is
present to separate the sample chamber from the X-ray tube and detector.
The window is very fragile and brittle. Do not allow sample or debris to
fall onto the window, and avoid using compressed air to clean the window
because it will cause the window to rupture. If the window should
rupture, note that Be metal is poisonous. Use extreme caution when
collecting pieces of Be and consult the instrument manufacturer for
advice on cleanup of the broken window and replacement.
6.0 Equipment and Supplies.
6.1 Measurement System. Use any measurement system that meets the
specifications of this method listed in section 13. The typical
components of the measurement system are described below.
6.1.1 Sample Mixer/Mill. Stainless steel, or equivalent to grind/mix
catalyst and binders, if used, to produce uniform particle samples.
6.1.2 Sample Press/Fluxer. Stainless steel, or equivalent to produce
pellets of sufficient size to fill analyzer sample window, or
alternatively, a fusion device capable of preparing a fused disk of
sufficient size to fill analyzer sample window.
6.1.3 Analytical Balance. 0.0001 gram accuracy
for weighing prepared samples (pellets).
6.1.4 Analyzer. An XRF spectrometer to determine the analyte
concentration in the prepared sample. The analyzer must meet the
applicable performance specifications in section 13.
6.1.5 Data Recorder. A digital recorder or personal computer for
recording measurement data. The data recorder resolution (i.e.,
readability) must be 0.5 percent of span. Alternatively, a digital or
analog meter having a resolution of 0.5 percent of span may be used to
obtain the analyzer responses and the readings may be recorded manually.
7.0 Reagents and Standards.
7.1 Calibration Standards. The calibration standards for the
analyzer must be prepared catalyst samples or other material of similar
particle size and matrix as the catalyst samples to be tested that have
known concentrations of the analytes of interest. Preparation (grinding/
milling/fusion) of the calibration standards should follow the same
processes used to prepare the catalyst samples to be tested. The
calibration standards values must be established as the average of a
minimum of three analyses using an approved EPA or ASTM method with
instrument analyzer calibrations traceable to the U.S. National
Institute of Standards and Technology (NIST), if available. The maximum
percent deviation of the triplicate calibration standard analyses should
agree within 10 percent of the average value for the triplicate analysis
(see Figure 1). If the calibration analyses do not meet this criteria,
the calibration standards must be re-analyzed. If unacceptable
variability persists, new calibration standards must be prepared.
Approved methods for the calibration standard analyses include, but are
not limited to, EPA Methods 6010B, 6020, 7520, or 7521 of SW-846.\1\ Use
a minimum of four calibration standards as specified below (see Figure
1):
7.1.1 High-Range Calibration Standard. Concentration equivalent to
80 to 100 percent of the span. The concentration of the high-range
calibration standard should exceed the maximum concentration anticipated
in the catalyst samples.
7.1.2 Mid-Range Calibration Standard. Concentration equivalent to 40
to 60 percent of the span.
7.1.3 Low-Range Calibration Standard. Concentration equivalent to 1
to 20 percent of the span. The concentration of the low-range
calibration standard should be selected so that it is less than either
one-forth of the applicable concentration limit or of the lowest
concentration anticipated in the catalyst samples.
7.1.4 Zero Calibration Standard. Concentration of less than 0.25
percent of the span.
7.2 Accuracy Assessment Standard. Prepare an accuracy assessment
standard and determine the ideal value for the accuracy assessment
standard following the same procedures used to prepare and analyze the
calibration standards as described in section 7.1. The maximum percent
deviation of the triplicate accuracy assessment standard analyses should
agree within 10 percent of the average value for the triplicate analysis
(see Figure 1). The concentration equivalent of the accuracy assessment
standard must be between 20 and 80 percent of the span.
7.3 Energy Calibration Standard. Generally, the energy calibration
standard will be provided by the XRF instrument manufacturer for energy
dispersive spectrometers. Energy calibration is performed using the
manufacturer's recommended calibration standard and involves measurement
of a specific energy line (based on the metal in the
[[Page 178]]
energy calibration standard). This is generally an automated procedure
used to assure the accuracy of the energy scale. This calibration
standard may not be applicable to all models of XRF spectrometers
(particularly wavelength dispersive XRF spectrometers).
8.0 Sample Collection, Preservation, Transport, and Storage. [Reserved]
9.0 Quality Control.
9.1 Energy Calibration. For energy dispersive spectrometers, conduct
the energy calibration by analyzing the energy calibration standard
provided by the manufacturer. The energy calibration involves
measurement of a specific energy line (based on the metal in the energy
calibration standard) and then determination of the difference between
the measured peak energy value and the ideal value. This analysis, if
applicable, should be performed daily prior to any sample analyses to
check the instrument's energy scale. This is generally an automated
procedure and assures the accuracy of the energy scale. If the energy
scale calibration process is not automated, follow the manufacturer's
procedures to manually adjust the instrument, as necessary.
9.2 Zero Drift Test. Conduct the zero drift test by analyzing the
analyte concentration output by the measurement system with the initial
calibration value for the zero calibration standard (see Figure 2). This
analysis should be performed with each set of samples analyzed.
9.3 Calibration Drift Test. Conduct the calibration drift test by
analyzing the analyte concentration output by the measurement system
with the initial calibration value for the mid-range calibration
standard (see Figure 2). This analysis should be performed with each set
of samples analyzed.
9.4 Analyzer Accuracy Test. Conduct the analyzer accuracy test by
analyzing the accuracy assessment standard and comparing the value
output by the measurement system with the ideal value for the accuracy
assessment standard (see Figure 2). This analysis should be performed
with each set of samples analyzed.
10.0 Calibration and Standardization.
10.1 Perform the initial calibration and set-up following the
instrument manufacturer's instructions. These procedures should include,
at a minimum, the major steps listed in sections 10.2 and 10.3.
Subsequent calibrations are to be performed when either a quality
assurance/quality control (QA/QC) limit listed in section 13 is exceeded
or when there is a change in the excitation conditions, such as a change
in the tube, detector, X-ray filters, or signal processor. Calibrations
are typically valid for 6 months to 1 year.
10.2 Instrument Calibration. Calibration is performed initially with
calibration standards of similar matrix and binders, if used, as the
samples to be analyzed (see Figure 1).
10.3 Reference Peak Spectra. Acquisition of reference spectra is
required only during the initial calibration. As long as no processing
methods have changed, these peak shape references remain valid. This
procedure consists of placing the standards in the instrument and
acquiring individual elemental spectra that are stored in the method
file with each of the analytical conditions. These reference spectra are
used in the standard deconvolution of the unknown spectra.
11.0 Analytical Procedure.
11.1 Sample Preparation. Prepare catalyst samples using the same
procedure used to prepare the calibration standards. Measure and record
the weight of sample used. Measure and record the amount of binder, if
any, used. Pellets or films must be of sufficient size to cover the
analyzer sample window.
11.2 Sample Analyses. Place the prepared catalyst samples into the
analyzer. Follow the manufacturer's instructions for analyzing the
samples.
11.3 Record and Store Data. Use a digital recorder or personal
computer to record and store results for each sample. Record any
mechanical or software problems encountered during the analysis.
12.0 Data Analysis and Calculations.
Carry out the following calculations, retaining at least one extra
significant figure beyond that of the acquired data. Round off figures
after final calculation.
12.1 Drift. Calculate the zero and calibration drift for the tests
described in sections 9.2 and 9.3 (see also Figure 2) as follows:
[GRAPHIC] [TIFF OMITTED] TR09FE05.010
Where:
CurrentAnalyzerCal.Response = Instrument response for current QC sample
analyses;
[[Page 179]]
InitialCal.Response = Initial instrument response for calibration
standard;
QC Value = QC metric (zero drift or calibration drift), percent of span;
Span = Span of the monitoring system.
12.2 Analyzer Accuracy. Calculate the analyzer accuracy error for
the tests described in section 9.4 (see also Figure 2) as follows:
[GRAPHIC] [TIFF OMITTED] TR09FE05.011
Where:
Accuracy Value = Percent difference of instrument response to the
ideal response for the accuracy assessment standard;
CurrentAnalyzerCal.Response = Instrument response for current QC sample
analyses;
IdealCal.Response = Ideal instrument response for the accuracy
assessment standard.
13.0 Method Performance.
13.1 Analytical Range. The analytical range is determined by the
instrument design. For this method, a portion of the analytical range is
selected by choosing the span of the monitoring system. The span of the
monitoring system must be selected such that it encompasses the range of
concentrations anticipated to occur in the catalyst sample. If
applicable, the span must be selected such that the analyte
concentration equivalent to the emission standard is not less than 30
percent of the span. If the measured analyte concentration exceeds the
concentration of the high-range calibration standard, the sample
analysis is considered invalid. Additionally, if the measured analyte
concentration is less than the concentration of the low-range
calibration standard but above the detectable limit, the sample analysis
results must be flagged with a footnote stating, in effect, that the
analyte was detected but that the reported concentration is below the
lower quantitation limit.
13.2 Minimum Detectable Limit. The minimum detectable limit depends
on the signal-to-noise ratio of the measurement system. For a well-
designed system, the minimum detectable limit should be less than 2
percent of the span.
13.3 Zero Drift. Less than 2 percent of the
span.
13.4 Calibration Drift. Less than 5 percent of
the span.
13.5 Analyzer Accuracy Error. Less than 10
percent.
14.0 Pollution Prevention. [Reserved]
15.0 Waste Management. [Reserved]
16.0 Alternative Procedures. [Reserved]
17.0 References.
1. U.S. Environmental Protection Agency. 1998. Test Methods for
Evaluating Solid Waste, Physical/Chemical Methods. EPA Publication No.
SW-846, Revision 5 (April 1998). Office of Solid Waste, Washington, DC.
18.0 Tables, Diagrams, Flowcharts, and Validation Data.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Date:
---------------------------------------------------------------------------------------------------------------------------------------------------------
Analytic Method Used:
---------------------------------------------------------------------------------------------------------------------------------------------------------
Zero \a\ Low-Range \b\ Mid-Range \c\ High-Range \d\ Accuracy Std \e\
--------------------------------------------------------------------------------------------------------------------------------------------------------
Sample Run:........................
1..............................
2..............................
3..............................
Average............................
Maximum Percent Deviation .........
--------------------------------------------------------------------------------------------------------------------------------------------------------
\a\ Average must be less than 0.25 percent of span.
\b\ Average must be 1 to 20 percent of span.
\c\ Average must be 40 to 60 percent of span.
\d\ Average must be 80 to 100 percent of span.
\e\ Average must be 20 to 80 percent of span.
Figure 1. Data Recording Sheet for Analysis of Calibration Samples.
Source Identification:
Run Number:
Test Personnel:
Span:
Date:
[[Page 180]]
----------------------------------------------------------------------------------------------------------------
Current
Initial analyzer Drift (percent
calibration calibration of span)
response response
----------------------------------------------------------------------------------------------------------------
Zero Standard...................................................
Mid-range Standard..............................................
----------------------------------------------------------------------------------------------------------------
Current
Ideal analyzer Accuracy error
calibration calibration (percent of
response response ideal)
----------------------------------------------------------------------------------------------------------------
Accuracy Standard...............................................
----------------------------------------------------------------------------------------------------------------
Figure 2. Data Recording Sheet for System Calibration Drift Data.
[70 FR 6970, Feb. 9, 2005]
Subpart VVV_National Emission Standards for Hazardous Air Pollutants:
Publicly Owned Treatment Works
Source: 64 FR 57579, Oct. 26, 1999, unless otherwise noted.
Applicability
Sec. 63.1580 Am I subject to this subpart?
(a) You are subject to this subpart if the following are all true:
(1) You own or operate a publicly owned treatment works (POTW) that
includes an affected source (Sec. 63.1595);
(2) The affected source is located at a POTW which is a major source
of HAP emissions, or at any industrial POTW regardless of whether or not
it is a major source of HAP; and
(3) Your POTW is required to develop and implement a pretreatment
program as defined by 40 CFR 403.8 (for a POTW owned or operated by a
municipality, State, or intermunicipal or interstate agency), or your
POTW would meet the general criteria for development and implementation
of a pretreatment program (for a POTW owned or operated by a department,
agency, or instrumentality of the Federal government).
(b) If your existing POTW treatment plant is not located at a major
source as of October 26, 1999, but thereafter becomes a major source for
any reason other than reconstruction, then, for the purpose of this
subpart, your POTW treatment plant would be considered an existing
source. Note to Paragraph (b): See Sec. 63.2 of the national emission
standards for hazardous air pollutants (NESHAP) General Provisions in
subpart A of this part for the definitions of major source and area
source.
(c) If you reconstruct your POTW treatment plant, then the
requirements for a new or reconstructed POTW treatment plant, as defined
in Sec. 63.1595, apply.
[67 FR 64745, Oct. 21, 2002]
Sec. 63.1581 Does the subpart distinguish between different types of
POTW treatment plants?
Yes, POTW treatment plants are divided into two subcategories. A
POTW treatment plant which does not meet the characteristics of an
industrial POTW treatment plant belongs in the non-industrial POTW
treatment plant subcategory as defined in Sec. 63.1595.
Industrial POTW Treatment Plant Description and Requirements
Sec. 63.1582 What are the characteristics of an industrial POTW
treatment plant?
(a) Your POTW is an industrial POTW treatment plant if an industrial
discharger complies with its NESHAP by using the treatment and controls
located at your POTW. Your POTW accepts the regulated waste stream and
provides treatment and controls as an agent for the industrial
discharger. Industrial POTW treatment plant is defined in Sec. 63.1595.
(b) If, in the future, an industrial discharger begins complying
with its NESHAP by using the treatment and controls at your POTW, then
on the date that the industrial discharger certifies compliance, your
POTW treatment plant will be considered an industrial POTW treatment
plant.
[[Page 181]]
(c) If your POTW treatment plant accepts one or more specific
regulated industrial waste streams as part of compliance with one or
more other NESHAP, then you are subject to all the requirements of each
appropriate NESHAP for each waste stream, as described in the following
section. In the case of overlapping NESHAP requirements, the more
stringent of the requirements will apply.
Sec. 63.1583 What are the emission points and control requirements for
an industrial POTW treatment plant?
(a) The emission points and control requirements for an existing
industrial POTW treatment plant are specified in the appropriate
NESHAP(s) for the industrial user(s) (see Sec. 63.1582). For example,
an existing industrial POTW treatment plant that provides treatment for
a facility subject to subpart FF of this part, the National Emission
Standard for Benzene Waste Operations, must meet the treatment and
control requirements specified in Sec. 61.348(d)(4) of this chapter.
(b) The emission points and control requirements for a new or
reconstructed industrial POTW treatment plant are either those specified
by the particular NESHAP(s) which apply to the industrial user(s) who
discharge their waste for treatment to the POTW, or those emission
points and control requirements set forth in Sec. 63.1586. The set of
control requirements which applies to a particular new or reconstructed
POTW is that set which requires the most stringent overall control of
HAP emissions. If you are uncertain which set of requirements is more
stringent, this determination should be made in consultation with the
permitting authority. Reconstruction is defined in Sec. 63.1595.
Sec. 63.1584 When do I have to comply?
(a) Existing industrial POTW treatment plant. If you have an
existing industrial POTW treatment plant, the appropriate NESHAP(s) for
the industrial user(s) sets the compliance date, or the compliance date
is 60 days after October 26, 1999, whichever is later.
(b) New industrial POTW treatment plant. If you have a new
industrial POTW treatment plant, you must be in compliance as soon as
you begin accepting the waste stream(s) for treatment. If you begin
accepting a specific regulated industrial waste stream(s) for treatment,
you must be in compliance by the time specified in the appropriate
NESHAP(s) for the industrial user(s).
Sec. 63.1585 How does an industrial POTW treatment plant demonstrate
compliance?
(a) An existing industrial POTW treatment plant demonstrates
compliance by operating treatment and control devices which meet all
requirements specified in the appropriate industrial NESHAP(s).
Requirements may include performance tests, routine monitoring,
recordkeeping, and reporting.
(b) If you have a new or reconstructed industrial POTW plant, you
must first determine whether the control requirements set forth in the
applicable industrial NESHAP(s) or the control requirements applicable
to a new or reconstructed nonindustrial POTW under Sec. 63.1586 would
require more stringent overall control of HAP emissions. You must then
meet whichever set of requirements is more stringent. If you determine
that the controls required by the applicable industrial NESHAP(s) are
more stringent, you demonstrate compliance by operating treatment and
control devices which meet all requirements specified in those
industrial NESHAP(s). If you determine that the controls required for a
new or reconstructed nonindustrial POTW are more stringent, you
demonstrate compliance by meeting all requirements in Sec. Sec. 63.1586
through 63.1590.
Non-industrial POTW Treatment Plant Requirements
Sec. 63.1586 What are the emission points and control requirements for
a non-industrial POTW treatment plant?
There are no control requirements for an existing non-industrial
POTW treatment plant. There are no control requirements for any new or
reconstructed area source non-industrial POTW treatment plant which is
not a major source of HAP. The control requirements for a new or
reconstructed
[[Page 182]]
major source non-industrial POTW treatment plant which is a major source
of HAP are as follows:
(a) Covers on the emission points up to, but not including, the
secondary influent pumping station or the secondary treatment units.
These emission points are treatment units that include, but are not
limited to, influent waste stream conveyance channels, bar screens, grit
chambers, grinders, pump stations, aerated feeder channels, primary
clarifiers, primary effluent channels, and primary screening stations.
In addition, all covered units, except primary clarifiers, must have the
air in the headspace ducted to a control device in accordance with the
standards for closed-vent systems and control devices in Sec. 63.693 of
subpart DD of this part, except you may substitute visual inspections
for leak checks rather than Method 21 of Appendix A of part 60 of this
chapter. Reconstruction is defined in Sec. 63.1595.
(1) Covers must be tightly fitted and designed and operated to
minimize exposure of the wastewater to the atmosphere. This includes,
but is not limited to, the absence of visible cracks, holes, or gaps in
the roof sections or between the roof and the supporting wall; broken,
cracked, or otherwise damaged seals or gaskets on closure devices; and
broken or missing hatches, access covers, caps, or other closure
devices.
(2) If wastewater is in a treatment unit, each opening must be
maintained in a closed, sealed position, unless plant personnel are
present and conducting wastewater or sludge sampling, or equipment
inspection, maintenance, or repair.
(b) As an alternative to the requirements in paragraph (a) of this
section, you may comply by demonstrating, for all units up to the
secondary influent pumping station or the secondary treatment units,
that the fraction emitted does not exceed 0.014. You must demonstrate
that for your POTW, the sum of all HAP emissions from those units
divided by the sum of all HAP mass loadings results in an annual rolling
average of the fraction emitted no greater than 0.014. You may use any
combination of pretreatment, wastewater treatment plant modifications,
and control devices to achieve this performance standard; however, you
must demonstrate, to the Administrator's satisfaction that:
(1) You have accurately determined your POTW's annual HAP mass
loadings and your POTW's annual HAP emissions as of the date of start-
up;
(2) Your POTW meets the fraction emitted standard of 0.014 or less;
and
(3) Your POTW has established procedures to demonstrate continuous
compliance which are consistent with the criteria set forth in Sec.
63.1588(c)(4).
[64 FR 57579, Oct. 26, 1999, as amended at 66 FR 16142, Mar. 23, 2001;
67 FR 64746, Oct. 21, 2002]
Sec. 63.1587 When do I have to comply?
If your POTW treatment plant began construction on or after December
1, 1998, you must comply with all provisions of this subpart either
immediately upon startup, or by six months after October 26, 1999,
whichever date is later.
Sec. 63.1588 What inspections must I conduct?
(a) If your treatment units are required to have covers, you must
conduct the following inspections:
(1) You must visually check the cover and its closure devices for
defects that could result in air emissions. Defects include, but are not
limited to, visible cracks, holes, or gaps in the roof sections or
between the roof and the supporting wall; broken, cracked, or otherwise
damaged seals or gaskets on closure devices; and broken or missing
hatches, access covers, caps, or other closure devices.
(2) You must perform an initial visual inspection with follow-up
inspections at least once per year.
(3) In the event that you find a defect on a treatment unit in use,
you must repair the defect within 45 days. If you cannot repair within
45 days, you must notify the EPA or the designated State authority
immediately and report the reason for the delay and the date you expect
to complete the repair. If you find a defect on a treatment unit that is
not in service, you must repair the defect prior to putting the
treatment unit back in wastewater service.
(b) If you own or operate a control device used to meet the
requirements
[[Page 183]]
for Sec. 63.1586, you must comply with the inspection and monitoring
requirements of Sec. 63.695(c) of subpart DD of this part.
(c) To comply with the performance standard specified in Sec.
63.1586(b), you must develop an inspection and monitoring plan. This
inspection and monitoring plan must include, at a minimum, the
following:
(1) A method to determine, to the satisfaction of the Administrator,
the influent HAP mass loading, i.e., the annual mass quantity for each
HAP entering the wastewater treatment plant.
(2) A method to determine, to the satisfaction of the Administrator,
your POTW's annual HAP emissions for all units up to and including the
secondary influent pumping station or up to and not including the
secondary treatment units as of October 26, 1999. The method you use to
determine your HAP emissions, such as modeling or direct source
measurement, must:
(i) Be approved by your EPA Regional Office, State, or local
regulatory agency for use at your POTW;
(ii) Account for all factors affecting emissions from your plant
including, but not limited to, emissions from wastewater treatment
units; emissions resulting from inspection, maintenance, and repair
activities; fluctuations (e.g., daily, monthly, annual, seasonal) in
your influent wastewater HAP concentrations; annual industrial loading;
performance of control devices; or any other factors that could affect
your annual HAP emissions; and
(iii) Include documentation that the values and sources of all data,
operating conditions, assumptions, etc., used in your method result in
an accurate estimation of annual emissions from your plant.
(3) Documentation, to the satisfaction of the Administrator, that
your POTW meets the fraction emitted standard of 0.014 or less, i.e.,
the sum of all HAP emissions from paragraph (c)(2) of this section
divided by the sum of all HAP mass loadings from paragraph (c)(1) of
this section results in a fraction emitted of 0.014 or less as described
in paragraph (c)(4) of this section.
(4) A method to demonstrate, to the satisfaction of the
Administrator, that your POTW is in continuous compliance with the
requirements of Sec. 63.1586(b). Continuous compliance means that your
emissions, when averaged over the course of a year, do not exceed the
level of emissions that allows your POTW to comply with Sec.
63.1586(b). For example, you may identify a parameter(s) that you can
monitor that assures your emissions, when averaged over the entire year,
will meet the requirements in Sec. 63.1586(b). Some example parameters
that may be considered for monitoring include your wastewater influent
HAP concentration and flow, industrial loading from your permitted
industrial dischargers, and your control device performance criteria.
Where emission reductions are due to proper operation of equipment, work
practices, or other operational procedures, your demonstration must
specify the frequency of inspections and the number of days to
completion of repairs. You must, at a minimum, perform the following
each month to demonstrate that your annual rolling average of the
fraction emitted is 0.014 or less:
(i) Determine the average daily flow of the wastewater entering your
POTW treatment plant for the month;
(ii) Determine the flow-weighted monthly concentration of each HAP
in your influent listed in Table 1 to subpart DD of this part;
(iii) Using the current month's information in paragraphs (c)(4)(i)
and (ii) of this section, determine a total annual loading (Mg/year) of
each HAP entering your POTW treatment plant;
(iv) Sum up the values in paragraph (c)(4)(iii) of this section and
determine a total annual loading value (Mg/year) for all HAP entering
your POTW treatment plant for the current month;
(v) Based on the current month's information in paragraph
(c)(4)(iii) of this section along with source testing and emission
modeling, for each HAP, determine annual emissions (Mg/year) from all
wastewater units up to, but not including, secondary treatment units;
(vi) Sum up the values in paragraph (c)(4)(v) of this section and
determine the total annual emissions value for
[[Page 184]]
the month for all HAP from all wastewater units up to, but not
including, secondary treatment units;
(vii) Calculate the fraction emitted value for the month by dividing
the total annual HAP emissions value from paragraph (c)(4)(vi) of this
section by the total annual loading from paragraph (c)(4)(iv) of this
section; and
(viii) Average the fraction emitted value for the month determined
in paragraph (c)(4)(vii) of this section, with the values determined for
the previous 11 months, to calculate an annual rolling average of the
fraction HAP emitted.
Sec. 63.1589 What records must I keep?
(a) To comply with the equipment standard specified in Sec.
63.1586(a), you must prepare and maintain the records required in
paragraphs (a)(1) through (4) of this section:
(1) A record for each treatment unit inspection required by Sec.
63.1588(a). You must include a treatment unit identification number (or
other unique identification description as selected by you) and the date
of inspection.
(2) For each defect detected during inspections required by Sec.
63.1588(a), you must record the location of the defect, a description of
the defect, the date of detection, the corrective action taken to repair
the defect, and the date the repair to correct the defect is completed.
(3) In the event that repair of the defect is delayed, in accordance
with the provisions of Sec. 63.1588(a)(3), you must also record the
reason for the delay and the date you expect to complete the repair.
(4) If you own or operate a control device used to meet the
requirements for Sec. 63.1586, you must comply with the recordkeeping
requirements of Sec. 63.696(a), (b), (g), and (h).
(b) To comply with the performance standard specified in Sec.
63.1586(b), you must prepare and maintain the records required in
paragraphs (b)(1) through (3) of this section:
(1) A record of the methods and data used to determine your POTW's
annual HAP emissions as determined in Sec. 63.1588(c)(2);
(2) A record of the methods and data used to determine that your
POTW meets the fraction emitted standard of 0.014 or less, as determined
in Sec. 63.1588(c)(3); and
(3) A record of the methods and data that demonstrates that your
POTW is in continuous compliance with the requirements of Sec.
63.1588(c)(4).
[64 FR 57579, Oct. 26, 1999, as amended at 66 FR 16142, Mar. 23, 2001]
Sec. 63.1590 What reports must I submit?
(a)(1) If you have an existing non-industrial POTW treatment plant,
or a new or reconstructed area source non-industrial POTW treatment
plant, you are not required to submit a notification of compliance
status. If you have a new or reconstructed non-industrial POTW treatment
plant which is a major source of HAP, you must submit to the
Administrator a notification of compliance status, signed by the
responsible official who must certify its accuracy, attesting to whether
your POTW treatment plant has complied with this subpart. This
notification must be submitted initially, and each time a notification
of compliance status is required under this subpart. At a minimum, the
notification must list--
(i) The methods that were used to determine compliance;
(ii) The results of any monitoring procedures or methods that were
conducted;
(iii) The methods that will be used for determining continuing
compliance;
(iv) The type and quantity of HAP emitted by your POTW treatment
plant;
(v) A description of the air pollution control equipment (or method)
for each emission point; and
(vi) Your statement that your POTW treatment plant has complied with
this subpart.
(2) You must send this notification before the close of business on
the 60th day following the completion of the relevant compliance
demonstration activity specified in this subpart.
(b) After you have been issued a title V permit, you must comply
with all requirements for compliance status reports contained in your
title V permit, including reports required under this subpart. After you
have been issued a
[[Page 185]]
title V permit, and each time a notification of compliance status is
required under this subpart, you must submit the notification of
compliance status to the appropriate permitting authority, as described
in paragraph (d) of this section, following completion of the relevant
compliance demonstration activity specified in this subpart.
(c) You must comply with the delay of repair reporting required in
Sec. 63.1588(a)(3).
(d) If your State has not been delegated authority, you must submit
reports to your EPA Regional Office. If your State has been delegated
authority, you must submit reports to your delegated State authority,
and you must send a copy of each report submitted to the State to your
EPA Regional Office. Your EPA Regional Office, at its discretion, may
waive this requirement for any reports.
(e) You may apply to the Administrator for a waiver of recordkeeping
and reporting requirements by complying with the requirements of Sec.
63.10(f) of subpart A of this part.
(f) If you own or operate a control device used to meet the
requirements of Sec. 63.1586(a), you must submit the reports required
by Sec. 63.697(b) of subpart DD of this part, including a notification
of performance tests; a performance test report; a startup, shutdown,
and malfunction report; and a summary report.
(g) To comply with the performance standard specified in Sec.
63.1586(b), you must submit, for approval by the Administrator, an
initial report explaining your compliance approach 90 days prior to
beginning operation of your new or reconstructed POTW. You must also
submit a startup, shutdown, and malfunction report.
[64 FR 57579, Oct. 26, 1999, as amended at 66 FR 16142, Mar. 23, 2001;
67 FR 64746, Oct. 21, 2002]
General Requirements
Sec. 63.1591 What are my notification requirements?
(a) If you have an industrial POTW treatment plant or a new or
reconstructed non-industrial POTW which is a major source of HAP, and
your State has not been delegated authority, you must submit
notifications to the appropriate EPA Regional Office. If your State has
been delegated authority you must submit notifications to your State and
a copy of each notification to the appropriate EPA Regional Office. The
Regional Office may waive this requirement for any notifications at its
discretion.
(b) You must notify the Administrator in writing no later than 120
calendar days after the effective date of this subpart (or within 120
calendar days after your POTW treatment plant becomes subject to the
relevant standard), and you must provide the following information:
(1) Your name and address;
(2) The address (i.e., physical location) of your POTW treatment
plant;
(3) An identification of these standards as the basis of the
notification and your POTW treatment plant's compliance date; and
(4) A brief description of the nature, size, design, and method of
operation of your POTW treatment plant, including its operating design
capacity and an identification of each point of emission for each HAP,
or if a definitive identification is not yet possible, a preliminary
identification of each point of emission for each HAP.
(c) You must notify the Administrator if your data show that you are
no longer in continuous compliance.
[64 FR 57579, Oct. 26, 1999, as amended at 67 FR 64746, Oct. 21, 2002]
Sec. 63.1592 Which General Provisions apply to my POTW treatment plant?
(a) Table 1 to this subpart lists the General Provisions (40 CFR
part 63, subpart A) which do and do not apply to POTW treatment plants.
(b) Unless a permit is otherwise required by law, the owner or
operator of an industrial POTW which is not a major source is exempt
from the permitting requirements established by 40 CFR part 70.
[67 FR 64746, Oct. 21, 2002]
Sec. 63.1594 Who enforces this subpart?
(a) This subpart can be implemented and enforced by the U.S. EPA, or
a delegated authority such as the applicable State, local, or Tribal
agency. If the
[[Page 186]]
U.S. EPA Administrator has delegated authority to a State, local, or
Tribal agency, then that agency, in addition to the U.S. EPA, has the
authority to implement and enforce this subpart. Contact the applicable
U.S. EPA Regional Office to find out if implementation and enforcement
of this subpart is delegated to a State, local, or Tribal agency.
(b) In delegating implementation and enforcement authority of this
subpart to a State, local, or Tribal agency under subpart E of this
part, the authorities contained in paragraph (c) of this section are
retained by the Administrator of U.S. EPA and cannot be transferred to
the State, local, or Tribal agency.
(c) The authorities that cannot be delegated to State, local, or
Tribal agencies are as specified in paragraphs (c)(1) through (4) of
this section.
(1) Approval of alternatives to the requirements in Sec. Sec.
63.1580, 63.1583 through 63.1584, and 63.1586 through 63.1587.
(2) Approval of major alternatives to test methods under Sec.
63.7(e)(2)(ii) and (f), as defined in Sec. 63.90, and as required in
this subpart.
(3) Approval of major alternatives to monitoring under Sec.
63.8(f), as defined in Sec. 63.90, and as required in this subpart.
(4) Approval of major alternatives to recordkeeping and reporting
under Sec. 63.10(f), as defined in Sec. 63.90, and as required in this
subpart.
[68 FR 37360, June 23, 2003]
Sec. 63.1595 List of definitions.
Affected source means the group of all equipment that comprise the
POTW treatment plant.
Area source means any stationary source of HAP that is not a major
source.
Cover means a device that prevents or reduces air pollutant
emissions to the atmosphere by forming a continuous barrier over the
waste material managed in a treatment unit. A cover may have openings
(such as access hatches, sampling ports, gauge wells) that are necessary
for operation, inspection, maintenance, and repair of the treatment unit
on which the cover is used. A cover may be a separate piece of equipment
which can be detached and removed from the treatment unit, or a cover
may be formed by structural features permanently integrated into the
design of the treatment unit. The cover and its closure devices must be
made of suitable materials that will minimize exposure of the waste
material to the atmosphere, to the extent practical, and will maintain
the integrity of the cover and its closure devices throughout its
intended service life.
Fraction emitted means the fraction of the mass of HAP entering the
POTW wastewater treatment plant which is emitted prior to secondary
treatment. The value is calculated using the following steps:
(1) Determine mass emissions from all equipment up to, but not
including, secondary treatment for each HAP listed in Table 1 to subpart
DD of this part;
(2) Sum the HAP emissions ([Sigma]E);
(3) Sum the HAP mass loadings ([Sigma]L) in the influent to the POTW
wastewater treatment plant; and
(4) Calculate the fraction emitted (fe monthly) using
fe monthly = [Sigma]E/[Sigma]L.
HAP means hazardous air pollutant(s).
Industrial POTW means a POTW that accepts a waste stream regulated
by an industrial NESHAP and provides treatment and controls as an agent
for the industrial discharger. The industrial discharger complies with
its NESHAP by using the treatment and controls located at the POTW. For
example, an industry discharges its benzene-containing waste stream to
the POTW for treatment to comply with 40 CFR part 61, Subpart FF--
National Emission Standard for Benzene Waste Operations. This definition
does not include POTW treating waste streams not specifically regulated
under another NESHAP.
Industrial user means a nondomestic source introducing any pollutant
or combination of pollutants into a POTW. Industrial users can be
commercial or industrial facilities whose wastes enter local sewers.
Non-industrial POTW means a POTW that does not meet the definition
of an industrial POTW as defined above.
Publicly owned treatment works (POTW) means a treatment works, as
that term is defined by section 112(e)(5) of the Clean Air Act, which is
owned by
[[Page 187]]
a municipality (as defined by section 502(4) of the Clean Water Act), a
State, an intermunicipal or interstate agency, or any department,
agency, or instrumentality of the Federal Government. This definition
includes any intercepting sewers, outfall sewers, sewage collection
systems, pumping, power, and other equipment. The wastewater treated by
these facilities is generated by industrial, commercial, and domestic
sources. As used in this regulation, the term POTW refers to both any
publicly owned treatment works which is owned by a State, municipality,
or intermunicipal or interstate agency and therefore eligible to receive
grant assistance under the Subchapter II of the Clean Water Act, and any
federally owned treatment works as that term is described in section
3023 of the Solid Waste Disposal Act.
POTW treatment plant means that portion of the POTW which is
designed to provide treatment (including recycling and reclamation) of
municipal sewage and industrial waste.
Reconstruction means the replacement of components of an affected or
a previously unaffected stationary source such that:
(1) The fixed capital cost of the new components exceeds 50 percent
of the fixed capital cost that would be required to construct a
comparable new source; and
(2) It is technologically and economically feasible for the
reconstructed source to meet the relevant standard(s) established by the
Administrator (or a State) pursuant to section 112 of the Act. Upon
reconstruction, an affected source, or a stationary source that becomes
an affected source, is subject to relevant standards for new sources,
including compliance dates, irrespective of any change in emissions of
HAP from that source.
Secondary treatment means treatment processes, typically biological,
designed to reduce the concentrations of dissolved and colloidal organic
matter in wastewater.
Waste and wastewater means a material, or spent or used water or
waste, generated from residential, industrial, commercial, mining, or
agricultural operations or from community activities that contain
dissolved or suspended matter, and that is discarded, discharged, or is
being accumulated, stored, or physically, chemically, thermally, or
biologically treated in a publicly owned treatment works.
[64 FR 57579, Oct. 26, 1999 as amended at 66 FR 16142, Mar. 23, 2001]
Table 1 to Subpart VVV of Part 63--Applicability of 40 CFR Part 63
General Provisions to Subpart VVV
----------------------------------------------------------------------------------------------------------------
General provisions reference Applicable to subpart VVV Explanation
----------------------------------------------------------------------------------------------------------------
Sec. 63.1................................ ................................... APPLICABILITY.
Sec. 63.1(a)(1).......................... Yes................................ Terms defined in the Clean Air
Act.
Sec. 63.1(a)(2).......................... Yes................................ General applicability
explanation.
Sec. 63.1(a)(3).......................... Yes................................ Cannot diminish a stricter
NESHAP.
Sec. 63.1(a)(4).......................... Yes................................ Not repetitive. Doesn't apply
to section 112(r).
Sec. 63.1(a)(5).......................... Yes................................ Section reserved.
Sec. 63.1(a)(6)-(8)...................... Yes................................ Contacts and authorities.
Sec. 63.1(a)(9).......................... Yes................................ Section reserved.
Sec. 63.1(a)(10)......................... Yes................................ Time period definition.
Sec. 63.1(a)(11)......................... Yes................................ Postmark explanation.
Sec. 63.1(a)(12)-(14).................... Yes................................ Time period changes.
Regulation conflict. Force
and effect of subpart A.
Sec. 63.1(b)(1).......................... Yes................................ Initial applicability
determination of subpart A.
Sec. 63.1(b)(2).......................... Yes................................ Operating permits by States.
Sec. 63.1(b)(3).......................... No................................. Subpart VVV specifies
recordkeeping of records of
applicability determination.
Sec. 63.1(c)(1).......................... Yes................................ Requires compliance with both
subpart A and subpart VVV.
Sec. 63.1(c)(2)(i)....................... No................................. State options regarding title
V permit. Unless required by
the State, area sources
subject to subpart VVV are
exempted from permitting
requirements.
Sec. 63.1(c)(2)(ii)-(iii)................ No................................. State options regarding title
V permit.
Sec. 63.1(c)(3).......................... Yes................................ Section reserved.
Sec. 63.1(c)(4).......................... Yes................................ Extension of compliance.
[[Page 188]]
Sec. 63.1(c)(5).......................... No................................. Subpart VVV addresses area
sources becoming major due to
increase in emissions.
Sec. 63.1(d)............................. Yes................................ Section reserved.
Sec. 63.1(e)............................. Yes................................ Title V permit before a
relevant standard is
established.
Sec. 63.2................................ Yes................................ DEFINITIONS.
Sec. 63.3................................ Yes................................ UNITS AND ABBREVIATIONS.
Sec. 63.4................................ ................................... PROHIBITED ACTIVITIES AND
CIRCUMVENTION.
Sec. 63.4(a)(1)-(3)...................... Yes................................ Prohibits operation in
violation of subpart A.
Sec. 63.4(a)(4).......................... Yes................................ Section reserved.
Sec. 63.4(a)(5).......................... Yes................................ Compliance dates.
Sec. 63.4(b)............................. Yes................................ Circumvention.
Sec. 63.4(c)............................. Yes................................ Severability.
Sec. 63.5................................ ................................... CONSTRUCTION AND
RECONSTRUCTION.
Sec. 63.5(a)(1).......................... Yes................................ Construction and
reconstruction.
Sec. 63.5(a)(2).......................... Yes................................ New source--effective dates.
Sec. 63.5(b)(1).......................... Yes................................ New sources subject to
relevant standards.
Sec. 63.5(b)(2).......................... Yes................................ Section reserved.
Sec. 63.5(b)(3).......................... Yes................................ No new major sources without
Administrator approval.
Sec. 63.5(b)(4).......................... Yes................................ New major source notification.
Sec. 63.5(b)(5).......................... Yes................................ New major sources must comply.
Sec. 63.5(b)(6).......................... Yes................................ New equipment added considered
part of major source.
Sec. 63.5(c)............................. Yes................................ Section reserved.
Sec. 63.5(d)(1).......................... Yes................................ Implementation of section
112(I)(2)--application of
approval of new source
construction.
Sec. 63.5(d)(2).......................... Yes................................ Application for approval of
construction for new sources
listing and describing
planned air pollution control
system.
Sec. 63.5(d)(3).......................... Yes................................ Application for
reconstruction.
Sec. 63.5(d)(4).......................... Yes................................ Administrator may request
additional information.
Sec. 63.5(e)............................. Yes................................ Approval of reconstruction.
Sec. 63.5(f)(1).......................... Yes................................ Approval based on State
review.
Sec. 63.5(f)(2).......................... Yes................................ Application deadline.
Sec. 63.6................................ ................................... COMPLIANCE WITH STANDARDS AND
MAINTENANCE REQUIREMENTS.
Sec. 63.6(a)............................. Yes................................ Applicability of compliance
with standards and
maintenance requirements.
Sec. 63.6(b)............................. Yes................................ Compliance dates for new and
reconstructed sources.
Sec. 63.6(c)............................. Yes................................ Compliance dates for existing
sources apply to existing
industrial POTW treatment
plants.
Sec. 63.6(d)............................. Yes................................ Section reserved.
Sec. 63.6(e)............................. Yes................................ Operation and maintenance
requirements apply to new
sources.
Sec. 63.6(f)............................. Yes................................ Compliance with non-opacity
emission standards applies to
new sources.
Sec. 63.6(g)............................. Yes................................ Use of alternative non-opacity
emission standards applies to
new sources.
Sec. 63.6(h)............................. No................................. POTW treatment plants do not
typically have visible
emissions.
Sec. 63.6(i)............................. Yes................................ Extension of compliance with
emission standards applies to
new sources.
Sec. 63.6(j)............................. Yes................................ Presidential exemption from
compliance with emission
standards.
Sec. 63.7................................ ................................... PERFORMANCE TESTING
REQUIREMENTS.
Sec. 63.7(a)............................. Yes................................ Performance testing is
required for new sources.
Sec. 63.7(b)............................. Yes................................ New sources must notify the
Administrator of intention to
conduct performance testing.
Sec. 63.7(c)............................. Yes................................ New sources must comply with
quality assurance program
requirements.
Sec. 63.7(d)............................. Yes................................ New sources must provide
performance testing
facilities at the request of
the Administrator.
Sec. 63.7(e)............................. Yes................................ Requirements for conducting
performance tests apply to
new sources.
Sec. 63.7(f)............................. Yes................................ New sources may use an
alternative test method.
Sec. 63.7(g)............................. Yes................................ Requirements for data
analysis, recordkeeping, and
reporting associated with
performance testing apply to
new sources.
Sec. 63.7(h)............................. Yes................................ New sources may request a
waiver of performance tests.
Sec. 63.8................................ ................................... MONITORING REQUIREMENTS.
Sec. 63.8(a)............................. Yes................................ Applicability of monitoring
requirements.
Sec. 63.8(b)............................. Yes................................ Monitoring shall be conducted
by new sources.
Sec. 63.8(c)............................. Yes................................ New sources shall operate and
maintain continuous
monitoring systems (CMS).
Sec. 63.8(d)............................. Yes................................ New sources must develop and
implement a CMS quality
control program.
[[Page 189]]
Sec. 63.8(e)............................. Yes................................ New sources may be required to
conduct a performance
evaluation of CMS.
Sec. 63.8(f)............................. Yes................................ New sources may use an
alternative monitoring
method.
Sec. 63.8(g)............................. Yes................................ Requirements for reduction of
monitoring data.
Sec. 63.9................................ ................................... NOTIFICATION REQUIREMENTS.
Sec. 63.9(a)............................. Yes................................ Applicability of notification
requirements.
Sec. 63.9(b)............................. Yes................................ Applicability of notification
requirements. Existing major
non-industrial POTW treatment
plants, and existing and new
or reconstructed area non-
industrial POTW treatment
plants are not subject to the
notification requirements.
Sec. 63.9(c)............................. Yes................................ Request for extension of
compliance with subpart VVV.
Sec. 63.9(d)............................. Yes................................ Notification that source is
subject to special compliance
requirements as specified in
Sec. 63.6(b)(3) and (4).
Sec. 63.9(e)............................. Yes................................ Notification of performance
test.
Sec. 63.9(f)............................. No................................. POTW treatment plants do not
typically have visible
emissions.
Sec. 63.9(g)............................. Yes................................ Additional notification
requirements for sources with
continuous emission
monitoring systems.
Sec. 63.9(h)............................. Yes................................ Notification of compliance
status when the source
becomes subject to subpart
VVV.
Sec. 63.9(i)............................. Yes................................ Adjustments to time periods or
postmark deadlines or
submittal and review of
required communications.
Sec. 63.9(j)............................. Yes................................ Change of information already
provided to the
Administrator.
Sec. 63.10............................... ................................... RECORDKEEPING AND REPORTING
REQUIREMENTS.
Sec. 63.10(a)............................ Yes................................ Applicability of notification
and reporting requirements.
Sec. 63.10(b)(1)-(2)..................... Yes................................ General recordkeeping
requirements.
Sec. 63.10(b)(3)......................... No................................. Recording requirement for
applicability determination.
Sec. 63.10(c)............................ Yes................................ Additional recordkeeping
requirements for sources with
continuous monitoring
systems.
Sec. 63.10(d)............................ Yes................................ General reporting
requirements.
Sec. 63.10(e)............................ Yes................................ Additional reporting
requirements for sources with
continuous monitoring
systems.
Sec. 63.10(f)............................ Yes................................ Waiver of recordkeeping and
reporting requirements.
Sec. 63.11............................... ................................... FLARES AS A CONTROL DEVICE.
Sec. 63.11(a) and (b).................... Yes................................ If a new source uses flares to
comply with the requirements
of subpart VVV, the
requirements of Sec. 63.11
apply.
Sec. 63.12............................... Yes................................ STATE AUTHORITY AND
DESIGNATION.
Sec. 63.13............................... Yes................................ ADDRESSES OF STATE AIR
POLLUTION CONTROL AGENCIES
AND EPA REGIONAL OFFICES.
Sec. 63.14............................... Yes................................ INCORPORATION BY REFERENCE.
Sec. 63.15............................... Yes................................ AVAILABILITY OF INFORMATION
AND CONFIDENTIALITY.
----------------------------------------------------------------------------------------------------------------
[64 FR 57579, Oct. 26, 1999 as amended at 66 FR 16142, Mar. 23, 2001; 67
FR 64746, Oct. 21, 2002]
Subpart WWW [Reserved]
Subpart XXX_National Emission Standards for Hazardous Air Pollutants for
Ferroalloys Production: Ferromanganese and Silicomanganese
Source: 64 FR 27458, May 20, 1999, unless otherwise noted.
Sec. Sec. 63.1620-63.1649 [Reserved]
Sec. 63.1650 Applicability and compliance dates.
(a) This subpart applies to all new and existing ferromanganese and
silicomanganese production facilities that manufacture ferromanganese or
silicomanganese and are major sources or are co-located at major sources
of hazardous air pollutant emissions.
(b) The following sources at a ferromanganese and silicomanganese
production facility are subject to this subpart:
[[Page 190]]
(1) Open submerged arc furnaces with a furnace power input of 22 MW
or less when producing ferromanganese.
(2) Open submerged arc furnaces with a furnace power input greater
than 22 MW when producing ferromanganese.
(3) Open submerged arc furnaces with a furnace power input greater
than 25 MW when producing silicomanganese.
(4) Open submerged arc furnaces with a furnace power input of 25 MW
or less when producing silicomanganese.
(5) Semi-sealed submerged arc furnaces when producing
ferromanganese.
(6) Metal oxygen refining (MOR) process.
(7) Crushing and screening operations.
(8) Fugitive dust sources.
(c) A new affected source is one for which construction or
reconstruction commenced after August 4, 1998.
(d) The following table specifies which provisions of subpart A of
this part apply to owners and operators of ferromanganese and
silicomanganese production facilities subject to this subpart:
General Provisions Applicability to Subpart XXX
------------------------------------------------------------------------
Applies to
Reference, Subpart A General Subpart XXX, Sec.
Provisions Sec. 63.1620- Comment
63.1679
------------------------------------------------------------------------
63.1-63.5..................... Yes..............
63.6(a)-(g), (i)-(j).......... Yes..............
63.6(h)(1)-(h)(6), (h)(8)- Yes..............
(h)(9).
63.7(h)(7).................... No............... Sec. 63.6(h)(7),
use of continuous
opacity monitoring
system, not
applicable.
63.7.......................... Yes..............
63.8.......................... Yes..............
63.9.......................... Yes.............. Notification of
performance test
results changed to a
30-day notification
period.
63.10......................... Yes.............. Allow changes in
dates by which
periodic reports are
submitted by mutual
agreement between
the owner or
operator and the
State to occur any
time after the
source's compliance
date.
63.11......................... No............... Flares will not be
used to comply with
the emission limits.
63.12-63.15................... Yes..............
------------------------------------------------------------------------
(e) Compliance dates. (1) Each owner or operator of an existing
affected source must comply with the requirements of this subpart no
later than November 21, 2001.
(2) Each owner or operator of a new or reconstructed affected source
that commences construction or reconstruction after August 4, 1998, must
comply with the requirements of this subpart by May 20, 1999 or upon
startup of operations, whichever is later.
[64 FR 27458, May 20, 1999, as amended at 66 FR 16012, Mar. 22, 2001]
Sec. 63.1651 Definitions.
Terms in this subpart are defined in the Clean Air Act (Act), in
subpart A of this part, or in this section as follows:
Bag leak detection system means a system that is capable of
continuously monitoring particulate matter (dust) loadings in the
exhaust of a baghouse in order to detect bag leaks and other upset
conditions. A bag leak detection system includes, but is not limited to,
an instrument that operates on triboelectric, light scattering, light
transmittance, or other effect to continuously monitor relative
particulate matter loadings.
Capture system means the equipment (including hoods, ducts, fans,
dampers, etc.) used to capture or transport particulate matter generated
by an affected submerged arc furnace.
Casting means the period of time from when molten ferroalloy falls
from the furnace tapping runner into the ladle until pouring into molds
is completed. This includes the following operations: ladle filling,
pouring alloy from one ladle to another, slag separation, slag removal,
and ladle transfer by crane, truck, or other conveyance.
Crushing and screening equipment means the crushers, grinders,
mills, screens and conveying systems used to crush, size, and prepare
for packing
[[Page 191]]
manganese-containing materials, including raw materials, intermediate
products, and final products.
Fugitive dust source means a stationary source from which manganese-
bearing particles are discharged to the atmosphere due to wind or
mechanical inducement such as vehicle traffic. Fugitive dust sources
include plant roadways, yard areas, and outdoor material storage and
transfer operations.
Furnace power input means the resistive electrical power consumption
of a submerged arc furnace, expressed as megawatts (MW).
Malfunction means any sudden, infrequent, and not reasonably
preventable failure of air pollution control equipment, process
equipment, or a process to operate in a normal or usual manner which
causes, or has the potential to cause, the emission limitations in an
applicable standard to be exceeded. Failures caused in part by poor
maintenance or careless operation are not malfunctions.
Metal oxygen refining (MOR) process means the reduction of the
carbon content of ferromanganese through the use of oxygen.
Open submerged arc furnace means an electric submerged arc furnace
that is equipped with a canopy hood above the furnace to collect primary
emissions.
Operating time means the period of time in hours that the affected
source is in operation beginning at a startup and ending at the next
shutdown.
Plant roadway means any area at a ferromanganese and silicomanganese
production facility that is subject to plant mobile equipment, such as
fork lifts, front end loaders, or trucks, carrying manganese-bearing
materials. Excluded from this definition are employee and visitor
parking areas, provided they are not subject to traffic by plant mobile
equipment.
Primary emissions means gases and emissions collected by hoods and
ductwork located above an open furnace or under the cover of a semi-
closed or sealed furnace.
Sealed submerged arc furnace means an electric submerged arc furnace
equipped with a total enclosure or cover from which primary emissions
are evacuated directly.
Semi-closed submerged arc furnace means an electric submerged arc
furnace equipped with a partially sealed cover over the furnace. This
cover is equipped with openings to allow penetration of the electrodes
into the furnace. Mix is introduced into the furnace around the
electrode holes forming a partial seal between the electrodes and the
cover. Furnace emissions generated under the cover are ducted to an
emission control device. Emissions that escape the cover are collected
and vented through stacks directly to the atmosphere.
Shop means the building which houses one or more submerged arc
furnaces.
Shutdown means the cessation of operation of an affected source for
any purpose.
Startup means the setting in operation of an affected source for any
purpose.
Submerged arc furnace means any furnace wherein electrical energy is
converted to heat energy by transmission of current between electrodes
partially submerged in the furnace charge. The furnace may be of an
open, semi-sealed, or sealed design.
Tapping emissions means a source of air pollutant emissions that
occur during the process of removing the molten product from the
furnace.
Tapping period means the time from when a tap hole is opened until
the time a tap hole is closed.
[64 FR 27458, May 20, 1999, as amended at 71 FR 20462, Apr. 20, 2006]
Sec. 63.1652 Emission standards.
(a) New and reconstructed submerged arc furnaces. No owner or
operator shall cause to be discharged into the atmosphere from any new
or reconstructed submerged arc furnace exhaust gases (including primary
and tapping) containing particulate matter in excess of one of the
following:
(1) 0.23 kilograms per hour per megawatt (kg/hr/MW) (0.51 pounds per
hour per megawatt [lb/hr/MW]), or
(2) 35 milligrams per dry standard cubic meter (mg/dscm) (0.015
grains per dry standard cubic foot [gr/dscf]).
(b) Existing open submerged arc furnaces. No owner or operator shall
cause to be discharged into the atmosphere
[[Page 192]]
from any existing open submerged arc furnace exhaust gases (including
primary and tapping) containing particulate matter in excess of one of
the following:
(1) 9.8 kilograms per hour (kg/hr) (21.7 pounds per hour (lb/hr))
when producing ferromanganese in an open furnace operating at a furnace
power input of 22 MW or less; or
(2) 13.5 kg/hr (29.8 lb/hr) when producing ferromanganese in an open
furnace operating at a furnace power input greater than 22 MW; or
(3) 16.3 kg/hr (35.9 lb/hr) when producing silicomanganese in an
open furnace operating at a furnace power input greater than 25 MW; or
(4) 12.3 kg/hr (27.2 lb/hr) when producing silicomanganese in an
open furnace operating at a furnace power input of 25 MW or less.
(c) Existing semi-sealed submerged arc furnaces. No owner or
operator shall cause to be discharged into the atmosphere from any
existing semi-sealed submerged arc furnace exhaust gases (including
primary, tapping, and vent stacks) containing particulate matter in
excess of 11.2 kg/hr (24.7 lb/hr) when producing ferromanganese.
(d) MOR process. No owner or operator shall cause to be discharged
into the atmosphere from any new, reconstructed, or existing MOR process
exhaust gases containing particulate matter in excess of 69 mg/dscm
(0.03 gr/dscf).
(e) Crushing and screening equipment--(1) New and reconstructed
equipment. No owner or operator shall cause to be discharged into the
atmosphere from any new or reconstructed piece of equipment associated
with crushing and screening exhaust gases containing particulate matter
in excess of 50 mg/dscm (0.022 gr/dscf).
(2) Existing equipment. No owner or operator shall cause to be
discharged into the atmosphere from any existing piece of equipment
associated with crushing and screening exhaust gases containing
particulate matter in excess of 69 (mg/dscm) (0.03 gr/dscf).
[64 FR 27458, May 20, 1999, as amended at 66 FR 16013, Mar. 22, 2001]
Sec. 63.1653 Opacity standards.
No owner or operator shall cause emissions exiting from a shop due
solely to operations of any affected submerged arc furnace, to exceed 20
percent opacity for more than one 6-minute period during any performance
test, with the following exceptions:
(a) Visible particulate emissions from a shop due solely to
operation of a semi-closed submerged arc furnace, may exceed 20 percent
opacity, measured as a 6-minute average, one time during any performance
test, so long as the emissions never exceed 60 percent opacity, measured
as a 6-minute average.
(b) Blowing taps, poling and oxygen lancing of the tap hole;
burndowns associated with electrode measurements; and maintenance
activities associated with submerged arc furnaces and casting operations
are exempt from the opacity standards specified in this section.
Sec. 63.1654 Operational and work practice standards.
(a) Fugitive dust sources. (1) Each owner or operator of an affected
ferromanganese and silicomanganese production facility must prepare, and
at all times operate according to, a fugitive dust control plan that
describes in detail the measures that will be put in place to control
fugitive dust emissions from the individual fugitive dust sources at the
facility.
(2) The owner or operator must submit a copy of the fugitive dust
control plan to the designated permitting authority on or before the
applicable compliance date for the affected source as specified in Sec.
63.1650(e). The requirement for the owner or operator to operate the
facility according to a written fugitive dust control plan must be
incorporated in the operating permit for the facility that is issued by
the designated permitting authority under part 70 of this chapter.
(3) The owner or operator may use existing manuals that describe the
measures in place to control fugitive dust sources required as part of a
State implementation plan or other federally enforceable requirement for
particulate matter to satisfy the requirements of paragraph (a)(1) of
this section.
[[Page 193]]
(b) Baghouses equipped with bag leak detection systems. The owner or
operator of a new or reconstructed submerged arc furnace must install
and continuously operate a bag leak detection system if the furnace's
primary and/or tapping emissions are ducted to a negative pressure
baghouse or to a positive pressure baghouse equipped with a stack. The
owner or operator must maintain and operate each baghouse such that the
following conditions are met:
(1) The alarm on the system does not sound for more than 5 percent
of the total operating time in a 6-month reporting period.
(2) A record is made of the date and time of each alarm and
procedures to determine the cause of the alarm are initiated within 1
hour of the alarm according to the plan for corrective action required
under Sec. 63.1657(a)(7).
Sec. 63.1655 Maintenance requirements.
(a) The owner or operator of an affected source must comply with the
requirements of Sec. 63.6(e) of subpart A.
(b)(1) The owner or operator must develop and implement a written
maintenance plan for each air pollution control device associated with
submerged arc furnaces, metal oxygen refining processes, and crushing
and screening operations subject to the provisions of this part. The
owner or operator must keep the maintenance plan on record and available
for the Administrator's inspection for the life of the air pollution
control device or until the affected source is no longer subject to the
provisions of this part.
(2) To satisfy the requirement to develop maintenance plans, the
owner or operator may use the affected source's standard operating
procedures (SOP) manual or other plan, provided the alternative plan
meets the requirements of this paragraph and is made available for
inspection when requested by the Administrator.
(c) The procedures specified in the maintenance plan must include a
preventive maintenance schedule that is consistent with good air
pollution control practices for minimizing emissions and, for baghouses,
ensure that the requirements specified in Sec. 63.1657(a) are met.
(d) The owner or operator must perform monthly inspections of the
equipment that is important to the performance of the furnace capture
system. This inspection must include an examination of the physical
condition of the equipment, suitable for detecting holes in ductwork or
hoods, flow constrictions in ductwork due to dents or accumulated dust,
and operational status of flow rate controllers (pressure sensors,
dampers, damper switches, etc.). Any deficiencies must be recorded and
proper maintenance and repairs performed.
Sec. 63.1656 Performance testing, test methods, and compliance
demonstrations.
(a) Performance testing. (1) All performance tests must be conducted
according to the requirements in Sec. 63.7 of subpart A.
(2) Each performance test must consist of three separate and
complete runs using the applicable test methods.
(3) Each run must be conducted under conditions that are
representative of normal process operations.
(4) Performance tests conducted on air pollution control devices
serving submerged arc furnaces must be conducted such that at least one
tapping period, or at least 20 minutes of a tapping period, whichever is
less, is included in at least two of the three runs. The sampling time
for each run must be at least as long as three times the average tapping
period of the tested furnace, but no less than 60 minutes.
(5) The sample volume for each run must be at least 0.9 dscm (30
dscf).
(b) Test methods. The following test methods in Appendix A of part
60 of this chapter must be used to determine compliance with the
emission standards.
(1) Method 1 to select the sampling port location and the number of
traverse points.
(2) Method 2 to determine the volumetric flow rate of the stack gas.
(3) Method 3 to determine the dry molecular weight of the stack gas.
(4) Method 4 to determine the moisture content of the stack gas.
(5) Method 5 to determine the particulate matter concentration of
the stack gas for negative pressure
[[Page 194]]
baghouses and positive pressure baghouses with stacks.
(6) Method 5D to determine particulate matter concentration and
volumetric flow rate of the stack gas for positive pressure baghouses
without stacks.
(7) Method 9 to determine opacity.
(8) The owner or operator may use equivalent alternative measurement
methods approved by the Administrator following the procedures described
in Sec. 63.7(f) of subpart A.
(c) Compliance demonstration with the emission standards. (1) The
owner or operator must conduct an initial performance test for air
pollution control devices or vent stacks subject to Sec. 63.1652(a)
through (e) to demonstrate compliance with the applicable emission
standards.
(2) The owner or operator must conduct annual performance tests for
the air pollution control devices and vent stacks associated with the
submerged arc furnaces, with the exception of any air pollution control
devices that serve tapping emissions combined with non-furnace
emissions, such as the MOR process or equipment associated with crushing
and screening. Also excluded are air pollution control devices that
serve dedicated non-furnace emissions, such as the MOR process or
equipment associated with crushing and screening. The results of these
annual tests will be used to demonstrate compliance with the emission
standards in Sec. 63.1652(a) through (e), as applicable.
(3) Following development, and approval, if required, of the site-
specific test plan, the owner or operator must conduct a performance
test for each air pollution control device or vent stack to measure
particulate matter and determine compliance with the applicable
standard.
(i) An owner or operator of sources subject to the particulate
matter concentration standards in Sec. 63.1652(a)(2), (d), or (e), must
determine compliance as follows:
(A) Determine the particulate matter concentration using Method 5 or
5D, as applicable.
(B) Compliance is demonstrated if the average concentration for the
three runs comprising the performance test does not exceed the standard.
(ii) An owner or operator of sources subject to the particulate mass
rate standards in Sec. 63.1652(b) or (c) must determine compliance as
follows:
(A) Determine the particulate matter concentration and volumetric
flow rate using Method 5 or 5D, as applicable.
(B) Compute the mass rate (EM) of particulate matter for
each run using the following equation:
[GRAPHIC] [TIFF OMITTED] TR20MY99.000
Where:
EM = mass rate of particulate matter, kg/hr (lb/hr).
N = total number of exhaust streams at which emissions are quantified.
Csi = concentration of particulate matter from exhaust stream
``i'', mg/dscm (gr/dscf).
Qsdi = volumetric flow rate of effluent gas from exhaust
stream ``i'', dscm/hr (dscf/hr)
K = conversion factor, 1 x 10\6\ mg/kg (7,000 gr/lb).
(C) Compliance is demonstrated if the average of the mass rates for
the three runs comprising the performance test does not exceed the
standard.
(iii) An owner or operator of sources subject to the particulate
matter process-weighted rate standard in Sec. 63.1652(a)(1) must
determine compliance as follows:
(A) Determine particulate matter concentration and volumetric flow
rate using Method 5 or 5D, as applicable.
(B) Compute the process-weighted mass rate (EP) of
particulate matter for each run using the following equation:
[GRAPHIC] [TIFF OMITTED] TR20MY99.001
Where:
EP = process-weighted mass rate of particulate matter, kg/hr/
MW (lb/hr/MW).
N = total number of exhaust streams at which emissions are quantified.
Csi = concentration of particulate matter from exhaust stream
``i'', mg/dscm (gr/dscf)
Qsdi = volumetric flow rate of effluent gas from exhaust
stream ``i'', dscm/hr (dscf/hr)
P = Average furnace power input, MW
K = conversion factor, 1 x 10\6\ mg/kg (7,000 gr/lb).
(C) Compliance is demonstrated if the average process-weighted mass
rate
[[Page 195]]
for the three runs comprising the performance test does not exceed the
standard.
(4) If a venturi scrubber is used to comply with the emission
standards, the owner or operator must establish as a site-specific
operating parameter the lowest average pressure drop on any individual
complying run in the three runs constituting any compliant test. The
pressure drop must be monitored at least every 5 minutes during the test
and hourly averages recorded.
(i) [Reserved]
(ii) The owner or operator may augment the data obtained under
paragraph (a)(4) of this section by conducting multiple performance
tests to establish a range of compliant operating parameter values. The
lowest value of this range would be selected as the operating parameter
monitoring value. The use of historic compliance data may be used to
establish the compliant operating parameter value if the previous values
were recorded during performance tests using the same test methods
specified in this subpart and established as required in paragraph
(a)(4) of this section.
(d) Compliance demonstration with opacity standards. (1)(i) The
owner or operator subject to Sec. 63.1653 must conduct initial opacity
observations of the shop building to demonstrate compliance with the
applicable opacity standards according to Sec. 63.6(h)(5), which
addresses the conduct of opacity or visible emission observations.
(ii) In conducting the opacity observations of the shop building,
the observer must limit his or her field of view to the area of the shop
building roof monitor that corresponds to the placement of the affected
submerged arc furnaces.
(iii) The owner or operator must conduct the opacity observations
according to EPA Method 9 of 40 CFR part 60, appendix A, for a minimum
of 60 minutes.
(2)(i) When demonstrating initial compliance with the shop building
opacity standard, as required by paragraph (d)(1) of this section, the
owner or operator must simultaneously establish parameter values for one
of the following: the control system fan motor amperes and all capture
system damper positions, the total volumetric flow rate to the air
pollution control device and all capture system damper positions, or
volumetric flow rate through each separately ducted hood that comprises
the capture system.
(ii) The owner or operator may petition the Administrator to
reestablish these parameters whenever he or she can demonstrate to the
Administrator's satisfaction that the submerged arc furnace operating
conditions upon which the parameters were previously established are no
longer applicable. The values of these parameters determined during the
most recent demonstration of compliance must be maintained at the
appropriate level for each applicable period.
(3) The owner or operator must demonstrate continuing compliance
with the opacity standards by following the monitoring requirements
specified in Sec. 63.1657(c) and the reporting and recordkeeping
requirements specified in Sec. Sec. 63.1659(b)(4) and 63.1660(b).
(e) Compliance demonstration with the operational and work practice
standards--(1) Fugitive dust sources. Failure to have a fugitive dust
control plan or failure to report deviations from the plan and take
necessary corrective action would be a violation of the general duty to
ensure that fugitive dust sources are operated and maintained in a
manner consistent with good air pollution control practices for
minimizing emissions per Sec. 63.6(e)(1)(i) of subpart A.
(2) Baghouses equipped with bag leak detection systems. The owner or
operator demonstrates compliance with the bag leak detection system
requirements by submitting reports as required by Sec. 63.1659(b)(5)
showing that the alarm on the system does not sound for more than 5
percent of the total operating time in a 6-month period. Calculate the
percentage of total operating time the alarm on the bag leak detection
system sounds as follows:
(i) Do not include alarms that occur due solely to a malfunction of
the bag leak detection system in the calculation.
(ii) Do not include alarms that occur during startup, shutdown, and
malfunction in the calculation if the condition is described in the
startup, shutdown, and malfunction plan and the
[[Page 196]]
owner or operator operates the source during such periods in accordance
with Sec. 63.6(e)(1).
(iii) Count 1 hour of alarm time for each alarm where the owner or
operator initiates procedures to determine the cause within 1 hour of
the alarm.
(iv) Count the actual time it takes the owner or operator to
initiate procedures to determine the cause of the alarm for each alarm
where the owner or operator does not initiate procedures to determine
the cause within 1 hour of the alarm.
(v) Calculate the percentage of time the alarm on the bag leak
detection system sounds as the ratio of the sum of alarm times to the
total operating time multiplied by 100.
[64 FR 27458, May 20, 1999, as amended at 71 FR 20462, Apr. 20, 2006]
Sec. 63.1657 Monitoring requirements.
(a) Baghouses. (1) For the baghouses serving the submerged arc
furnaces, the metal oxygen refining process, and crushing and screening
operations, the owner or operator must observe on a daily basis for the
presence of any visible emissions.
(2) In addition to the daily visible emissions observation, the
owner or operator must conduct the following activities:
(i) Daily monitoring of pressure drop across each baghouse cell, or
across the baghouse if it is not possible to monitor each cell
individually, to ensure the pressure drop is within the normal operating
range identified in the baghouse maintenance plan.
(ii) Weekly confirmation that dust is being removed from hoppers
through visual inspection, or equivalent means of ensuring the proper
functioning of removal mechanisms.
(iii) Daily check of compressed air supply for pulse-jet baghouses.
(iv) An appropriate methodology for monitoring cleaning cycles to
ensure proper operation.
(v) Monthly check of bag cleaning mechanisms for proper functioning
through visual inspection or equivalent means.
(vi) Quarterly visual check of bag tension on reverse air and
shaker-type baghouses to ensure that the bags are not kinked (kneed or
bent) or laying on their sides. Such checks are not required for shaker-
type baghouses using self-tensioning (spring loaded) devices.
(vii) Quarterly confirmation of the physical integrity of the
baghouse structure through visual inspection of the baghouse interior
for air leaks.
(viii) Semiannual inspection of fans for wear, material buildup, and
corrosion through visual inspection, vibration detectors, or equivalent
means.
(3) In addition to meeting the requirements of paragraphs (a)(1) and
(a)(2) of this section, the owner or operator of a new or reconstructed
submerged arc furnace must install and continuously operate a bag leak
detection system if the furnace primary and/or tapping emissions are
ducted to a negative pressure baghouse or to a positive pressure
baghouse equipped with a stack. The bag leak detection system must meet
the following requirements:
(i) The bag leak detection system must be certified by the
manufacturer to be capable of detecting particulate matter emissions at
concentrations of 10 milligrams per actual cubic meter (0.0044 grains
per actual cubic foot) or less.
(ii) The bag leak detection system sensor must provide output of
relative particulate matter loadings, and the owner or operator must
continuously record the output from the bag leak detection system.
(iii) The bag leak detection system must be equipped with an alarm
system that will sound when an increase in relative particulate loadings
is detected over a preset level. The alarm must be located where it can
be heard by the appropriate plant personnel.
(iv) Each bag leak detection system that works based on the
triboelectric effect must be installed, calibrated, operated, and
maintained consistent with the U.S. Environmental Protection Agency
guidance document ``Fabric Filter Bag Leak Detection Guidance'' (EPA-
454/R-98-015). Other bag leak detection systems must be installed,
calibrated, and maintained consistent with the manufacturer's written
specifications and recommendations.
[[Page 197]]
(v) The initial adjustment of the system must, at a minimum, consist
of establishing the baseline output by adjusting the sensitivity (range)
and the averaging period of the device, and establishing the alarm set
points and the alarm delay time.
(vi) Following initial adjustment, the owner or operator must not
adjust the sensitivity or range, averaging period, alarm set points, or
alarm delay time, except as detailed in the maintenance plan required
under Sec. 63.1655(b). In no event must the sensitivity be increased by
more than 100 percent or decreased more than 50 percent over a 365-day
period unless a responsible official certifies the baghouse has been
inspected and found to be in good operating condition.
(vii) Where multiple detectors are required, the system's
instrumentation and alarm may be shared among detectors.
(4) As part of the maintenance plan required by Sec. 63.1655(b),
the owner or operator must develop and implement corrective action
procedures to be followed in the case of a bag leak detection system
alarm (for baghouses equipped with such a system), the observation of
visible emissions from the baghouse, or the indication through the
periodic baghouse system inspections that the system is not operating
properly. The owner or operator must initiate corrective action as soon
as practicable after the occurrence of the observation or event
indicating a problem.
(5) The corrective action plan must include procedures used to
determine the cause of an alarm or other indications of problems as well
as actions to minimize emissions. These actions may include the
following:
(i) Inspecting the baghouse for air leaks, torn or broken bags or
filter media, or any other condition that may cause an increase in
emissions.
(ii) Sealing off defective bags or filter media.
(iii) Replacing defective bags or filter media, or otherwise
repairing the control device.
(iv) Sealing off a defective baghouse compartment.
(v) Cleaning the bag leak detection system probe, or otherwise
repairing the bag leak detection system.
(vi) Shutting down the process producing the particulate matter
emissions.
(6) Failure to monitor or failure to take corrective action under
the requirements of paragraph (a) of this section would be a violation
of the general duty to operate in a manner consistent with good air
pollution control practices that minimizes emissions per Sec.
63.6(e)(1)(i) of subpart A.
(b) Venturi scrubbers. (1) The owner or operator must monitor the
pressure drop across the venturi at least every 5 minutes and record the
average hourly pressure drop. Measurement of an average hourly pressure
drop less than the pressure drop operating parameter limit established
during a successful compliance demonstration would be a violation of the
applicable emission standard, unless the excursion in the pressure drop
is due to a malfunction.
(2) As part of the maintenance plan required by Sec. 63.1655(b),
the owner or operator must develop and implement corrective action
procedures to be followed in the case of a violation of the pressure
drop requirement. The owner or operator must initiate corrective action
as soon as practicable after the excursion.
(3) Failure to monitor or failure to take corrective action under
the requirements of paragraph (b) of this section is a violation of the
general duty to operate in a manner consistent with good air pollution
control practices that minimizes emissions per Sec. 63.6(e)(1)(i).
(c) Shop opacity. The owner or operator subject to the opacity
standards in Sec. 63.1653 must comply with one of the monitoring
options in paragraphs (c)(1), (c)(2) or (c)(3) of this section. The
selected option must be consistent with that selected during the initial
performance test described in Sec. 63.1656(d)(2). Alternatively, the
owner or operator may use the provisions of Sec. 63.8(f) to request
approval to use an alternative monitoring method.
(1) The owner or operator must check and record the control system
fan motor amperes and capture system damper positions once per shift.
[[Page 198]]
(2) The owner or operator must install, calibrate, and maintain a
monitoring device that continuously records the volumetric flow rate
through each separately ducted hood.
(3) The owner or operator must install, calibrate, and maintain a
monitoring device that continuously records the volumetric flow rate at
the inlet of the air pollution control device and must check and record
the capture system damper positions once per shift.
(4) The flow rate monitoring devices must meet the following
requirements:
(i) Be installed in an appropriate location in the exhaust duct such
that reproducible flow rate monitoring will result.
(ii) Have an accuracy 10 percent over its
normal operating range and be calibrated according to the manufacturer's
instructions.
(5) The Administrator may require the owner or operator to
demonstrate the accuracy of the monitoring device(s) relative to Methods
1 and 2 of appendix A of part 60 of this chapter.
(6) Failure to maintain the appropriate capture system parameters
(fan motor amperes, flow rate, and/or damper positions) establishes the
need to initiate corrective action as soon as practicable after the
monitoring excursion in order to minimize excess emissions.
(7) Failure to monitor or failure to take corrective action under
the requirements of paragraph (c) of this section is a violation of the
general duty to operate in a manner consistent with good air pollution
control practices that minimizes emissions per Sec. 63.6(e)(1)(i).
Sec. 63.1658 Notification requirements.
(a) As required by Sec. 63.9(b) of subpart A, unless otherwise
specified in this subpart, the owner or operator must submit the
following written notifications to the Administrator:
(1) The owner or operator of an area source that subsequently
becomes subject to the requirements of the standard must provide
notification to the applicable permitting authority as required by Sec.
63.9(b)(1).
(2) As required by Sec. 63.9(b)(2), the owner or operator of an
affected source that has an initial startup before the effective date of
the standard must notify the Administrator that the source is subject to
the requirements of the standard. The notification must be submitted no
later than 120 calendar days after May 20, 1999 (or within 120 calendar
days after the source becomes subject to this standard) and must contain
the information specified in Sec. 63.9(b)(2)(i) through (b)(2)(v).
(3) As required by Sec. 63.9(b)(3), the owner or operator of a new
or reconstructed affected source, or a source that has been
reconstructed such that it is an affected source, that has an initial
startup after the effective date and for which an application for
approval of construction or reconstruction is not required under Sec.
63.5(d), must notify the Administrator in writing that the source is
subject to the standards no later than 120 days after initial startup.
The notification must contain the information specified in Sec.
63.9(b)(2)(i) through (b)(2)(v), delivered or postmarked with the
notification required in Sec. 63.9(b)(5).
(4) As required by Sec. 63.9(b)(4), the owner or operator of a new
or reconstructed major affected source that has an initial startup after
the effective date of this standard and for which an application for
approval of construction or reconstruction is required under Sec.
63.5(d) must provide the information specified in Sec. 63.9(b)(4)(i)
through (b)(4)(v).
(5) As required by Sec. 63.9(b)(5), the owner or operator who,
after the effective date of this standard, intends to construct a new
affected source or reconstruct an affected source subject to this
standard, or reconstruct a source such that it becomes an affected
source subject to this standard, must notify the Administrator, in
writing, of the intended construction or reconstruction.
(b) Request for extension of compliance. As required by Sec.
63.9(c), if the owner or operator of an affected source cannot comply
with this standard by the applicable compliance date for that source, or
if the owner or operator has installed BACT or technology to meet LAER
consistent with Sec. 63.6(i)(5), he or she may submit to the
Administrator (or the State with an approved permit program) a request
for an extension of
[[Page 199]]
compliance as specified in Sec. 63.6(i)(4) through (i)(6).
(c) Notification that source is subject to special compliance
requirements. As required by Sec. 63.9(d), an owner or operator of a
new source that is subject to special compliance requirements as
specified in Sec. 63.6(b)(3) and (b)(4) must notify the Administrator
of his or her compliance obligations no later than the notification
dates established in Sec. 63.9(b) for new sources that are not subject
to the special provisions.
(d) Notification of performance test. As required by Sec. 63.9(e),
the owner or operator of an affected source must notify the
Administrator in writing of his or her intention to conduct a
performance test at least 30 calendar days before the performance test
is scheduled to begin to allow the Administrator to review and approve
the site-specific test plan required under Sec. 63.7(c) and to have an
observer present during the test.
(e) Notification of opacity and visible emission observations. As
required by Sec. 63.9(f), the owner or operator of an affected source
must notify the Administrator in writing of the anticipated date for
conducting the opacity or visible emission observations specified in
Sec. 63.6(h)(5). The notification must be submitted with the
notification of the performance test date, as specified in paragraph (d)
of this section, or if visibility or other conditions prevent the
opacity or visible emission observations from being conducted
concurrently with the initial performance test required under Sec.
63.7, the owner or operator must deliver or postmark the notification
not less than 30 days before the opacity or visible emission
observations are scheduled to take place.
(f) Notification of compliance status. The owner or operator of an
affected source must submit a notification of compliance status as
required by Sec. 63.9(h). The notification must be sent before the
close of business on the 60th day following completion of the relevant
compliance demonstration.
Sec. 63.1659 Reporting requirements.
(a) General reporting requirements. The owner or operator of a
ferromanganese and silicomanganese production facility must comply with
all of the reporting requirements under Sec. 63.10 of subpart A, unless
otherwise specified in this subpart.
(1) Frequency of reports. As provided by Sec. 63.10(a)(5), if the
owner or operator is required to submit periodic reports to a State on
an established time line, he or she may change the dates by which
periodic reports submitted under this part may be submitted (without
changing the frequency of reporting) to be consistent with the State's
schedule by mutual agreement between the owner or operator and the
State. This provision may be applied at any point after the source's
compliance date.
(2) Reporting results of performance tests. As required by Sec.
63.10(d)(2), the owner or operator of an affected source must report the
results of the initial performance test as part of the notification of
compliance status required in Sec. 63.1658(f).
(3) [Reserved]
(4) Periodic startup, shutdown, and malfunction reports. (i) As
required by Sec. 63.10(d)(5)(i), if actions taken by an owner or
operator during a startup, shutdown, or malfunction of an affected
source (including actions taken to correct a malfunction) are consistent
with the procedures specified in the startup, shutdown, and malfunction
plan, the owner or operator must state such information in a semiannual
report. The report, to be certified by the owner or operator or other
responsible official, must be submitted semiannually and delivered or
postmarked by the 30th day following the end of each calendar half; and
(ii) Any time an action taken by an owner or operator during a
startup, shutdown, or malfunction (including actions taken to correct a
malfunction) is not consistent with the procedures in the startup,
shutdown, and malfunction plan, the owner or operator must comply with
all requirements of Sec. 63.10(d)(5)(ii).
(b) Specific reporting requirements. In addition to the information
required under Sec. 63.10, reports required under paragraph (a) of this
section must include the information specified in paragraphs (b)(1)
through (b)(5) of this section. As allowed by Sec. 63.10(a)(3), if any
State requires a report that contains all of the information required in
a report listed in this section, an owner or
[[Page 200]]
operator may send the Administrator a copy of the report sent to the
State to satisfy the requirements of this section for that report.
(1) Air pollution control devices. The owner or operator must submit
reports that summarize the records maintained as part of the practices
described in the maintenance plan for air pollution control devices
required under Sec. 63.1655(b), including an explanation of the periods
when the procedures were not followed and the corrective actions taken.
(2) Venturi scrubbers. In addition to the information required to be
submitted in paragraph (b)(1) of this section, the owner or operator
must submit reports that identify the periods when the average hourly
pressure drop of venturi scrubbers used to control particulate emissions
dropped below the levels established in Sec. 63.1656(c)(4), and an
explanation of the corrective actions taken.
(3) Fugitive dust. The owner or operator must submit reports that
explain the periods when the procedures outlined in the fugitive dust
control plan pursuant to Sec. 63.1654(a) were not followed and the
corrective actions taken.
(4) Capture system. The owner or operator must submit reports that
summarize the monitoring parameter excursions measured pursuant to Sec.
63.1657(c) and the corrective actions taken.
(5) Bag leak detection system. The owner or operator must submit
reports including the following information:
(i) Records of all alarms.
(ii) Description of the actions taken following each bag leak
detection system alarm.
(iii) Calculation of the percent of time the alarm on the bag leak
detection system sounded during the reporting period.
(6) Frequency of reports. (i) The owner or operator must submit
reports pursuant to Sec. 63.10(e)(3) that are associated with excess
emissions events such as the excursion of the scrubber pressure drop
limit per paragraph (b)(2) of this section. These reports are to be
submitted on a quarterly basis, unless the owner or operator can satisfy
the requirements in Sec. 63.10(e)(3) to reduce the frequency to a
semiannual basis.
(ii) All other reports specified in paragraphs (b)(1) through (b)(5)
of this section must be submitted semiannually.
Sec. 63.1660 Recordkeeping requirements.
(a) General recordkeeping requirements. (1) The owner or operator of
a ferromanganese and silicomanganese production facility must comply
with all of the recordkeeping requirements under Sec. 63.10.
(2) As required by Sec. 63.10(b)(2), the owner or operator must
maintain records for 5 years from the date of each record of:
(i) The occurrence and duration of each startup, shutdown, or
malfunction of operation (i.e., process equipment and control devices);
(ii) The occurrence and duration of each malfunction of the source
or air pollution control equipment;
(iii) All maintenance performed on the air pollution control
equipment;
(iv) Actions taken during periods of startup, shutdown, and
malfunction (including corrective actions to restore malfunctioning
process and air pollution control equipment to its normal or usual
manner of operation) when such actions are different from the procedures
specified in the startup, shutdown, and malfunction plan;
(v) All information necessary to demonstrate conformance with the
startup, shutdown, and malfunction plan when all actions taken during
periods of startup, shutdown, and malfunction (including corrective
actions) are consistent with the procedures specified in such plan. This
information can be recorded in a checklist or similar form (see Sec.
63.10(b)(2)(v));
(vi) All required measurements needed to demonstrate compliance with
the standard and to support data that the source is required to report,
including, but not limited to, performance test measurements (including
initial and any subsequent performance tests) and measurements as may be
necessary to determine the conditions of the initial test or subsequent
tests;
(vii) All results of initial or subsequent performance tests;
(viii) If the owner or operator has been granted a waiver from
recordkeeping or reporting requirements under Sec. 63.10(f), any
information demonstrating whether a source is meeting
[[Page 201]]
the requirements for a waiver of recordkeeping or reporting
requirements;
(ix) If the owner or operator has been granted a waiver from the
initial performance test under Sec. 63.7(h), a copy of the full request
and the Administrator's approval or disapproval;
(x) All documentation supporting initial notifications and
notifications of compliance status required by Sec. 63.9; and
(xi) As required by Sec. 63.10(b)(3), records of any applicability
determination, including supporting analyses.
(b) Specific recordkeeping requirements. (1) In addition to the
general records required by paragraph (a) of this section, the owner or
operator must maintain records for 5 years from the date of each record
of:
(i) Records of pressure drop across the venturi if a venturi
scrubber is used.
(ii) Records of manufacturer certification that monitoring devices
are accurate to within 5 percent (unless otherwise specified in this
subpart) and of calibrations performed at the manufacturer's recommended
frequency, or at a frequency consistent with good engineering practice,
or as experience dictates.
(iii) Records of bag leak detection system output.
(iv) An identification of the date and time of all bag leak
detection system alarms, the time that procedures to determine the cause
of the alarm were initiated, the cause of the alarm, an explanation of
the actions taken, and the date and time the alarm was corrected.
(v) Copy of the written maintenance plan for each air pollution
control device.
(vi) Copy of the fugitive dust control plan.
(vii) Records of each maintenance inspection and repair,
replacement, or other corrective action.
(2) All records for the most recent 2 years of operation must be
maintained on site. Records for the previous 3 years may be maintained
off site.
Sec. 63.1661 Implementation and enforcement.
(a) This subpart can be implemented and enforced by the U.S. EPA, or
a delegated authority such as the applicable State, local, or Tribal
agency. If the U.S. EPA Administrator has delegated authority to a
State, local, or Tribal agency, then that agency, in addition to the
U.S. EPA, has the authority to implement and enforce this subpart.
Contact the applicable U.S. EPA Regional Office to find out if this
subpart is delegated to a State, local, or Tribal agency.
(b) In delegating implementation and enforcement authority of this
subpart to a State, local, or Tribal agency under subpart E of this
part, the authorities contained in paragraph (c) of this section are
retained by the Administrator of U.S. EPA and cannot be transferred to
the State, local, or Tribal agency.
(c) The authorities that cannot be delegated to State, local, or
Tribal agencies are as specified in paragraphs (c)(1) through (4) of
this section.
(1) Approval of alternatives to requirements in Sec. Sec. 63.1650
and 63.1652 through 63.1654.
(2) Approval of major alternatives to test methods under Sec.
63.7(e)(2)(ii) and (f), as defined in Sec. 63.90, and as required in
this subpart.
(3) Approval of major alternatives to monitoring under Sec.
63.8(f), as defined in Sec. 63.90, and as required in this subpart.
(4) Approval of major alternatives to recordkeeping and reporting
under Sec. 63.10(f), as defined in Sec. 63.90, and as required in this
subpart.
[68 FR 37360, June 23, 2003]
Sec. Sec. 63.1662-63.1679 [Reserved]
Subpart AAAA_National Emission Standards for Hazardous Air Pollutants:
Municipal Solid Waste Landfills
Source: 68 FR 2238, Jan. 16, 2003, unless otherwise noted.
What This Subpart Covers
Sec. 63.1930 What is the purpose of this subpart?
This subpart establishes national emission standards for hazardous
air pollutants for existing and new municipal solid waste (MSW)
landfills. This subpart requires all landfills described in Sec.
63.1935 to meet the requirements of
[[Page 202]]
40 CFR part 60, subpart Cc or WWW and requires timely control of
bioreactors. This subpart also requires such landfills to meet the
startup, shutdown, and malfunction (SSM) requirements of the general
provisions of this part and provides that compliance with the operating
conditions shall be demonstrated by parameter monitoring results that
are within the specified ranges. It also includes additional reporting
requirements.
Sec. 63.1935 Am I subject to this subpart?
You are subject to this subpart if you meet the criteria in
paragraph (a) or (b) of this section.
(a) You are subject to this subpart if you own or operate a MSW
landfill that has accepted waste since November 8, 1987 or has
additional capacity for waste deposition and meets any one of the three
criteria in paragraphs (a)(1) through (3) of this section:
(1) Your MSW landfill is a major source as defined in 40 CFR 63.2 of
subpart A.
(2) Your MSW landfill is collocated with a major source as defined
in 40 CFR 63.2 of subpart A.
(3) Your MSW landfill is an area source landfill that has a design
capacity equal to or greater than 2.5 million megagrams (Mg) and 2.5
million cubic meters (m \3\) and has estimated uncontrolled emissions
equal to or greater than 50 megagrams per year (Mg/yr) NMOC as
calculated according to Sec. 60.754(a) of the MSW landfills new source
performance standards in 40 CFR part 60, subpart WWW, the Federal plan,
or an EPA approved and effective State or tribal plan that applies to
your landfill.
(b) You are subject to this subpart if you own or operate a MSW
landfill that has accepted waste since November 8, 1987 or has
additional capacity for waste deposition, that includes a bioreactor, as
defined in Sec. 63.1990, and that meets any one of the criteria in
paragraphs (b)(1) through (3) of this section:
(1) Your MSW landfill is a major source as defined in 40 CFR 63.2 of
subpart A.
(2) Your MSW landfill is collocated with a major source as defined
in 40 CFR 63.2 of subpart A.
(3) Your MSW landfill is an area source landfill that has a design
capacity equal to our greater than 2.5 million Mg and 2.5 million m\3\
and that is not permanently closed as of January 16, 2003.
Sec. 63.1940 What is the affected source of this subpart?
(a) An affected source of this subpart is a MSW landfill, as defined
in Sec. 63.1990, that meets the criteria in Sec. 63.1935(a) or (b).
The affected source includes the entire disposal facility in a
contiguous geographic space where household waste is placed in or on
land, including any portion of the MSW landfill operated as a
bioreactor.
(b) A new affected source of this subpart is an affected source that
commenced construction or reconstruction after November 7, 2000. An
affected source is reconstructed if it meets the definition of
reconstruction in 40 CFR 63.2 of subpart A.
(c) An affected source of this subpart is existing if it is not new.
Sec. 63.1945 When do I have to comply with this subpart?
(a) If your landfill is a new affected source, you must comply with
this subpart by January 16, 2003 or at the time you begin operating,
whichever is last.
(b) If your landfill is an existing affected source, you must comply
with this subpart by January 16, 2004.
(c) If your landfill is a new affected source and is a major source
or is collocated with a major source, you must comply with the
requirements in Sec. Sec. 63.1955(b) and 63.1960 through 63.1980 by the
date your landfill is required to install a collection and control
system by 40 CFR 60.752(b)(2) of subpart WWW.
(d) If your landfill is an existing affected source and is a major
source or is collocated with a major source, you must comply with the
requirements in Sec. Sec. 63.1955(b) and 63.1960 through 63.1980 by the
date your landfill is required to install a collection and control
system by 40 CFR 60.752(b)(2) of subpart WWW, the Federal plan, or EPA
approved and effective State or tribal plan that applies to your
landfill or by January 13, 2004, whichever occurs later.
(e) If your landfill is a new affected source and is an area source
meeting
[[Page 203]]
the criteria in Sec. 63.1935(a)(3), you must comply with the
requirements of Sec. Sec. 63.1955(b) and 63.1960 through 63.1980 by the
date your landfill is required to install a collection and control
system by 40 CFR 60.752(b)(2) of subpart WWW.
(f) If your landfill is an existing affected source and is an area
source meeting the criteria in Sec. 63.1935(a)(3), you must comply with
the requirements in Sec. Sec. 63.1955(b) and 63.1960 through 63.1980 by
the date your landfill is required to install a collection and control
system by 40 CFR 60.752(b)(2) of subpart WWW, the Federal plan, or EPA
approved and effective State or tribal plan that applies to your
landfill or by January 16, 2004, whichever occurs later.
Sec. 63.1947 When do I have to comply with this subpart if I own or
operate a bioreactor?
You must comply with this subpart by the dates specified in Sec.
63.1945(a) or (b) of this subpart. If you own or operate a bioreactor
located at a landfill that is not permanently closed as of January 16,
2003 and has a design capacity equal to or greater than 2.5 million Mg
and 2.5 million m\3\, then you must install and operate a collection and
control system that meets the criteria in 40 CFR 60.752(b)(2)(v) of part
60, subpart WWW, the Federal plan, or EPA approved and effective State
plan according to the schedule specified in paragraph (a), (b), or (c)
of this section.
(a) If your bioreactor is at a new affected source, then you must
meet the requirements in paragraphs (a)(1) and (2) of this section:
(1) Install the gas collection and control system for the bioreactor
before initiating liquids addition.
(2) Begin operating the gas collection and control system within 180
days after initiating liquids addition or within 180 days after
achieving a moisture content of 40 percent by weight, whichever is
later. If you choose to begin gas collection and control system
operation 180 days after achieving a 40 percent moisture content instead
of 180 days after liquids addition, use the procedures in Sec.
63.1980(g) and (h) to determine when the bioreactor moisture content
reaches 40 percent.
(b) If your bioreactor is at an existing affected source, then you
must install and begin operating the gas collection and control system
for the bioreactor by January 17, 2006 or by the date your bioreactor is
required to install a gas collection and control system under 40 CFR
part 60, subpart WWW, the Federal plan, or EPA approved and effective
State plan or tribal plan that applies to your landfill, whichever is
earlier.
(c) If your bioreactor is at an existing affected source and you do
not initiate liquids addition to your bioreactor until later than
January 17, 2006, then you must meet the requirements in paragraphs
(c)(1) and (2) of this section:
(1) Install the gas collection and control system for the bioreactor
before initiating liquids addition.
(2) Begin operating the gas collection and control system within 180
days after initiating liquids addition or within 180 days after
achieving a moisture content of 40 percent by weight, whichever is
later. If you choose to begin gas collection and control system
operation 180 days after achieving a 40 percent moisture content instead
of 180 days after liquids addition, use the procedures in Sec.
63.1980(g) and (h) to determine when the bioreactor moisture content
reaches 40 percent.
Sec. 63.1950 When am I no longer required to comply with this subpart?
You are no longer required to comply with the requirements of this
subpart when you are no longer required to apply controls as specified
in 40 CFR 60.752(b)(2)(v) of subpart WWW, or the Federal plan or EPA
approved and effective State plan or tribal plan that implements 40 CFR
part 60, subpart Cc, whichever applies to your landfill.
Sec. 63.1952 When am I no longer required to comply with the
requirements of this subpart if I own or operate a bioreactor?
If you own or operate a landfill that includes a bioreactor, you are
no longer required to comply with the requirements of this subpart for
the bioreactor provided you meet the conditions of either paragraphs (a)
or (b).
(a) Your affected source meets the control system removal criteria
in 40
[[Page 204]]
CFR 60.752(b)(2)(v) of part 60, subpart WWW or the bioreactor meets the
criteria for a nonproductive area of the landfill in 40 CFR
60.759(a)(3)(ii) of part 60, subpart WWW.
(b) The bioreactor portion of the landfill is a closed landfill as
defined in 40 CFR 60.751, subpart WWW, you have permanently ceased
adding liquids to the bioreactor, and you have not added liquids to the
bioreactor for at least 1 year. A closure report for the bioreactor must
be submitted to the Administrator as provided in 40 CFR 60.757(d) of
subpart WWW.
(c) Compliance with the bioreactor control removal provisions in
this section constitutes compliance with 40 CFR part 60, subpart WWW or
the Federal plan, whichever applies to your bioreactor.
Standards
Sec. 63.1955 What requirements must I meet?
(a) You must fulfill one of the requirements in paragraph (a)(1) or
(2) of this section, whichever is applicable:
(1) Comply with the requirements of 40 CFR part 60, subpart WWW.
(2) Comply with the requirements of the Federal plan or EPA approved
and effective State plan or tribal plan that implements 40 CFR part 60,
subpart Cc.
(b) If you are required by 40 CFR 60.752(b)(2) of subpart WWW, the
Federal plan, or an EPA approved and effective State or tribal plan to
install a collection and control system, you must comply with the
requirements in Sec. Sec. 63.1960 through 63.1985 and with the general
provisions of this part specified in table 1 of this subpart.
(c) For approval of collection and control systems that include any
alternatives to the operational standards, test methods, procedures,
compliance measures, monitoring, recordkeeping or reporting provisions,
you must follow the procedures in 40 CFR 60.752(b)(2). If alternatives
have already been approved under 40 CFR part 60 subpart WWW or the
Federal plan, or EPA approved and effective State or tribal plan, these
alternatives can be used to comply with this subpart, except that all
affected sources must comply with the SSM requirements in Subpart A of
this part as specified in Table 1 of this subpart and all affected
sources must submit compliance reports every 6 months as specified in
Sec. 63.1980(a) and (b), including information on all deviations that
occurred during the 6-month reporting period. Deviations for continuous
emission monitors or numerical continuous parameter monitors must be
determined using a 3 hour monitoring block average.
(d) If you own or operate a bioreactor that is located at a MSW
landfill that is not permanently closed and has a design capacity equal
to or greater than 2.5 million Mg and 2.5 million m\3\, then you must
meet the requirements of paragraph (a) and the additional requirements
in paragraphs (d)(1) and (2) of this section.
(1) You must comply with the general provisions specified in Table 1
of this subpart and Sec. Sec. 63.1960 through 63.1985 starting on the
date you are required to install the gas collection and control system.
(2) You must extend the collection and control system into each new
cell or area of the bioreactor prior to initiating liquids addition in
that area, instead of the schedule in 40 CFR 60.752(b)(2)(ii)(A)(2).
General and Continuing Compliance Requirements
Sec. 63.1960 How is compliance determined?
Compliance is determined in the same way it is determined for 40 CFR
part 60, subpart WWW, including performance testing, monitoring of the
collection system, continuous parameter monitoring, and other credible
evidence. In addition, continuous parameter monitoring data, collected
under 40 CFR 60.756(b)(1), (c)(1), and (d) of subpart WWW, are used to
demonstrate compliance with the operating conditions for control
systems. If a deviation occurs, you have failed to meet the control
device operating conditions described in this subpart and have deviated
from the requirements of this subpart. Finally, you must develop a
written SSM plan according to the provisions in 40 CFR 63.6(e)(3). A
copy of the SSM plan must be maintained on site.
[[Page 205]]
Failure to write or maintain a copy of the SSM plan is a deviation from
the requirements of this subpart.
[68 FR 2238, Jan. 16, 2003, as amended at 71 FR 20462, Apr. 20, 2006]
Sec. 63.1965 What is a deviation?
A deviation is defined in Sec. 63.1990. For the purposes of the
landfill monitoring and SSM plan requirements, deviations include the
items in paragraphs (a) through (c) of this section.
(a) A deviation occurs when the control device operating parameter
boundaries described in 40 CFR 60.758(c)(1) of subpart WWW are exceeded.
(b) A deviation occurs when 1 hour or more of the hours during the
3-hour block averaging period does not constitute a valid hour of data.
A valid hour of data must have measured values for at least three 15-
minute monitoring periods within the hour.
(c) A deviation occurs when a SSM plan is not developed or
maintained on site.
[68 FR 2238, Jan. 16, 2003, as amended at 71 FR 20462, Apr. 20, 2006]
Sec. 63.1975 How do I calculate the 3-hour block average used to
demonstrate compliance?
Averages are calculated in the same way as they are calculated in 40
CFR part 60, subpart WWW, except that the data collected during the
events listed in paragraphs (a), (b), (c), and (d) of this section are
not to be included in any average computed under this subpart:
(a) Monitoring system breakdowns, repairs, calibration checks, and
zero (low-level) and high-level adjustments.
(b) Startups.
(c) Shutdowns.
(d) Malfunctions.
Notifications, Records, and Reports
Sec. 63.1980 What records and reports must I keep and submit?
(a) Keep records and reports as specified in 40 CFR part 60, subpart
WWW, or in the Federal plan, EPA approved State plan or tribal plan that
implements 40 CFR part 60, subpart Cc, whichever applies to your
landfill, with one exception: You must submit the annual report
described in 40 CFR 60.757(f) every 6 months.
(b) You must also keep records and reports as specified in the
general provisions of 40 CFR part 60 and this part as shown in Table 1
of this subpart. Applicable records in the general provisions include
items such as SSM plans and the SSM plan reports.
(c) For bioreactors at new affected sources you must submit the
initial semiannual compliance report and performance test results
described in 40 CFR 60.757(f) within 180 days after the date you are
required to begin operating the gas collection and control system by
Sec. 63.1947(a)(2) of this subpart.
(d) For bioreactors at existing affected sources, you must submit
the initial semiannual compliance report and performance test results
described in 40 CFR 60.757(f) within 180 days after the compliance date
specified in Sec. 63.1947(b) of this subpart, unless you have
previously submitted a compliance report for the bioreactor required by
40 CFR part 60, subpart WWW, the Federal plan, or an EPA approved and
effective State plan or tribal plan.
(e) For bioreactors that are located at existing affected sources,
but do not initiate liquids addition until later than the compliance
date in Sec. 63.1947(b) of this subpart, you must submit the initial
semiannual compliance report and performance tests results described in
40 CFR 60.757(f) within 180 days after the date you are required to
begin operating the gas collection and control system by Sec.
63.1947(c) of this subpart.
(f) If you must submit a semiannual compliance report for a
bioreactor as well as a semiannual compliance report for a conventional
portion of the same landfill, you may delay submittal of a subsequent
semiannual compliance report for the bioreactor according to paragraphs
(f)(1) through (3) of this section so that the reports may be submitted
on the same schedule.
(1) After submittal of your initial semiannual compliance report and
performance test results for the bioreactor, you may delay submittal of
the subsequent semiannual compliance report for the bioreactor until the
date the initial or subsequent semiannual compliance report is due for
the conventional portion of your landfill.
[[Page 206]]
(2) You may delay submittal of your subsequent semiannual compliance
report by no more than 12 months after the due date for submitting the
initial semiannual compliance report and performance test results
described in 40 CFR 60.757(f) for the bioreactor. The report shall cover
the time period since the previous semiannual report for the bioreactor,
which would be a period of at least 6 months and no more than 12 months.
(3) After the delayed semiannual report, all subsequent semiannual
reports for the bioreactor must be submitted every 6 months on the same
date the semiannual report for the conventional portion of the landfill
is due.
(g) If you add any liquids other than leachate in a controlled
fashion to the waste mass and do not comply with the bioreactor
requirements in Sec. Sec. 63.1947, 63.1955(c) and 63.1980(c) through
(f) of this subpart, you must keep a record of calculations showing that
the percent moisture by weight expected in the waste mass to which
liquid is added is less than 40 percent. The calculation must consider
the waste mass, moisture content of the incoming waste, mass of water
added to the waste including leachate recirculation and other liquids
addition and precipitation, and the mass of water removed through
leachate or other water losses. Moisture level sampling or mass balances
calculations can be used. You must document the calculations and the
basis of any assumptions. Keep the record of the calculations until you
cease liquids addition.
(h) If you calculate moisture content to establish the date your
bioreactor is required to begin operating the collection and control
system under Sec. 63.1947(a)(2) or (c)(2), keep a record of the
calculations including the information specified in paragraph (g) of
this section for 5 years. Within 90 days after the bioreactor achieves
40 percent moisture content, report the results of the calculation, the
date the bioreactor achieved 40 percent moisture content by weight, and
the date you plan to begin collection and control system operation.
Other Requirements and Information
Sec. 63.1985 Who enforces this subpart?
(a) This subpart can be implemented and enforced by the U.S. EPA, or
a delegated authority such as the applicable State, local, or tribal
agency. If the EPA Administrator has delegated authority to a State,
local, or tribal agency, then that agency as well as the U.S. EPA has
the authority to implement and enforce this subpart. Contact the
applicable EPA Regional Office to find out if this subpart is delegated
to a State, local, or tribal agency.
(b) In delegating implementation and enforcement authority of this
subpart to a State, local, or tribal agency under subpart E of this
part, the authorities contained in paragraph (c) of this section are
retained by the EPA Administrator and are not transferred to the State,
local, or tribal agency.
(c) The authorities that will not be delegated to State, local, or
tribal agencies are as follows. Approval of alternatives to the
standards in Sec. 63.1955. Where these standards reference another
subpart, the cited provisions will be delegated according to the
delegation provisions of the referenced subpart.
Sec. 63.1990 What definitions apply to this subpart?
Terms used in this subpart are defined in the Clean Air Act, 40 CFR
part 60, subparts A, Cc, and WWW; 40 CFR part 62, subpart GGG, and
subpart A of this part, and this section that follows:
Bioreactor means a MSW landfill or portion of a MSW landfill where
any liquid other than leachate (leachate includes landfill gas
condensate) is added in a controlled fashion into the waste mass (often
in combination with recirculating leachate) to reach a minimum average
moisture content of at least 40 percent by weight to accelerate or
enhance the anaerobic (without oxygen) biodegradation of the waste.
Deviation means any instance in which an affected source subject to
this subpart, or an owner or operator of such a source:
(1) Fails to meet any requirement or obligation established by this
subpart,
[[Page 207]]
including, but not limited to, any emissions limitation (including any
operating limit) or work practice standard;
(2) Fails to meet any term or condition that is adopted to implement
an applicable requirement in this subpart and that is included in the
operating permit for any affected source required to obtain such a
permit; or
(3) Fails to meet any emission limitation, (including any operating
limit), or work practice standard in this subpart during SSM, regardless
of whether or not such failure is permitted by this subpart.
Emissions limitation means any emission limit, opacity limit,
operating limit, or visible emissions limit.
EPA approved State plan means a State plan that EPA has approved
based on the requirements in 40 CFR part 60, subpart B to implement and
enforce 40 CFR part 60, subpart Cc. An approved State plan becomes
effective on the date specified in the notice published in the Federal
Register announcing EPA's approval.
Federal plan means the EPA plan to implement 40 CFR part 60, subpart
Cc for existing MSW landfills located in States and Indian country where
State plans or tribal plans are not currently in effect. On the
effective date of an EPA approved State or tribal plan, the Federal plan
no longer applies. The Federal plan is found at 40 CFR part 62, subpart
GGG.
Municipal solid waste landfill or MSW landfill means an entire
disposal facility in a contiguous geographical space where household
waste is placed in or on land. A municipal solid waste landfill may also
receive other types of RCRA Subtitle D wastes (see Sec. 257.2 of this
chapter) such as commercial solid waste, nonhazardous sludge,
conditionally exempt small quantity generator waste, and industrial
solid waste. Portions of a municipal solid waste landfill may be
separated by access roads. A municipal solid waste landfill may be
publicly or privately owned. A municipal solid waste landfill may be a
new municipal solid waste landfill, an existing municipal solid waste
landfill, or a lateral expansion.
Tribal plan means a plan submitted by a tribal authority pursuant to
40 CFR parts 9, 35, 49, 50, and 81 to implement and enforce 40 CFR part
60, subpart Cc.
Work practice standard means any design, equipment, work practice,
or operational standard, or combination thereof, that is promulgated
pursuant to section 112(h) of the Clean Air Act.
As stated in Sec. Sec. 63.1955 and 63.1980, you must meet each
requirement in the following table that applies to you.
Table 1 to Subpart AAAA of Part 63--Applicability of NESHAP General
Provisions to Subpart AAAA
------------------------------------------------------------------------
Part 63 Citation Description Explanation
------------------------------------------------------------------------
63.1(a)..................... Applicability: Affected sources are
general already subject to
applicability of the provisions of
NESHAP in this part. paragraphs (a)(10)-
(12) through the
same provisions
under 40 CFR, part
60 subpart A.
63.1(b)..................... Applicability
determination for
stationary sources.
63.1(e)..................... Title V permitting..
63.2........................ Definitions.........
63.4........................ Prohibited Affected sources are
activities and already subject to
circumvention. the provisions of
paragraph (b)
through the same
provisions under 40
CFR, part 60
subpart A.
63.5(b)..................... Requirements for
existing, newly
constructed, and
reconstructed
sources.
63.6(e)..................... Operation and
maintenance
requirements,
startup, shutdown
and malfunction
plan provisions.
63.6(f)..................... Compliance with Affected sources are
nonopacity emission already subject to
standards. the provisions of
paragraphs (f)(1)
and (2)(i) through
the same provisions
under 40 CFR, part
60 subpart A.
63.10(b)(2)(i)-(b)(2)(v).... General
recordkeeping
requirements.
[[Page 208]]
63.10(d)(5)................. If actions taken
during a startup,
shutdown and
malfunction plan
are consistent with
the procedures in
the startup,
shutdown and
malfunction plan,
this information
shall be included
in a semi-annual
startup, shutdown
and malfunction
plan report. Any
time an action
taken during a
startup, shutdown
and malfunction
plan is not
consistent with the
startup, shutdown
and malfunction
plan, the source
shall report
actions taken
within 2 working
days after
commencing such
actions, followed
by a letter 7 days
after the event.
63.12(a).................... These provisions do
not preclude the
State from adopting
and enforcing any
standard,
limitation, etc.,
requiring permits,
or requiring
emissions
reductions in
excess of those
specified.
63.15....................... Availability of
information and
confidentiality.
------------------------------------------------------------------------
Subpart CCCC_National Emission Standards for Hazardous Air Pollutants:
Manufacturing of Nutritional Yeast
Source: 66 FR 27884, May 21, 2001, unless otherwise noted.
What This Subpart Covers
Sec. 63.2130 What is the purpose of this subpart?
This subpart establishes national emission limitations for hazardous
air pollutants emitted from manufacturers of nutritional yeast. This
subpart also establishes requirements to demonstrate initial and
continuous compliance with the emission limitations.
Sec. 63.2131 Am I subject to this subpart?
(a) You are subject to this subpart if you own or operate a
nutritional yeast manufacturing facility that is, is located at, or is
part of a major source of hazardous air pollutants (HAP) emissions.
(1) A manufacturer of nutritional yeast is a facility that makes
yeast for the purpose of becoming an ingredient in dough for bread or
any other yeast-raised baked product, or for becoming a nutritional food
additive intended for consumption by humans. A manufacturer of
nutritional yeast does not include production of yeast intended for
consumption by animals, such as an additive for livestock feed.
(2) A major source of HAP emissions is any stationary source or
group of stationary sources located within a contiguous area and under
common control that emits or has the potential to emit, considering
controls, any single HAP at a rate of 9.07 megagrams (10 tons) or more
per year or any combination of HAP at a rate of 22.68 megagrams (25
tons) or more per year.
(b) [Reserved]
Sec. 63.2132 What parts of my plant does this subpart cover?
(a) This subpart applies to each new, reconstructed, or existing
``affected source'' that produces Saccharomyces cerevisiae at a
nutritional yeast manufacturing facility.
(b) The affected source is the collection of equipment used in the
manufacture of the nutritional yeast species Saccharomyces cerevisiae.
This collection of equipment includes, but is not limited to,
fermentation vessels (fermenters). The collection of equipment used in
the manufacture of the nutritional yeast species Candida utilis (torula
yeast) is not part of the affected source.
(c) The emission limitations in this subpart apply to fermenters in
the affected source that meet all of the criteria listed in paragraphs
(c)(1) through (2) of this section.
(1) The fermenters are ``fed-batch'' as defined in Sec. 63.2192.
(2) The fermenters are used to support one of the last three
fermentation stages in a production run, which may be referred to as
``stock, first generation, and trade,'' ``seed, semi-seed, and
commercial,'' or ``CB4, CB5, and CB6'' stages.
[[Page 209]]
(d) The emission limitations in this subpart do not apply to flask,
pure-culture, yeasting-tank, or any other set-batch fermentation, and
they do not apply to any operations after the last dewatering operation,
such as filtration.
(e) The emission limitations in this subpart do not apply to the
affected source during the production of specialty yeast (defined in
Sec. 63.2192).
(f) An affected source is a ``new affected source'' if you commenced
construction of the affected source after October 19, 1998, and you met
the applicability criteria in Sec. 63.2131 at the time you commenced
construction.
(g) An affected source is ``reconstructed'' if you meet the criteria
as defined in Sec. 63.2.
(h) An affected source is ``existing'' if it is not new or
reconstructed.
Sec. 63.2133 When do I have to comply with this subpart?
(a) If you have a new or reconstructed affected source, you must
comply with paragraphs (a)(1) through (2) of this section.
(1) If you start up your affected source before May 21, 2001, then
you must comply with the emission limitations in this subpart no later
than May 21, 2001.
(2) If you start up your affected source after May 21, 2001, then
you must comply with the emission limitations in this subpart upon
startup of your affected source.
(b) If you have an existing affected source, you must comply with
the emission limitations for existing sources no later than May 21,
2004.
(c) If you have an area source that increases its emissions, or its
potential to emit, so that it becomes a major source of HAP, paragraphs
(c)(1) through (2) of this section apply.
(1) Any portion of the existing facility that is a new affected
source or a new reconstructed source must be in compliance with this
subpart upon startup.
(2) All other parts of the source must be in compliance with this
subpart by not later than 3 years after it becomes a major source.
(d) You must meet the notification requirements in Sec. 63.2180
according to the schedule in Sec. 63.2180 and in subpart A of this
part.
Emission Limitations
Sec. 63.2140 What emission limitations must I meet?
You must meet all of the emission limitations in Table 1 to this
subpart.
General Compliance Requirements
Sec. 63.2150 What are my general requirements for complying with this
subpart?
(a) You must be in compliance with the emission limitations in Table
1 to this subpart at all times, except during periods of malfunction.
(b) You must always operate and maintain your affected source,
including monitoring equipment, according to the provisions in Sec.
63.6(e)(1)(i). If the date upon which you must demonstrate initial
compliance as specified in Sec. 63.2160 falls after the compliance date
specified for your affected source in Sec. 63.2133, then you must
maintain a log detailing the operation and maintenance of the continuous
monitoring systems and the process and emissions control equipment
during the period between those dates.
(c) You must develop a written malfunction plan. It will be as
specified in Sec. 63.6(e)(3), except that the requirements for startup,
shutdown, and maintenance plans, records and reports apply only to
malfunctions. Under this subpart, a period of malfunction is expressed
in whole batches and not in portions of batches.
[66 FR 27884, May 21, 2001, as amended at 71 FR 20462, Apr. 20, 2006]
Testing and Initial Compliance Requirements
Sec. 63.2160 By what date must I conduct an initial compliance
demonstration?
(a) For each emission limitation in Table 1 to this subpart for
which compliance is demonstrated by monitoring fermenter exhaust, you
must demonstrate initial compliance for the period ending on the last
day of the month that is 12 calendar months (or 11 calendar months, if
the compliance date for your source is the first day of
[[Page 210]]
the month) after the compliance date that is specified for your source
in Sec. 63.2133. (For example, if the compliance date is October 15,
2003, the first 12-month period for which you must demonstrate
compliance would be October 15, 2003 through October 31, 2004.)
(b) For each emission limitation in Table 1 to this subpart for
which initial compliance is demonstrated by monitoring brew ethanol
concentration and calculating volatile organic compound (VOC)
concentration in the fermenter exhaust according to the procedures in
Sec. 63.2161, you must demonstrate initial compliance within 180
calendar days before the compliance date that is specified for your
source in Sec. 63.2133.
Sec. 63.2161 What performance tests and other procedures must I use
if I monitor brew ethanol?
(a) You must conduct each performance test in Table 2 to this
subpart that applies to you.
(b) Each performance test must be conducted according to the
requirements in Sec. 63.7(e)(1) and under the specific conditions that
this subpart specifies in Table 2 to this subpart and in paragraphs
(b)(1) through (4) of this section.
(1) Conduct each performance test simultaneously with brew ethanol
monitoring to establish a brew-to-exhaust correlation equation as
specified in paragraph (f) of this section.
(2) For each fermentation stage, conduct one run of the EPA Test
Method 25A of 40 CFR part 60, appendix A, over the entire length of a
batch. The three fermentation stages do not have to be from the same
production run.
(3) Do the test at a point in the exhaust-gas stream before you
inject any dilution air, which is any air not needed to control
fermentation.
(4) Record the results of the test for each fermentation stage.
(c) You may not conduct performance tests during periods of startup,
shutdown, or malfunction, as specified in Sec. 63.7(e)(1).
(d) You must collect data to correlate the brew ethanol
concentration measured by the continuous emission monitoring system
(CEMS) to the VOC concentration in the fermenter exhaust according to
paragraphs (d)(1) through (3) of this section.
(1) You must collect a separate set of brew ethanol concentration
data for each fed-batch fermentation stage while manufacturing the
product that comprises the largest percentage (by mass) of average
annual production.
(2) Measure brew ethanol as specified in Sec. 63.2164
simultaneously with conducting a performance test for VOC in fermenter
exhaust as specified in paragraph (b) of this section. You must measure
brew ethanol at least once during each successive 30-minute period over
the entire period of the performance test for VOC in fermenter exhaust.
(3) Keep a record of the brew ethanol concentration data for each
fermentation stage over the period of EPA Test Method 25A of 40 CFR part
60, appendix A, performance test when the VOC concentration in the
fermenter exhaust does not exceed the applicable emission limitation in
Table 1 to this subpart.
(e) For each set of data that you collected under paragraph (d) of
this section, perform a linear regression of brew ethanol concentration
(percent) on VOC fermenter exhaust concentration (parts per million by
volume (ppmv) measured as propane). The correlation between the brew
ethanol concentration as measured by the CEMS and the VOC fermenter
exhaust concentration as measured by EPA Test Method 25A of 40 CFR part
60, appendix A, must be linear with a correlation coefficient of at
least 0.90.
(f) Calculate the VOC concentration in the fermenter exhaust using
the brew ethanol concentration data collected under paragraph (d) of
this section and according to Equation 1 of this section.
BAVOC = BAE * CF + y (Eq. 1)
Where:
BAVOC = batch-average concentration of VOC in fermenter exhaust (ppmv
measured as propane), calculated for compliance demonstration
BAE = batch-average concentration of brew ethanol in fermenter liquid
(percent), measured by CEMS
CF = constant established at performance test and representing the slope
of the regression line
[[Page 211]]
y = constant established at performance test and representing the y-
intercept of the regression line
Sec. 63.2162 When must I conduct subsequent performance tests?
(a) For each emission limitation in Table 1 to this subpart for
which compliance is demonstrated by monitoring brew ethanol
concentration and calculating VOC concentration in the fermenter exhaust
according to the procedures in Sec. 63.2161, you must conduct an EPA
Test Method 25A of 40 CFR part 60, appendix A, performance test and
establish a brew-to-exhaust correlation according to the procedures in
Table 2 to this subpart and in Sec. 63.2161, at least once every year.
(b) The first subsequent performance test must be conducted no later
than 365 calendar days after the initial performance test conducted
according to Sec. 63.2160. Each subsequent performance test must be
conducted no later than 365 calendar days after the previous performance
test. You must conduct a performance test for each 365 calendar day
period for the lifetime of the affected source.
Sec. 63.2163 If I monitor fermenter exhaust, what are my monitoring
installation, operation, and maintenance requirements?
(a) Each CEMS must be installed, operated, and maintained according
to the applicable Performance Specification (PS) of 40 CFR part 60,
appendix B.
(b) You must conduct a performance evaluation of each CEMS according
to the requirements in Sec. 63.8, according to the applicable
Performance Specification of 40 CFR part 60, appendix B, and according
to paragraphs (b)(1) through (4) of this section.
(1) If your CEMS monitor generates a single combined response value
for VOC (examples of such detection principles are flame ionization,
photoionization, and non-dispersive infrared absorption), but it is not
a flame ionization analyzer, you must use PS 8 to show that your CEMS is
operating properly.
(i) Use EPA Test Method 25A of 40 CFR part 60, appendix A, to do the
relative-accuracy test PS 8 requires.
(ii) Calibrate the reference method with propane.
(iii) Collect a 1-hour sample for each reference-method test.
(2) If you continuously monitor VOC emissions using a flame
ionization analyzer, then you must conduct the calibration drift test PS
8 requires, but you are not required to conduct the relative-accuracy
test PS 8 requires.
(3) If you continuously monitor VOC emissions using gas
chromatography, you must use PS 9 of CFR part 60, appendix B, to show
that your CEMS is operating properly.
(4) You must complete the performance evaluation and submit the
performance evaluation report before the compliance date that is
specified for your source in Sec. 63.2133.
(c) Calibrate the CEMS with propane.
(d) Set the CEMS span at not greater than 5 times the relevant
emission limit, with 1.5 to 2.5 times the relevant emission limit being
the range considered by us to be generally optimum.
(e) You must monitor VOC concentration in fermenter exhaust at any
point prior to dilution of the exhaust stream.
(f) Each CEMS must complete a minimum of one cycle of operation
(sampling, analyzing, and data recording) for each successive 30-minute
period within each batch monitoring period. Except as specified in
paragraph (g) of this section, you must have a minimum of two cycles of
operation in a 1-hour period to have a valid hour of data.
(g) The CEMS data must be reduced to arithmetic batch averages
computed from two or more data points over each 1-hour period, except
during periods when calibration, quality assurance, or maintenance
activities pursuant to provisions of this part are being performed.
During these periods, a valid hour of data shall consist of at least one
data point representing a 30-minute period.
(h) You must have valid CEMS data from at least 75 percent of the
full hours over the entire batch monitoring period.
(i) For each CEMS, record the results of each inspection,
calibration, and validation check.
(j) You must check the zero (low-level) and high-level calibration
drifts for each CEMS in accordance with the
[[Page 212]]
applicable PS of 40 CFR part 60, appendix B. The zero (low-level) and
high-level calibration drifts shall be adjusted, at a minimum, whenever
the zero (low-level) drift exceeds 2 times the limits of the applicable
PS. The calibration drift checks must be performed at least once daily
except that they may be performed less frequently under the conditions
of paragraphs (j)(1) through (3) of this section.
(1) If a 24-hour calibration drift check for your CEMS is performed
immediately prior to, or at the start of, a batch monitoring period of a
duration exceeding 24 hours, you are not required to perform 24-hour-
interval calibration drift checks during that batch monitoring period.
(2) If the 24-hour calibration drift exceeds 2.5 percent of the span
value (or more than 10 percent of the calibration gas value if your CEMS
is a gas chromatograph (GC)) in fewer than 5 percent of the checks over
a 1-month period, and the 24-hour calibration drift never exceeds 7.5
percent of the span value, then the frequency of calibration drift
checks may be reduced to at least weekly (once every 7 days).
(3) If, during two consecutive weekly checks, the weekly calibration
drift exceeds 5 percent of the span value (or more than 20 percent of
the calibration gas value, if your CEMS is a GC), then a frequency of at
least 24-hour interval calibration checks must be resumed until the 24-
hour calibration checks meet the test of paragraph (j)(2) of this
section.
(k) If your CEMS is out of control, you must take corrective action
according to paragraphs (k)(1) through (3) of this section.
(1) Your CEMS is out of control if the zero (low-level) or high-
level calibration drift exceeds 2 times the limits of the applicable PS.
(2) When the CEMS is out of control, take the necessary corrective
action and repeat all necessary tests that indicate that the system is
out of control. You must take corrective action and conduct retesting
until the performance requirements are below the applicable limits.
(3) During the batch monitoring periods in which the CEMS is out of
control, recorded data shall not be used in data averages and
calculations, or to meet any data availability requirement established
under this subpart. The beginning of the out-of-control period is the
beginning of the first batch monitoring period that follows the most
recent calibration drift check during which the system was within
allowable performance limits. The end of the out-of-control period is
the end of the last batch monitoring period before you have completed
corrective action and successfully demonstrated that the system is
within the allowable limits. If your successful demonstration that the
system is within the allowable limits occurs during a batch monitoring
period, then the out-of-control period ends at the end of that batch
monitoring period. If the CEMS is out of control for any part of a
particular batch monitoring period, it is out of control for the whole
batch monitoring period.
Sec. 63.2164 If I monitor brew ethanol, what are my monitoring
installation, operation, and maintenance requirements?
(a) Each CEMS must be installed, operated, and maintained according
to manufacturer's specifications and in accordance with Sec.
63.6(e)(1).
(b) Each CEMS must complete a minimum of one cycle of operation
(sampling, analyzing, and data recording) for each successive 30-minute
period within each batch monitoring period. Except as specified in
paragraph (c) of this section, you must have a minimum of two cycles of
operation in a 1-hour period to have a valid hour of data.
(c) The CEMS data must be reduced to arithmetic batch averages
computed from two or more data points over each 1-hour period, except
during periods when calibration, quality assurance, or maintenance
activities pursuant to provisions of this part are being performed.
During these periods, a valid hour of data shall consist of at least one
data point representing a 30-minute period.
(d) You must have valid CEMS data from at least 75 percent of the
full hours over the entire batch monitoring period.
[[Page 213]]
(e) Set the CEMS span to correspond to not greater than 5 times the
relevant emission limit, with 1.5 to 2.5 times the relevant emission
limit being the range considered by us to be generally optimum. Use the
brew-to-exhaust correlation equation established under Sec. 63.2161(f)
to determine the span value for your CEMS that corresponds to the
relevant emission limit.
(f) For each CEMS, record the results of each inspection,
calibration, and validation check.
(g) The GC that you use to calibrate your CEMS must meet the
requirements of paragraphs (g)(1) through (3) of this section.
(1) Calibrate the GC at least daily, by analyzing standard solutions
of ethanol in water (0.05 percent, 0.15 percent, and 0.3 percent).
(2) For use in calibrating the GC, prepare the standard solutions of
ethanol using the procedures listed in paragraphs (g)(2)(i) through (vi)
of this section.
(i) Starting with 100 percent ethanol, dry the ethanol by adding a
small amount of anhydrous magnesium sulfate (granular) to 15-20
milliliters (ml) of ethanol.
(ii) Place approximately 50 ml of water into a 100-ml volumetric
flask and place the flask on a balance. Tare the balance. Weigh 2.3670
grams of the dry (anhydrous) ethanol into the volumetric flask.
(iii) Add the 100-ml volumetric flask contents to a 1000-ml
volumetric flask. Rinse the 100-ml volumetric flask with water into the
1000-ml flask. Bring the volume to 1000 ml with water.
(iv) Place an aliquot into a sample bottle labeled ``0.3% Ethanol.''
(v) Fill a 50-ml volumetric flask from the contents of the 1000-ml
flask. Add the contents of the 50-ml volumetric flask to a 100-ml
volumetric flask and rinse the 50-ml flask into the 100-ml flask with
water. Bring the volume to 100 ml with water. Place the contents into a
sample bottle labeled ``0.15% Ethanol.''
(vi) With a 10-ml volumetric pipette, add two 10.0-ml volumes of
water to a sample bottle labeled ``0.05% Ethanol.'' With a 10.0-ml
volumetric pipette, pipette 10.0 ml of the 0.15 percent ethanol solution
into the sample bottle labeled ``0.05% Ethanol.''
(3) For use in calibrating the GC, dispense samples of the standard
solutions of ethanol in water in aliquots to appropriately labeled and
dated glass sample bottles fitted with caps having a Teflon
[reg] seal. Refrigerated samples may be kept unopened for 1
month. Prepare new calibration standards of ethanol in water at least
monthly.
(h) Calibrate the CEMS according to paragraphs (h)(1) through (3) of
this section.
(1) To calibrate the CEMS, inject a brew sample into a calibrated GC
and compare the simultaneous ethanol value given by the CEMS to that
given by the GC. Use either the Porapak [reg] Q, 80-100 mesh,
6[min] x \1/8\[min], stainless steel packed column or the DB Wax, 0.53
mm x 30 m capillary column.
(2) If a CEMS ethanol value differs by 20 percent or more from the
corresponding GC ethanol value, determine the brew ethanol values
throughout the rest of the batch monitoring period by injecting brew
samples into the GC not less frequently than every 30 minutes. From the
time at which the difference of 20 percent or more is detected until the
batch monitoring period ends, the GC data will serve as the CEMS data.
(3) Perform a calibration of the CEMS at least four times per batch.
[66 FR 27884, May 21, 2001, as amended at 71 FR 20462, Apr. 20, 2006]
Sec. 63.2165 How do I demonstrate initial compliance with the emission
limitations if I monitor fermenter exhaust?
(a) You must demonstrate initial compliance with each emission
limitation that applies to you according to Table 3 to this subpart.
(b) You must submit the Notification of Compliance Status containing
the results of the initial compliance demonstration according to the
requirements in Sec. 63.2180(e).
[[Page 214]]
Sec. 63.2166 How do I demonstrate initial compliance with the emission
limitations if I monitor brew ethanol?
(a) You must demonstrate initial compliance with each emission
limitation that applies to you according to Table 3 to this subpart.
(b) You must establish the brew-to-exhaust correlation for each
fermentation stage according to Sec. 63.2161(e).
(c) You must submit the Notification of Compliance Status containing
the results of the initial compliance demonstration according to the
requirements in Sec. 63.2180(e).
Continuous Compliance Requirements
Sec. 63.2170 How do I monitor and collect data to demonstrate continuous
compliance?
(a) You must monitor and collect data according to this section.
(b) Except for monitor malfunctions, associated repairs, and
required quality assurance or control activities (including, as
applicable, calibration checks and required zero and span adjustments),
you must monitor continuously during each batch monitoring period.
(c) You may not use data recorded during monitoring malfunctions,
associated repairs, and required quality assurance or quality control
activities in data averages and calculations used to report emission or
operating levels, or to fulfill a minimum data availability requirement.
You must use all the data collected during all other periods in
assessing the operation of the control system.
Sec. 63.2171 How do I demonstrate continuous compliance with the
emission limitations?
(a) You must demonstrate continuous compliance with each emission
limitation in Table 1 to this subpart that applies to you according to
methods specified in Table 4 to this subpart.
(b) You must calculate the percentage of within-concentration
batches (defined in Sec. 63.2192) for each 12-month period according to
paragraphs (b)(1) through (4) of this section.
(1) Determine the percentage of batches over a 12-month calculation
period that were in compliance with the applicable maximum
concentration. The total number of batches in the calculation period is
the sum of the numbers of batches of each fermentation stage for which
emission limits apply. To calculate the 12-month percentage, do not
include batches in production during periods of malfunction. In counting
the number of batches in the 12-month calculation period, include those
batches for which the batch monitoring period ended on or after 12 a.m.
on the first day of the period and exclude those batches for which the
batch monitoring period did not end on or before 11:59 p.m. on the last
day of the period.
(2) You must determine the 12-month percentage at the end of each
calendar month.
(3) The first 12-month calculation period begins on the compliance
date that is specified for your source in Sec. 63.2133 and ends on the
last day of the month that includes the date 365 days after your
compliance date, unless the compliance date for your source is the first
day of the month, in which case the first 12-month calculation period
ends on the last day of the month that is 11 calendar months after the
compliance date. (For example, if the compliance date for your source is
October 15, 2003, the first 12-month calculation period would begin on
October 15, 2003, and end on October 31, 2004. If the compliance date
for your source is October 1, 2003, the first 12-month calculation
period would begin on October 1, 2003, and end on September 30, 2004.)
(4) The second 12-month calculation period and each subsequent 12-
month calculation period begin on the first day of the month following
the first full month of the previous 12-month averaging period and end
on the last day of the month 11 calendar months later. (For example, if
the compliance date for your source is October 15, 2003, the second
calculation period would begin on December 1, 2003 and end on November
30, 2004.)
(c) You must report each instance (that is, each 12-month
calculation period) in which you did not meet each emission requirement
in Table 4 to this subpart that applies to you. (Failure of a single
batch to meet a concentration
[[Page 215]]
limit does not in and of itself constitute a failure to meet the
emission limitation.) Each instance in which you failed to meet each
applicable emission limitation is reported as part of the requirements
in Sec. 63.2181.
[66 FR 27884, May 21, 2001, as amended at 71 FR 20463, Apr. 20, 2006]
Notification, Reports, and Records
Sec. 63.2180 What notifications must I submit and when?
(a) You must submit all of the notifications in Sec. Sec. 63.7(b)
and (c), 63.8(e), (f)(4) and (6), and 63.9(b) through (h) that apply to
you by the dates specified.
(b) If you start up your affected source before May 21, 2001, you
are not subject to the initial notification requirements of Sec.
63.9(b)(2).
(c) If you are required to conduct a performance test as specified
in Table 2 to this subpart, you must submit a notification of intent to
conduct a performance test at least 60 calendar days before the
performance test is scheduled to begin as required in Sec. 63.7(b)(1).
(d) If you are required to conduct a performance evaluation as
specified in Sec. 63.2163(b), you must submit a notification of the
date of the performance evaluation at least 60 days prior to the date
the performance evaluation is scheduled to begin as required in Sec.
63.8(e)(2).
(e) If you are required to conduct a performance test or other
initial compliance demonstration as specified in Table 2 or 3 to this
subpart, you must submit a Notification of Compliance Status according
to Sec. 63.9(h)(2)(ii) and according to paragraphs (e)(1) through (2)
of this section.
(1) For each initial compliance demonstration required in Table 3 to
this subpart that does not include a performance test, you must submit
the Notification of Compliance Status no later than July 31 or January
31, whichever date follows the end of the first 12 calendar months after
the compliance date that is specified for your source in Sec. 63.2133.
If your initial compliance demonstration does not include a performance
test, the first compliance report, described in Sec. 63.2181(b)(1),
serves as the Notice of Compliance Status.
(2) For each initial compliance demonstration required in Table 2 or
3 to this subpart that includes a performance test conducted according
to the requirements in Table 2, you must submit the Notification of
Compliance Status, including the performance test results, before the
close of business on the 60th calendar day following the completion of
the performance test according to Sec. 63.10(d)(2).
Sec. 63.2181 What reports must I submit and when?
(a) You must submit each report in Table 5 to this subpart that
applies to you.
(b) Unless the Administrator has approved a different schedule for
submission of reports under Sec. 63.10(a), you must submit each report
by the date in Table 5 to this subpart and according to paragraphs
(b)(1) through (5) of this section.
(1) The first compliance report must cover the period beginning on
the compliance date that is specified for your affected source in Sec.
63.2133 and ending on either June 30 or December 31 (use whichever date
is the first date following the end of the first 12 calendar months
after the compliance date that is specified for your source in Sec.
63.2133). The first compliance report must include the percentage of
within-concentration batches, as described in Sec. 63.2171(b), for the
first 12-month calculation period described in Sec. 63.2171(b)(3). It
must also include a percentage for each subsequent 12-month calculation
period, as described in Sec. 63.2171(b)(4), ending on a calendar month
that falls within the first compliance period. (For example, if the
compliance date for your source is October 15, 2003, the first
compliance report would cover the period from October 15, 2003 to
December 31, 2004. It would contain percentages for the 12-month periods
ending October 31, 2004; November 30, 2004; and December 31, 2004.)
(2) The first compliance report must be postmarked or delivered no
later than July 31 or January 31, whichever date follows the end of the
first 12 calendar months after the compliance date that is specified for
your affected source in Sec. 63.2133.
[[Page 216]]
(3) Each subsequent compliance report must cover the semiannual
reporting period from January 1 through June 30 or the semiannual
reporting period from July 1 through December 31. Each subsequent
compliance report must include the percentage of within-concentration
batches for each 12-month calculation period ending on a calendar month
that falls within the reporting period. (For example, if the compliance
date for your source is October 15, 2003, the second compliance report
would cover the period from January 1, 2005 through June 30, 2005. It
would contain percentages for the 12-month periods ending January 31,
2005; February 28, 2005; March 31, 2005; April 30, 2005; May 31, 2005;
and June 30, 2005.)
(4) Each subsequent compliance report must be postmarked or
delivered no later than July 31 or January 31, whichever date is the
first date following the end of the semiannual reporting period.
(5) For each affected source that is subject to permitting
regulations pursuant to 40 CFR part 70 or part 71, and if the permitting
authority has established dates for submitting semiannual reports
pursuant to 40 CFR 70.6(a)(3)(a)(iii)(A) or 40 CFR
71.6(a)(3)(a)(iii)(A), you may submit the first and subsequent
compliance reports according to the dates the permitting authority has
established instead of according to the dates in paragraphs (b)(1)
through (4) of this section.
(c) The compliance report must contain the information listed in
paragraphs (c)(1) through (5) of this section.
(1) Company name and address.
(2) Statement by a responsible official with that official's name,
title, and signature, certifying the accuracy of the content of the
report.
(3) Date of report and beginning and ending dates of the reporting
period.
(4) Percentage of batches that are within-concentration batches for
each 12-month period ending on a calendar month that falls within the
reporting period.
(5) If you had a malfunction during the reporting period and you
took actions consistent with your malfunction plan, the compliance
report must include the information in Sec. 63.10(d)(5)(i) for each
malfunction.
Sec. 63.2182 What records must I keep?
(a) You must keep the records listed in paragraphs (a)(1) through
(4) of this section. These include:
(1) A copy of each notification and report that you submitted to
comply with this subpart, including all documentation supporting any
Notification of Compliance Status and compliance report that you
submitted, according to the requirements in Sec. 63.10(b)(2)(xiv).
(2) The records in Sec. 63.6(e)(3)(iii) through (v) related to
malfunction;
(3) Records of performance tests and performance evaluations as
required in Sec. 63.10(b)(2)(viii); and
(4) Records of results of brew-to-exhaust correlation tests
specified in Sec. 63.2161.
(b) For each CEMS, you must keep the records listed in paragraphs
(b)(1) through (9) of this section. These include:
(1) Records described in Sec. 63.10(b)(2)(vi);
(2) All required measurements needed to demonstrate compliance with
a relevant standard (including, but not limited to, 30-minute averages
of CEMS data, raw performance testing measurements, and raw performance
evaluation measurements, that support data that the source is required
to report);
(3) Records described in Sec. 63.10(b)(2)(viii) through (xi). The
CEMS system must allow the amount of excess zero (low-level) and high-
level calibration drift measured at the interval checks to be quantified
and recorded;
(4) All required CEMS measurements (including monitoring data
recorded during unavoidable CEMS breakdowns and out-of-control periods);
(5) Identification of each batch during which the CEMS was
inoperative, except for zero (low-level) and high-level checks;
(6) Identification of each batch during which the CEMS was out of
control, as defined in Sec. 63.2163(k);
(7) Previous (i.e., superseded) versions of the performance
evaluation plan as required in Sec. 63.8(d)(3);
(8) Request for alternatives to relative accuracy test for CEMS as
required in Sec. 63.8(f)(6)(i); and
(9) Records of each batch for which the batch-average VOC
concentration
[[Page 217]]
exceeded the applicable maximum VOC concentration in Table 1 to this
subpart and whether the batch was in production during a period of
malfunction or during another period.
(c) You must keep the records required in Table 4 to this subpart to
show continuous compliance with each emission limitation that applies to
you.
(d) You must also keep the records listed in paragraphs (d)(1)
through (3) of this section for each batch in your affected source.
(1) Unique batch identification number.
(2) Fermentation stage for which you are using the fermenter.
(3) Unique CEMS equipment identification number.
Sec. 63.2183 In what form and how long must I keep my records?
(a) Your records must be in a form suitable and readily available
for expeditious review, according to Sec. 63.10(b)(1).
(b) As specified in Sec. 63.10(b)(1), you must keep each record for
5 years following the date of each occurrence, measurement, maintenance,
corrective action, report, or record.
(c) You must keep each record on site for at least 2 years after the
date of each occurrence, measurement, maintenance, corrective action,
report, or record, according to Sec. 63.10(b)(1). You can keep the
records offsite for the remaining 3 years.
Other Requirements and Information
Sec. 63.2190 What parts of the General Provisions apply to me?
Table 6 to this subpart shows which parts of the General Provisions
in Sec. Sec. 63.1 through 63.13 apply to you.
Sec. 63.2191 Who implements and enforces this subpart?
(a) This subpart can be implemented and enforced by us, the U.S.
EPA, or a delegated authority such as your State, local, or tribal
agency. If the U.S. EPA Administrator has delegated authority to your
State, local, or tribal agency, then that agency has the authority to
implement and enforce this subpart. You should contact your U.S. EPA
Regional Office to find out if this subpart is delegated to your State,
local, or tribal agency.
(b) In delegating implementation and enforcement authority of this
subpart to a State, local, or tribal agency under 40 CFR part 63,
subpart E, the authorities contained in paragraph (c) of this section
are retained by the Administrator of the U.S. EPA and are not
transferred to the State, local, or tribal agency.
(c) The authorities that will not be delegated to State, local, or
tribal agencies are as listed in paragraphs (c)(1) through (4) of this
section.
(1) Approval of alternatives to the non-opacity emission limitations
in Sec. 63.2140 under Sec. 63.6(g).
(2) Approval of major alternatives to test methods under Sec.
63.7(e)(2)(ii) and (f) and as defined in Sec. 63.90.
(3) Approval of major alternatives to monitoring under Sec. 63.8(f)
and as defined in Sec. 63.90.
(4) Approval of major alternatives to recordkeeping and reporting
under Sec. 63.10(f) and as defined in Sec. 63.90.
Sec. 63.2192 What definitions apply to this subpart?
Terms used in this subpart are defined in the Clean Air Act, in 40
CFR 63.2, the General Provisions of this part, and in this section as
follows:
Batch means a single fermentation cycle in a single fermentation
vessel (fermenter).
Batch monitoring period means the period that begins at the later of
either the start of aeration or the addition of yeast to the fermenter;
the period ends at the earlier of either the end of aeration or the
point at which the yeast has begun being emptied from the fermenter.
Brew means the mixture of yeast and additives in the fermenter.
Brew ethanol means the ethanol in fermenter liquid.
Brew ethanol monitor means the monitoring system that you use to
measure brew ethanol to demonstrate compliance with this subpart. The
monitoring system includes a resistance element used as an ethanol
sensor, with the measured resistance proportional to the concentration
of ethanol in the brew.
[[Page 218]]
Brew-to-exhaust correlation means the correlation between the
concentration of ethanol in the brew and the concentration of VOC in the
fermenter exhaust. This correlation is specific to each fed-batch
fermentation stage and is established while manufacturing the product
that comprises the largest percentage (by mass) of average annual
production.
Emission limitation means any emission limit or operating limit.
Fed-batch means the yeast is fed carbohydrates and additives during
fermentation in the vessel. In contrast, carbohydrates and additives are
added to ``set-batch'' fermenters only at the start of the batch.
1-hour period means any 60-minute period commencing on the minute at
which the batch monitoring period begins.
Product means the yeast resulting from the final stage in a
production run. Products are distinguished by yeast species, strain, and
variety.
Responsible official means responsible official as defined in 40 CFR
70.2.
Specialty yeast includes but is not limited to yeast produced for
use in wine, champagne, whiskey, and beer.
Within-concentration batch means a batch for which the average VOC
concentration is not higher than the maximum concentration that is
allowed as part of the applicable emission limitation.
Table 1 to Subpart CCCC of Part 63--Emission Limitations
As stated in Sec. 63.2140, you must comply with the emission
limitations in the following table:
------------------------------------------------------------------------
For each fed-batch fermenter producing
yeast in the following fermentation You must meet the following
stage . . . emission limitation . . .
------------------------------------------------------------------------
Last stage (Trade); or Second-to-last a. For at least 98 percent of
stage (First Generation); or Third-to- all batches (sum of batches
last stage (Stock). from last, second-to-last, and
third-to-last stages) in each
12-month calculation period
described in Sec.
63.2171(b), the VOC
concentration in the fermenter
exhaust does not exceed the
applicable maximum
concentration (100 ppmv for
last stage, 200 ppmv for
second-to-last stage, or 300
ppmv for third-to-last stage),
measured as propane, and
averaged over the duration of
a batch.
b. The emission limitation does
not apply during the
production of specialty yeast.
------------------------------------------------------------------------
Table 2 to Subpart CCCC of Part 63--Requirements for Performance Tests
As stated in Sec. 63.2161, if you demonstrate compliance by
monitoring brew ethanol, you must comply with the requirements for
performance tests in the following table:
[Brew Ethanol Monitoring Only]
------------------------------------------------------------------------
For each fed-batch fermenter
for which compliance is
determined by monitoring
brew ethanol concentration According to the
and calculating VOC Using . . . following
concentration in the requirements . . .
fermenter exhaust according
to the procedures in Sec.
63.2161, you must . . .
------------------------------------------------------------------------
1. Measure VOC as propane... Method 25A*, or an You must measure the
alternative VOC concentration
validated by EPA in the fermenter
Method in the 301* exhaust at any
and approved by the point prior to
Administrator. dilution of the
exhaust stream.
2. Select the sampling Method 1* ....................
port's location and the
number of traverse points.
3. Measure volumetric flow Method 2* ....................
rate..
4. Perform gas analysis to Method 3* ....................
determine the dry molecular
weight of the stack gas.
5. Determine moisture Method 4* ....................
content of the stack gas.
------------------------------------------------------------------------
*EPA Test Methods found in appendix A of 40 CFR part 60.
[[Page 219]]
Table 3 to Subpart CCCC of Part 63--Initial Compliance With Emission
Limitations
As stated in Sec. 63.2165 (if you monitor fermenter exhaust) and
Sec. 63.2166 (if you monitor brew ethanol), you must comply with the
requirements to demonstrate initial compliance with the applicable
emission limitations in the following table:
------------------------------------------------------------------------
For the following You have
For . . . emission limitation demonstrated initial
. . . compliance if . . .
------------------------------------------------------------------------
1. Each fed-batch fermenter The VOC a. You reduce the
producing yeast in a concentration in CEMS data batch
fermentation stage (last the fermenter averages according
Trade), second-to-last exhaust, averaged to Sec.
(First Generation), or over the duration 63.2163(g).
third-to-last (Stock)) for of the batch, does b. The average VOC
which compliance is not exceed the concentration in
determined by monitoring applicable maximum the fermenter
VOC concentration in the concentration (100 exhaust for at
fermenter exhaust. ppmv for last least 98 percent of
stage, 200 ppmv for the batches (sum of
second-to-last batches from last,
stage, or 300 ppmv second-to-last, and
for third-to-last third-to-last
stage), measured as stages) during the
propane.. initial compliance
period described in
Sec. 63.2160(a)
does not exceed the
applicable maximum
concentration.
2. Each fed-batch fermenter The VOC a. The VOC fermenter
producing yeast in a concentration in exhaust
fermentation stage (last the fermenter concentration over
(Trade), second-to-last exhaust, averaged the period of the
(First Generation), or over the duration Method 25A*
third-to-last (Stock)) for of the batch, does performance test
which compliance is not exceed the does not exceed the
determined by monitoring applicable maximum applicable maximum
brew ethanol concentration concentration (100 concentration.
and calculating VOC ppmv for last b. You have a record
concentration in the stage, 2000 ppmv of the brew-to-
fermenter exhaust according for second-to-last exhaust correlation
to the procedures in Sec. stage, or 300 ppmv during the Method
63.2161. for third-to-last 25A* performance
stage), measured as test during which
propane. the VOC fermenter
exhaust
concentration did
not exceed the
applicable maximum
concentration.
------------------------------------------------------------------------
* EPA Test Method in appendix A of 40 CFR part 60.
Table 4 to Subpart CCCC of Part 63--Continuous Compliance With Emission
Limitations
As stated in Sec. 63.2171, you must comply with the requirements to
demonstrate continuous compliance with the applicable emission
limitations in the following table:
------------------------------------------------------------------------
For the following You must demonstrate
For . . . emission limitation continuous
. . . compliance by . . .
------------------------------------------------------------------------
1. Each fed-batch fermenter For at least 98 a. Collecting the
producing yeast in a percent of all monitoring data
fermentation stage (last batches (sum of according to Sec.
(Trade), second-to-last batches from last, 63.2163(f).
(First Generation), or second-to-last, and b. Reducing the data
third-to-last (Stock)) for third-to-last according to Sec.
which compliance is stages) in each 12- 63.2163(g).
determined by monitoring month calculation c. For at least 98
VOC concentration in the period described in percent of the
fermenter exhaust. Sec. 63.2171(b), batches (sum of
the VOC batches from last,
concentration in second-to-last, and
the fermenter third-to-last
exhaust, averaged stages) for each 12-
over the duration month period ending
of the batch, does within a semiannual
not exceed the reporting period
applicable maximum described in Sec.
concentration (100 63.2181(b)(3), the
ppmv for last batch average VOC
stage, 200 ppmv for concentration in
second-to-last the fermenter
stage, or 300 ppmv exhaust does not
for third-to-last exceed the
stage), measured as applicable maximum
propane. concentration.
2. Each fed-batch fermenter .For at least 98 a. Collecting the
producing yeast in a percent of all monitoring data
fermentation stage (last batches (sum of according to Sec.
(Trade), second-to-last batches from last, 63.2164(b).
(First Generation), or second-to-last, and b. Reducing the data
third-to-last (Stock)) for third-to-last according to Sec.
which compliance is stages) in each 12- 63.2164(c).
determined by monitoring month calculation c. For at least 98
brew ethanol concentration period described in percent of the
and calculating VOC Sec. 63.2171(b), batches (sum of
concentration in the the VOC batches from last,
fermenter exhaust according concentration in second-to-last, and
to the procedures in Sec. the fermenter third-to-last
63.2161. exhaust, averaged stages) for each 12-
over the duration month period ending
of the batch, does within a semiannual
not exceed the reporting period
applicable maximum described in Sec.
concentration (100 63.2181(b)(3), the
ppmvc for last batch average VOC
stage, 200 ppmv for concentration in
second-to-last the fermenter
stage, or 300 ppmv exhaust does not
for third-to-last exceed the
stage), measured as applicable maximum
propane. concentration.
------------------------------------------------------------------------
[[Page 220]]
Table 5 to Subpart CCCC of Part 63--Requirements for Reports
As stated in Sec. 63.2181, you must submit a compliance report that
contains the information in Sec. 63.2181(c) as well as the information
in the following table; you must also submit malfunction reports
according to the requirements in the following table:
------------------------------------------------------------------------
The report must You must submit the
You must submit a(n) contain . . . report . . .
------------------------------------------------------------------------
1. Compliance report........ a. Your calculated Semiannually
percentage of according to the
within- requirements in
concentration Sec. 63.2181(b).
batches, as
described in Sec.
63.2171(b), for 12-
month calculation
periods ending on
each calendar month
that falls within
the reporting
period.
b. If you had a Semiannually
malfunction during according to the
the reporting requirements in
period and you took Sec. 63.2181(b).
actions consistent
with your
malfunction plan,
the compliance
report must include
the information in
Sec.
63.10(d)(5)(i).
2. Immediate malfunction a. Actions taken for By fax or telephone
report if you had a the event. within 2 working
malfunction during the days after starting
reporting period that is actions
not consistent with your inconsistent with
malfunction plan. the plan.
b. The information By letter within 7
in Sec. working days after
63.10(d)(5)(ii). the end of the
event unless you
have made
alternative
arrangements with
the permitting
authority (Sec.
63.10(d)(5)(ii)).
------------------------------------------------------------------------
Table 6 to Subpart CCCC of Part 63--Applicability of General Provisions
to Subpart CCCC
As stated in Sec. 63.2190, you must comply with the applicable
General Provisions requirements according to the following table:
------------------------------------------------------------------------
Applicable to
Citation Subject subpart CCCC?
------------------------------------------------------------------------
Sec. 63.1................. Applicability....... Yes.
Sec. 63.2................. Definitions......... Yes.
Sec. 63.3................. Units and Yes.
Abbreviations.
Sec. 63.4................. Prohibited Yes.
Activities and
Circumvention.
Sec. 63.5................. Construction and Yes.
Reconstruction.
Sec. 63.6................. Compliance With 1. For Sec.
Standards and 63.6(e) and (f),
Maintenance requirements for
Requirements. startup, shutdown,
and malfunctions
apply only to
malfunctions.
2. Sec. 63.6(h)
does not apply.
3. Otherwise, all
apply.
Sec. 63.7................. Performance Testing 1. Sec. 63.7(a)(1)-
Requirements. (2) and (e)(3) do
not apply, instead
specified in this
subpart.
2. Otherwise, all
apply.
Sec. 63.8................. Monitoring 1. Sec. 63.8(a)(2)
Requirements. is modified by Sec.
63.2163.
2. Sec. 63.8(a)(4)
does not apply.
3. For Sec.
63.8(c)(1),
requirements for
startup, shutdown,
and malfunctions
apply only to
malfunctions, and
no report pursuant
to Sec.
63.10(d)(5)(i) is
required.
4. For Sec.
63.8(d),
requirements for
startup, shutdown,
and malfunctions
apply only to
malfunctions.
5. Sec.
63.8(c)(4)(i),
(c)(5), (e)(5)(ii),
and (g)(5), do not
apply.
6. Sec.
63.8(c)(4)(ii),
(c)(6)-(8), (e)(4),
and (g)(1)-(4) do
not apply, instead
specified in this
subpart.
7. Otherwise, all
apply.
Sec. 63.9................. Notification 1. Sec. 63.9(b)(2)
Requirements. does not apply
because rule omits
requirements for
initial
notification for
sources that start
up prior to May 21,
2001
2. Sec. 63.9(f)
does not apply.
3. Otherwise, all
apply.
[[Page 221]]
Sec. 63.10................ Recordkeeping and 1. For Sec.
Reporting 63.10(b)(2)(i)-(v),
Requirements. (c)(9)-(15), and
(d)(5),
requirements for
startup, shutdown,
and malfunctions
apply only to
malfunctions.
2. Sec.
63.10(b)(2)(vii)
and (c)(1)-(6) do
not apply, instead
specified in this
subpart.
3. Sec.
63.10(c)(7)-(8),
(d)(3), (e)(2)(ii)-
(4), (e)(3)-(4) do
not apply.
4. Otherwise, all
apply.
Sec. 63.11................ Flares.............. No.
Sec. 63.12................ Delegation.......... Yes.
Sec. 63.13................ Addresses........... Yes.
Sec. 63.14................ Incorporation by Yes.
Reference.
Sec. 63.15................ Availability of Yes.
Information.
------------------------------------------------------------------------
Subpart DDDD_National Emission Standards for Hazardous Air Pollutants:
Plywood and Composite Wood Products
What This Subpart Covers
Source: 69 FR 46011, July 30, 2004, unless otherwise noted.
Sec. 63.2230 What is the purpose of this subpart?
This subpart establishes national compliance options, operating
requirements, and work practice requirements for hazardous air
pollutants (HAP) emitted from plywood and composite wood products (PCWP)
manufacturing facilities. This subpart also establishes requirements to
demonstrate initial and continuous compliance with the compliance
options, operating requirements, and work practice requirements.
Sec. 63.2231 Does this subpart apply to me?
This subpart applies to you if you meet the criteria in paragraphs
(a) and (b) of this section, except for facilities that the
Environmental Protection Agency (EPA) determines are part of the low-
risk subcategory of PCWP manufacturing facilities as specified in
appendix B to this subpart.
(a) You own or operate a PCWP manufacturing facility. A PCWP
manufacturing facility is a facility that manufactures plywood and/or
composite wood products by bonding wood material (fibers, particles,
strands, veneers, etc.) or agricultural fiber, generally with resin
under heat and pressure, to form a structural panel or engineered wood
product. Plywood and composite wood products manufacturing facilities
also include facilities that manufacture dry veneer and lumber kilns
located at any facility. Plywood and composite wood products include,
but are not limited to, plywood, veneer, particleboard, oriented
strandboard, hardboard, fiberboard, medium density fiberboard, laminated
strand lumber, laminated veneer lumber, wood I-joists, kiln-dried
lumber, and glue-laminated beams.
(b) The PCWP manufacturing facility is located at a major source of
HAP emissions. A major source of HAP emissions is any stationary source
or group of stationary sources within a contiguous area and under common
control that emits or has the potential to emit any single HAP at a rate
of 9.07 megagrams (10 tons) or more per year or any combination of HAP
at a rate of 22.68 megagrams (25 tons) or more per year.
Sec. 63.2232 What parts of my plant does this subpart cover?
(a) This subpart applies to each new, reconstructed, or existing
affected source at a PCWP manufacturing facility.
(b) The affected source is the collection of dryers, refiners,
blenders, formers, presses, board coolers, and other process units
associated with the manufacturing of plywood and composite wood
products. The affected source includes, but is not limited to, green end
operations, refining, drying operations (including any combustion unit
exhaust stream routinely used to direct fire process unit(s)), resin
preparation, blending and forming operations, pressing and board cooling
operations, and miscellaneous finishing
[[Page 222]]
operations (such as sanding, sawing, patching, edge sealing, and other
finishing operations not subject to other national emission standards
for hazardous air pollutants (NESHAP)). The affected source also
includes onsite storage and preparation of raw materials used in the
manufacture of plywood and/or composite wood products, such as resins;
onsite wastewater treatment operations specifically associated with
plywood and composite wood products manufacturing; and miscellaneous
coating operations (Sec. 63.2292). The affected source includes lumber
kilns at PCWP manufacturing facilities and at any other kind of
facility.
(c) An affected source is a new affected source if you commenced
construction of the affected source after January 9, 2003, and you meet
the applicability criteria at the time you commenced construction.
(d) An affected source is reconstructed if you meet the criteria as
defined in Sec. 63.2.
(e) An affected source is existing if it is not new or
reconstructed.
[69 FR 46011, July 30, 2004, as amended at 71 FR 8371, Feb. 16, 2006]
Sec. 63.2233 When do I have to comply with this subpart?
(a) If you have a new or reconstructed affected source, you must
comply with this subpart according to paragraph (a)(1) or (2) of this
section, whichever is applicable.
(1) If the initial startup of your affected source is before
September 28, 2004, then you must comply with the compliance options,
operating requirements, and work practice requirements for new and
reconstructed sources in this subpart no later than September 28, 2004.
(2) If the initial startup of your affected source is after
September 28, 2004, then you must comply with the compliance options,
operating requirements, and work practice requirements for new and
reconstructed sources in this subpart upon initial startup of your
affected source.
(b) If you have an existing affected source, you must comply with
the compliance options, operating requirements, and work practice
requirements for existing sources no later than October 1, 2008.
(c) If you have an area source that increases its emissions or its
potential to emit such that it becomes a major source of HAP, you must
be in compliance with this subpart by October 1, 2008 or upon initial
startup of your affected source as a major source, whichever is later.
(d) You must meet the notification requirements according to the
schedule in Sec. 63.2280 and according to 40 CFR part 63, subpart A.
Some of the notifications must be submitted before you are required to
comply with the compliance options, operating requirements, and work
practice requirements in this subpart.
[69 FR 46011, July 30, 2004, as amended at 71 FR 8372, Feb. 16, 2006]
Compliance Options, Operating Requirements, and Work Practice
Requirements
Sec. 63.2240 What are the compliance options and operating requirements
and how must I meet them?
You must meet the compliance options and operating requirements
described in Tables 1A, 1B, and 2 to this subpart and in paragraph (c)
of this section by using one or more of the compliance options listed in
paragraphs (a), (b), and (c) of this section. The process units subject
to the compliance options are listed in Tables 1A and 1B to this subpart
and are defined in Sec. 63.2292. You need only to meet one of the
compliance options outlined in paragraphs (a) through (c) of this
section for each process unit. You cannot combine compliance options in
paragraph (a), (b), or (c) for a single process unit. (For example, you
cannot use a production-based compliance option in paragraph (a) for one
vent of a veneer dryer and an add-on control system compliance option in
paragraph (b) for another vent on the same veneer dryer. You must use
either the production-based compliance option or an add-on control
system compliance option for the entire dryer.)
(a) Production-based compliance options. You must meet the
production-based total HAP compliance options in
[[Page 223]]
Table 1A to this subpart and the applicable operating requirements in
Table 2 to this subpart. You may not use an add-on control system or wet
control device to meet the production-based compliance options.
(b) Compliance options for add-on control systems. You must use an
emissions control system and demonstrate that the resulting emissions
meet the compliance options and operating requirements in Tables 1B and
2 to this subpart. If you own or operate a reconstituted wood product
press at a new or existing affected source or a reconstituted wood
product board cooler at a new affected source, and you choose to comply
with one of the concentration-based compliance options for a control
system outlet (presented as option numbers 2, 4, and 6 in Table 1B to
this subpart), you must have a capture device that either meets the
definition of wood products enclosure in Sec. 63.2292 or achieves a
capture efficiency of greater than or equal to 95 percent.
(c) Emissions averaging compliance option (for existing sources
only). Using the procedures in paragraphs (c)(1) through (3) of this
section, you must demonstrate that emissions included in the emissions
average meet the compliance options and operating requirements. New
sources may not use emissions averaging to comply with this subpart.
(1) Calculation of required and actual mass removal. Limit emissions
of total HAP, as defined in Sec. 63.2292, to include acetaldehyde,
acrolein, formaldehyde, methanol, phenol, and propionaldehyde from your
affected source to the standard specified by Equations 1, 2, and 3 of
this section.
[GRAPHIC] [TIFF OMITTED] TR72AD04.000
[GRAPHIC] [TIFF OMITTED] TR72AD04.001
[GRAPHIC] [TIFF OMITTED] TR72AD04.002
Where:
RMR = required mass removal of total HAP from all process units
generating debits (i.e., all process units that are subject to the
compliance options in Tables 1A and 1B to this subpart and that are
either uncontrolled or under-controlled), pounds per semiannual period;
AMR = actual mass removal of total HAP from all process units generating
credits (i.e., all process units that are controlled as part of the
Emissions Averaging Plan including credits from debit-generating process
units that are under-controlled), pounds per semiannual period;
UCEPi = mass of total HAP from an uncontrolled or under-
controlled process unit (i) that generates debits, pounds per hour;
OHi = number of hours a process unit (i) is operated during
the semiannual period, hours per 6-month period;
CDi = control system efficiency for the emission point (i)
for total HAP, expressed as a fraction, and not to exceed 90 percent,
unitless (Note: To calculate the control system efficiency of biological
treatment units that do not meet the definition of biofilter in Sec.
63.2292, you must use 40 CFR part 63, appendix C, Determination of the
Fraction Biodegraded (Fbio) in a Biological Treatment Unit.);
OCEPi = mass of total HAP from a process unit (i) that
generates credits (including credits from debit-generating process units
that are under-controlled), pounds per hour;
0.90 = required control system efficiency of 90 percent multiplied,
unitless.
(2) Requirements for debits and credits. You must calculate debits
and credits as specified in paragraphs (c)(2)(i) through (vi) of this
section.
(i) You must limit process units in the emissions average to those
process units located at the existing affected source as defined in
Sec. 63.2292.
(ii) You cannot use nonoperating process units to generate emissions
averaging credits. You cannot use process units that are shut down to
generate emissions averaging debits or credits.
(iii) You may not include in your emissions average process units
controlled to comply with a State, Tribal, or Federal rule other than
this subpart.
(iv) You must use actual measurements of total HAP emissions from
process units to calculate your required mass removal (RMR) and actual
mass removal (AMR). The total HAP measurements must be obtained
according to Sec. 63.2262(b) through (d), (g), and (h), using the
methods specified in Table 4 to this subpart.
(v) Your initial demonstration that the credit-generating process
units will be capable of generating enough credits
[[Page 224]]
to offset the debits from the debit-generating process units must be
made under representative operating conditions. After the compliance
date, you must use actual operating data for all debit and credit
calculations.
(vi) Do not include emissions from the following time periods in
your emissions averaging calculations:
(A) Emissions during periods of startup, shutdown, and malfunction
as described in the startup, shutdown, and malfunction plan (SSMP).
(B) Emissions during periods of monitoring malfunctions, associated
repairs, and required quality assurance or control activities or during
periods of control device maintenance covered in your routine control
device maintenance exemption. No credits may be assigned to credit-
generating process units, and maximum debits must be assigned to debit-
generating process units during these periods.
(3) Operating requirements. You must meet the operating requirements
in Table 2 to this subpart for each process unit or control device used
in calculation of emissions averaging credits.
Sec. 63.2241 What are the work practice requirements and how must I
meet them?
(a) You must meet each work practice requirement in Table 3 to this
subpart that applies to you.
(b) As provided in Sec. 63.6(g), we, the EPA, may choose to grant
you permission to use an alternative to the work practice requirements
in this section.
(c) If you have a dry rotary dryer, you may choose to designate your
dry rotary dryer as a green rotary dryer and meet the more stringent
compliance options and operating requirements in Sec. 63.2240 for green
rotary dryers instead of the work practices for dry rotary dryers. If
you have a hardwood veneer dryer or veneer redryer, you may choose to
designate your hardwood veneer dryer or veneer redryer as a softwood
veneer dryer and meet the more stringent compliance options and
operating requirements in Sec. 63.2240 for softwood veneer dryer heated
zones instead of the work practices for hardwood veneer dryers or veneer
redryers.
General Compliance Requirements
Sec. 63.2250 What are the general requirements?
(a) You must be in compliance with the compliance options, operating
requirements, and the work practice requirements in this subpart at all
times, except during periods of process unit or control device startup,
shutdown, and malfunction; prior to process unit initial startup; and
during the routine control device maintenance exemption specified in
Sec. 63.2251. The compliance options, operating requirements, and work
practice requirements do not apply during times when the process unit(s)
subject to the compliance options, operating requirements, and work
practice requirements are not operating, or during periods of startup,
shutdown, and malfunction. Startup and shutdown periods must not exceed
the minimum amount of time necessary for these events.
(b) You must always operate and maintain your affected source,
including air pollution control and monitoring equipment, according to
the provisions in Sec. 63.6(e)(1)(i).
(c) You must develop a written SSMP according to the provisions in
Sec. 63.6(e)(3).
(d) Shutoff of direct-fired burners resulting from partial and full
production stoppages of direct-fired softwood veneer dryers or over-
temperature events shall be deemed shutdowns and not malfunctions.
Lighting or re-lighting any one or all gas burners in direct-fired
softwood veneer dryers shall be deemed startups and not malfunctions.
[69 FR 46011, July 30, 2004, as amended at 71 FR 8372, Feb. 16, 2006; 71
FR 20463, Apr. 20, 2006]
Sec. 63.2251 What are the requirements for the routine control device
maintenance exemption?
(a) You may request a routine control device maintenance exemption
from the EPA Administrator for routine maintenance events such as
control device bakeouts, washouts, media replacement, and replacement of
corroded parts. Your request must justify the need for the routine
maintenance on the control device and the time required to accomplish
the maintenance
[[Page 225]]
activities, describe the maintenance activities and the frequency of the
maintenance activities, explain why the maintenance cannot be
accomplished during process shutdowns, describe how you plan to make
reasonable efforts to minimize emissions during the maintenance, and
provide any other documentation required by the EPA Administrator.
(b) The routine control device maintenance exemption must not exceed
the percentages of process unit operating uptime in paragraphs (b)(1)
and (2) of this section.
(1) If the control device is used to control a green rotary dryer,
tube dryer, rotary strand dryer, or pressurized refiner, then the
routine control device maintenance exemption must not exceed 3 percent
of annual operating uptime for each process unit controlled.
(2) If the control device is used to control a softwood veneer
dryer, reconstituted wood product press, reconstituted wood product
board cooler, hardboard oven, press predryer, conveyor strand dryer, or
fiberboard mat dryer, then the routine control device maintenance
exemption must not exceed 0.5 percent of annual operating uptime for
each process unit controlled.
(3) If the control device is used to control a combination of
equipment listed in both paragraphs (b)(1) and (2) of this section, such
as a tube dryer and a reconstituted wood product press, then the routine
control device maintenance exemption must not exceed 3 percent of annual
operating uptime for each process unit controlled.
(c) The request for the routine control device maintenance
exemption, if approved by the EPA Administrator, must be IBR in and
attached to the affected source's title V permit.
(d) The compliance options and operating requirements do not apply
during times when control device maintenance covered under your approved
routine control device maintenance exemption is performed. You must
minimize emissions to the greatest extent possible during these routine
control device maintenance periods.
(e) To the extent practical, startup and shutdown of emission
control systems must be scheduled during times when process equipment is
also shut down.
Sec. 63.2252 What are the requirements for process units that have no
control or work practice requirements?
For process units not subject to the compliance options or work
practice requirements specified in Sec. 63.2240 (including, but not
limited to, lumber kilns), you are not required to comply with the
compliance options, work practice requirements, performance testing,
monitoring, SSM plans, and recordkeeping or reporting requirements of
this subpart, or any other requirements in subpart A of this part,
except for the initial notification requirements in Sec. 63.9(b).
[71 FR 8372, Feb. 16, 2006]
Initial Compliance Requirements
Sec. 63.2260 How do I demonstrate initial compliance with the
compliance options, operating requirements, and work practice requirements?
(a) To demonstrate initial compliance with the compliance options
and operating requirements, you must conduct performance tests and
establish each site-specific operating requirement in Table 2 to this
subpart according to the requirements in Sec. 63.2262 and Table 4 to
this subpart. Combustion units that accept process exhausts into the
flame zone are exempt from the initial performance testing and operating
requirements for thermal oxidizers.
(b) You must demonstrate initial compliance with each compliance
option, operating requirement, and work practice requirement that
applies to you according to Tables 5 and 6 to this subpart and according
to Sec. Sec. 63.2260 through 63.2269 of this subpart.
(c) You must submit the Notification of Compliance Status containing
the results of the initial compliance demonstration according to the
requirements in Sec. 63.2280(d).
Sec. 63.2261 By what date must I conduct performance tests or other
initial compliance demonstrations?
(a) You must conduct performance tests upon initial startup or no
later
[[Page 226]]
than 180 calendar days after the compliance date that is specified for
your source in Sec. 63.2233 and according to Sec. 63.7(a)(2),
whichever is later.
(b) You must conduct initial compliance demonstrations that do not
require performance tests upon initial startup or no later than 30
calendar days after the compliance date that is specified for your
source in Sec. 63.2233, whichever is later.
Sec. 63.2262 How do I conduct performance tests and establish operating
requirements?
(a) You must conduct each performance test according to the
requirements in Sec. 63.7(e)(1), the requirements in paragraphs (b)
through (o) of this section, and according to the methods specified in
Table 4 to this subpart.
(b) Periods when performance tests must be conducted. (1) You must
not conduct performance tests during periods of startup, shutdown, or
malfunction, as specified in Sec. 63.7(e)(1).
(2) You must test under representative operating conditions as
defined in Sec. 63.2292. You must describe representative operating
conditions in your performance test report for the process and control
systems and explain why they are representative.
(c) Number of test runs. You must conduct three separate test runs
for each performance test required in this section as specified in Sec.
63.7(e)(3). Each test run must last at least 1 hour except for: testing
of a temporary total enclosure (TTE) conducted using Methods 204A
through 204F of 40 CFR part 51, appendix M, which require three separate
test runs of at least 3 hours each; and testing of an enclosure
conducted using the alternative tracer gas method in appendix A to this
subpart, which requires a minimum of three separate runs of at least 20
minutes each.
(d) Location of sampling sites. (1) Sampling sites must be located
at the inlet (if emission reduction testing or documentation of inlet
methanol or formaldehyde concentration is required) and outlet of the
control device (defined in Sec. 63.2292) and prior to any releases to
the atmosphere. For control sequences with wet control devices (defined
in Sec. 63.2292) followed by control devices (defined in Sec.
63.2292), sampling sites may be located at the inlet and outlet of the
control sequence and prior to any releases to the atmosphere.
(2) Sampling sites for process units meeting compliance options
without a control device must be located prior to any releases to the
atmosphere. Facilities demonstrating compliance with a production-based
compliance option for a process unit equipped with a wet control device
must locate sampling sites prior to the wet control device.
(e) Collection of monitoring data. You must collect operating
parameter monitoring system or continuous emissions monitoring system
(CEMS) data at least every 15 minutes during the entire performance test
and determine the parameter or concentration value for the operating
requirement during the performance test using the methods specified in
paragraphs (k) through (o) of this section.
(f) Collection of production data. To comply with any of the
production-based compliance options, you must measure and record the
process unit throughput during each performance test.
(g) Nondetect data. (1) Except as specified in paragraph (g)(2) of
this section, all nondetect data (Sec. 63.2292) must be treated as one-
half of the method detection limit when determining total HAP,
formaldehyde, methanol, or total hydrocarbon (THC) emission rates.
(2) When showing compliance with the production-based compliance
options in Table 1A to this subpart, you may treat emissions of an
individual HAP as zero if all three of the performance test runs result
in a nondetect measurement, and the method detection limit is less than
or equal to 1 parts per million by volume, dry basis (ppmvd). Otherwise,
nondetect data for individual HAP must be treated as one-half of the
method detection limit.
(h) Calculation of percent reduction across a control system. When
determining the control system efficiency for any control system
included in your emissions averaging plan (not to exceed 90 percent) and
when complying with any of the compliance options based on percent
reduction across a
[[Page 227]]
control system in Table 1B to this subpart, as part of the performance
test, you must calculate the percent reduction using Equation 1 of this
section:
[GRAPHIC] [TIFF OMITTED] TR72AD04.003
Where:
PR = percent reduction, percent;
CE = capture efficiency, percent (determined for reconstituted wood
product presses and board coolers as required in Table 4 to this
subpart);
ERin = emission rate of total HAP (calculated as the sum of
the emission rates of acetaldehyde, acrolein, formaldehyde, methanol,
phenol, and propionaldehyde), THC, formaldehyde, or methanol in the
inlet vent stream of the control device, pounds per hour;
ERout = emission rate of total HAP (calculated as the sum of
the emission rates of acetaldehyde, acrolein, formaldehyde, methanol,
phenol, and propionaldehyde), THC, formaldehyde, or methanol in the
outlet vent stream of the control device, pounds per hour.
(i) Calculation of mass per unit production. To comply with any of
the production-based compliance options in Table 1A to this subpart, you
must calculate your mass per unit production emissions for each
performance test run using Equation 2 of this section:
[GRAPHIC] [TIFF OMITTED] TR72AD04.004
Where:
MP = mass per unit production, pounds per oven dried ton OR pounds per
thousand square feet on a specified thickness basis (see paragraph (j)
of this section if you need to convert from one thickness basis to
another);
ERHAP = emission rate of total HAP (calculated as the sum of
the emission rates of acetaldehyde, acrolein, formaldehyde, methanol,
phenol, and propionaldehyde) in the stack, pounds per hour;
P = process unit production rate (throughput), oven dried tons per hour
OR thousand square feet per hour on a specified thickness basis;
CE = capture efficiency, percent (determined for reconstituted wood
product presses and board coolers as required in Table 4 to this
subpart).
(j) Thickness basis conversion. Use Equation 3 of this section to
convert from one thickness basis to another:
[GRAPHIC] [TIFF OMITTED] TR72AD04.005
Where:
MSFA = thousand square feet on an A-inch basis;
MSFB = thousand square feet on a B-inch basis;
A = old thickness you are converting from, inches;
B = new thickness you are converting to, inches.
(k) Establishing thermal oxidizer operating requirements. If you
operate a thermal oxidizer, you must establish your thermal oxidizer
operating parameters according to paragraphs (k)(1) through (3) of this
section.
(1) During the performance test, you must continuously monitor the
firebox temperature during each of the required 1-hour test runs. For
regenerative thermal oxidizers, you may measure the temperature in
multiple locations (e.g., one location per burner) in the combustion
chamber and calculate the average of the temperature measurements prior
to reducing the temperature data to 15-minute averages for purposes of
establishing your minimum firebox temperature. The minimum firebox
temperature must then be established as the average of the three minimum
15-minute firebox temperatures monitored during the three test runs.
Multiple three-run performance tests may be conducted to establish a
range of parameter values under different operating conditions.
(2) You may establish a different minimum firebox temperature for
your thermal oxidizer by submitting the notification specified in Sec.
63.2280(g) and conducting a repeat performance test as specified in
paragraph (k)(1) of this section that demonstrates compliance with the
applicable compliance options of this subpart.
(3) If your thermal oxidizer is a combustion unit that accepts
process exhaust into the flame zone, then you are exempt from the
performance testing and monitoring requirements specified in paragraphs
(k)(1) and (2) of this section. To demonstrate initial compliance, you
must submit documentation with your Notification of Compliance Status
showing that process exhausts
[[Page 228]]
controlled by the combustion unit enter into the flame zone.
(l) Establishing catalytic oxidizer operating requirements. If you
operate a catalytic oxidizer, you must establish your catalytic oxidizer
operating parameters according to paragraphs (l)(1) and (2) of this
section.
(1) During the performance test, you must continuously monitor
during the required 1-hour test runs either the temperature at the inlet
to each catalyst bed or the temperature in the combustion chamber. For
regenerative catalytic oxidizers, you must calculate the average of the
temperature measurements from each catalyst bed inlet or within the
combustion chamber prior to reducing the temperature data to 15-minute
averages for purposes of establishing your minimum catalytic oxidizer
temperature. The minimum catalytic oxidizer temperature must then be
established as the average of the three minimum 15-minute temperatures
monitored during the three test runs. Multiple three-run performance
tests may be conducted to establish a range of parameter values under
different operating conditions.
(2) You may establish a different minimum catalytic oxidizer
temperature by submitting the notification specified in Sec. 63.2280(g)
and conducting a repeat performance test as specified in paragraphs
(l)(1) and (2) of this section that demonstrates compliance with the
applicable compliance options of this subpart.
(m) Establishing biofilter operating requirements. If you operate a
biofilter, you must establish your biofilter operating requirements
according to paragraphs (m)(1) through (3) of this section.
(1) During the performance test, you must continuously monitor the
biofilter bed temperature during each of the required 1-hour test runs.
To monitor biofilter bed temperature, you may use multiple thermocouples
in representative locations throughout the biofilter bed and calculate
the average biofilter bed temperature across these thermocouples prior
to reducing the temperature data to 15-minute averages for purposes of
establishing biofilter bed temperature limits. The biofilter bed
temperature range must be established as the minimum and maximum 15-
minute biofilter bed temperatures monitored during the three test runs.
You may base your biofilter bed temperature range on values recorded
during previous performance tests provided that the data used to
establish the temperature ranges have been obtained using the test
methods required in this subpart. If you use data from previous
performance tests, you must certify that the biofilter and associated
process unit(s) have not been modified subsequent to the date of the
performance tests. Replacement of the biofilter media with the same type
of material is not considered a modification of the biofilter for
purposes of this section.
(2) For a new biofilter installation, you will be allowed up to 180
days following the compliance date or 180 days following initial startup
of the biofilter to complete the requirements in paragraph (m)(1) of
this section.
(3) You may expand your biofilter bed temperature operating range by
submitting the notification specified in Sec. 63.2280(g) and conducting
a repeat performance test as specified in paragraph (m)(1) of this
section that demonstrates compliance with the applicable compliance
options of this subpart.
(n) Establishing operating requirements for process units meeting
compliance options without a control device. If you operate a process
unit that meets a compliance option in Table 1A to this subpart, or is a
process unit that generates debits in an emissions average without the
use of a control device, you must establish your process unit operating
parameters according to paragraphs (n)(1) through (2) of this section.
(1) During the performance test, you must identify and document the
process unit controlling parameter(s) that affect total HAP emissions
during the three-run performance test. The controlling parameters you
identify must coincide with the representative operating conditions you
describe according to Sec. 63.2262(b)(2). For each parameter, you must
specify appropriate monitoring methods, monitoring frequencies, and for
continuously monitored parameters, averaging times not to exceed 24
hours. The operating limit for each controlling parameter must then be
established as the minimum,
[[Page 229]]
maximum, range, or average (as appropriate depending on the parameter)
recorded during the performance test. Multiple three-run performance
tests may be conducted to establish a range of parameter values under
different operating conditions.
(2) You may establish different controlling parameter limits for
your process unit by submitting the notification specified in Sec.
63.2280(g) and conducting a repeat performance test as specified in
paragraph (n)(1) of this section that demonstrates compliance with the
compliance options in Table 1A to this subpart or is used to establish
emission averaging debits for an uncontrolled process unit.
(o) Establishing operating requirements using THC CEMS. If you
choose to meet the operating requirements by monitoring THC
concentration instead of monitoring control device or process operating
parameters, you must establish your THC concentration operating
requirement according to paragraphs (o)(1) through (2) of this section.
(1) During the performance test, you must continuously monitor THC
concentration using your CEMS during each of the required 1-hour test
runs. The maximum THC concentration must then be established as the
average of the three maximum 15-minute THC concentrations monitored
during the three test runs. Multiple three-run performance tests may be
conducted to establish a range of THC concentration values under
different operating conditions.
(2) You may establish a different maximum THC concentration by
submitting the notification specified in Sec. 63.2280(g) and conducting
a repeat performance test as specified in paragraph (o)(1) of this
section that demonstrates compliance with the compliance options in
Tables 1A and 1B to this subpart.
[69 FR 46011, July 30, 2004, as amended at 71 FR 8372, Feb. 16, 2006]
Sec. 63.2263 Initial compliance demonstration for a dry rotary dryer.
If you operate a dry rotary dryer, you must demonstrate that your
dryer processes furnish with an inlet moisture content of less than or
equal to 30 percent (by weight, dry basis) and operates with a dryer
inlet temperature of less than or equal to 600 [deg]F. You must
designate and clearly identify each dry rotary dryer. You must record
the inlet furnish moisture content (dry basis) and inlet dryer operating
temperature according to Sec. 63.2269(a), (b), and (c) and Sec.
63.2270 for a minimum of 30 calendar days. You must submit the highest
recorded 24-hour average inlet furnish moisture content and the highest
recorded 24-hour average dryer inlet temperature with your Notification
of Compliance Status. In addition, you must submit with the Notification
of Compliance Status a signed statement by a responsible official that
certifies with truth, accuracy, and completeness that the dry rotary
dryer will dry furnish with a maximum inlet moisture content less than
or equal to 30 percent (by weight, dry basis) and will operate with a
maximum inlet temperature of less than or equal to 600 [deg]F in the
future.
Sec. 63.2264 Initial compliance demonstration for a hardwood veneer
dryer.
If you operate a hardwood veneer dryer, you must record the annual
volume percentage of softwood veneer species processed in the dryer as
follows:
(a) Use Equation 1 of this section to calculate the annual volume
percentage of softwood species dried:
[GRAPHIC] [TIFF OMITTED] TR72AD04.006
Where:
SW% = annual volume percent softwood species dried;
SW = softwood veneer dried during the previous 12 months, thousand
square feet (\3/8\-inch basis);
T = total softwood and hardwood veneer dried during the previous 12
months, thousand square feet (\3/8\-inch basis).
(b) You must designate and clearly identify each hardwood veneer
dryer. Submit with the Notification of Compliance Status the annual
volume percentage of softwood species dried in the dryer based on your
dryer production for the 12 months prior to the compliance date
specified for your source in Sec. 63.2233. If you did not dry any
softwood species in the dryer during the 12 months prior to the
compliance
[[Page 230]]
date, then you need only to submit a statement indicating that no
softwood species were dried. In addition, submit with the Notification
of Compliance Status a signed statement by a responsible official that
certifies with truth, accuracy, and completeness that the veneer dryer
will be used to process less than 30 volume percent softwood species in
the future.
Sec. 63.2265 Initial compliance demonstration for a softwood veneer
dryer.
If you operate a softwood veneer dryer, you must develop a plan for
review and approval for minimizing fugitive emissions from the veneer
dryer heated zones, and you must submit the plan with your Notification
of Compliance Status.
Sec. 63.2266 Initial compliance demonstration for a veneer redryer.
If you operate a veneer redryer, you must record the inlet moisture
content of the veneer processed in the redryer according to Sec.
63.2269(a) and (c) and Sec. 63.2270 for a minimum of 30 calendar days.
You must designate and clearly identify each veneer redryer. You must
submit the highest recorded 24-hour average inlet veneer moisture
content with your Notification of Compliance Status to show that your
veneer redryer processes veneer with an inlet moisture content of less
than or equal to 25 percent (by weight, dry basis). In addition, submit
with the Notification of Compliance Status a signed statement by a
responsible official that certifies with truth, accuracy, and
completeness that the veneer redryer will dry veneer with a moisture
content less than 25 percent (by weight, dry basis) in the future.
Sec. 63.2267 Initial compliance demonstration for a reconstituted wood
product press or board cooler.
If you operate a reconstituted wood product press at a new or
existing affected source or a reconstituted wood product board cooler at
a new affected source, then you must either use a wood products
enclosure as defined in Sec. 63.2292 or measure the capture efficiency
of the capture device for the press or board cooler using Methods 204
and 204A through 204F of 40 CFR part 51, appendix M (as appropriate), or
using the alternative tracer gas method contained in appendix A to this
subpart. You must submit documentation that the wood products enclosure
meets the press enclosure design criteria in Sec. 63.2292 or the
results of the capture efficiency verification with your Notification of
Compliance Status.
Sec. 63.2268 Initial compliance demonstration for a wet control device.
If you use a wet control device as the sole means of reducing HAP
emissions, you must develop and implement a plan for review and approval
to address how organic HAP captured in the wastewater from the wet
control device is contained or destroyed to minimize re-release to the
atmosphere such that the desired emissions reductions are obtained. You
must submit the plan with your Notification of Compliance Status.
Sec. 63.2269 What are my monitoring installation, operation, and
maintenance requirements?
(a) General continuous parameter monitoring requirements. You must
install, operate, and maintain each continuous parameter monitoring
system (CPMS) according to paragraphs (a)(1) through (3) of this
section.
(1) The CPMS must be capable of completing a minimum of one cycle of
operation (sampling, analyzing, and recording) for each successive 15-
minute period.
(2) At all times, you must maintain the monitoring equipment
including, but not limited to, maintaining necessary parts for routine
repairs of the monitoring equipment.
(3) Record the results of each inspection, calibration, and
validation check.
(b) Temperature monitoring. For each temperature monitoring device,
you must meet the requirements in paragraphs (a) and (b)(1) through (6)
of this section.
(1) Locate the temperature sensor in a position that provides a
representative temperature.
[[Page 231]]
(2) Use a temperature sensor with a minimum accuracy of 4 [deg]F or
0.75 percent of the temperature value, whichever is larger.
(3) If a chart recorder is used, it must have a sensitivity with
minor divisions not more than 20 [deg]F.
(4) Perform an electronic calibration at least semiannually
according to the procedures in the manufacturer's owners manual.
Following the electronic calibration, you must conduct a temperature
sensor validation check in which a second or redundant temperature
sensor placed nearby the process temperature sensor must yield a reading
within 30 [deg]F of the process temperature sensor's reading.
(5) Conduct calibration and validation checks any time the sensor
exceeds the manufacturer's specified maximum operating temperature range
or install a new temperature sensor.
(6) At least quarterly, inspect all components for integrity and all
electrical connections for continuity, oxidation, and galvanic
corrosion.
(c) Wood moisture monitoring. For each furnish or veneer moisture
meter, you must meet the requirements in paragraphs (a)(1) through (3)
and paragraphs (c)(1) through (5) of this section.
(1) For dry rotary dryers, use a continuous moisture monitor with a
minimum accuracy of 1 percent (dry basis) moisture or better in the 25
to 35 percent (dry basis) moisture content range. For veneer redryers,
use a continuous moisture monitor with a minimum accuracy of 3 percent
(dry basis) moisture or better in the 15 to 25 percent (dry basis)
moisture content range. Alternatively, you may use a continuous moisture
monitor with a minimum accuracy of 5 percent (dry basis) moisture or
better for dry rotary dryers used to dry furnish with less than 25
percent (dry basis) moisture or for veneer redryers used to redry veneer
with less than 20 percent (dry basis) moisture.
(2) Locate the moisture monitor in a position that provides a
representative measure of furnish or veneer moisture.
(3) Calibrate the moisture monitor based on the procedures specified
by the moisture monitor manufacturer at least once per semiannual
compliance period (or more frequently if recommended by the moisture
monitor manufacturer).
(4) At least quarterly, inspect all components of the moisture
monitor for integrity and all electrical connections for continuity.
(5) Use Equation 1 of this section to convert percent moisture
measurements wet basis to a dry basis:
[GRAPHIC] [TIFF OMITTED] TR72AD04.012
Where:
MCdry = percent moisture content of wood material (weight
percent, dry basis);
MCwet = percent moisture content of wood material (weight
percent, wet basis).
(d) Continuous emission monitoring system(s). Each CEMS must be
installed, operated, and maintained according to paragraphs (d)(1)
through (4) of this section.
(1) Each CEMS for monitoring THC concentration must be installed,
operated, and maintained according to Performance Specification 8 of 40
CFR part 60, appendix B. You must also comply with Procedure 1 of 40 CFR
part 60, appendix F.
(2) You must conduct a performance evaluation of each CEMS according
to the requirements in Sec. 63.8 and according to Performance
Specification 8 of 40 CFR part 60, appendix B.
(3) As specified in Sec. 63.8(c)(4)(ii), each CEMS must complete a
minimum of one cycle of operation (sampling, analyzing, and data
recording) for each successive 15-minute period.
(4) The CEMS data must be reduced as specified in Sec. 63.8(g)(2)
and Sec. 63.2270(d) and (e).
[69 FR 46011, July 30, 2004, as amended at 71 FR 8372, Feb. 16, 2006]
Continuous Compliance Requirements
Sec. 63.2270 How do I monitor and collect data to demonstrate
continuous compliance?
(a) You must monitor and collect data according to this section.
(b) Except for, as appropriate, monitor malfunctions, associated
repairs, and required quality assurance or control activities
(including, as applicable, calibration checks and required zero
[[Page 232]]
and span adjustments), you must conduct all monitoring in continuous
operation at all times that the process unit is operating. For purposes
of calculating data averages, you must not use data recorded during
monitoring malfunctions, associated repairs, out-of-control periods, or
required quality assurance or control activities. You must use all the
data collected during all other periods in assessing compliance. A
monitoring malfunction is any sudden, infrequent, not reasonably
preventable failure of the monitoring to provide valid data. Monitoring
failures that are caused in part by poor maintenance or careless
operation are not malfunctions. Any period for which the monitoring
system is out-of-control and data are not available for required
calculations constitutes a deviation from the monitoring requirements.
(c) You may not use data recorded during monitoring malfunctions,
associated repairs, and required quality assurance or control
activities; data recorded during periods of startup, shutdown, and
malfunction; or data recorded during periods of control device downtime
covered in any approved routine control device maintenance exemption in
data averages and calculations used to report emission or operating
levels, nor may such data be used in fulfilling a minimum data
availability requirement, if applicable. You must use all the data
collected during all other periods in assessing the operation of the
control system.
(d) Except as provided in paragraph (e) of this section, determine
the 3-hour block average of all recorded readings, calculated after
every 3 hours of operation as the average of the evenly spaced recorded
readings in the previous 3 operating hours (excluding periods described
in paragraphs (b) and (c) of this section).
(e) For dry rotary dryer and veneer redryer wood moisture
monitoring, dry rotary dryer temperature monitoring, biofilter bed
temperature monitoring, and biofilter outlet THC monitoring, determine
the 24-hour block average of all recorded readings, calculated after
every 24 hours of operation as the average of the evenly spaced recorded
readings in the previous 24 operating hours (excluding periods described
in paragraphs (b) and (c) of this section).
(f) To calculate the data averages for each 3-hour or 24-hour
averaging period, you must have at least 75 percent of the required
recorded readings for that period using only recorded readings that are
based on valid data (i.e., not from periods described in paragraphs (b)
and (c) of this section).
Sec. 63.2271 How do I demonstrate continuous compliance with the
compliance options, operating requirements, and work practice requirements?
(a) You must demonstrate continuous compliance with the compliance
options, operating requirements, and work practice requirements in
Sec. Sec. 63.2240 and 63.2241 that apply to you according to the
methods specified in Tables 7 and 8 to this subpart.
(b) You must report each instance in which you did not meet each
compliance option, operating requirement, and work practice requirement
in Tables 7 and 8 to this subpart that applies to you. This includes
periods of startup, shutdown, and malfunction and periods of control
device maintenance specified in paragraphs (b)(1) through (3) of this
section. These instances are deviations from the compliance options,
operating requirements, and work practice requirements in this subpart.
These deviations must be reported according to the requirements in Sec.
63.2281.
(1) [Reserved]
(2) Consistent with Sec. Sec. 63.6(e) and 63.7(e)(1), deviations
that occur during a period of startup, shutdown, or malfunction are not
violations if you demonstrate to the EPA Administrator's satisfaction
that you were operating in accordance with Sec. 63.6(e)(1). The EPA
Administrator will determine whether deviations that occur during a
period of startup, shutdown, or malfunction are violations, according to
the provisions in Sec. 63.6(e).
(3) Deviations that occur during periods of control device
maintenance covered by any approved routine control device maintenance
exemption are not violations if you demonstrate to the EPA
Administrator's satisfaction that you were operating in accordance with
[[Page 233]]
the approved routine control device maintenance exemption.
[69 FR 46011, July 30, 2004, as amended at 71 FR 20463, Apr. 20, 2006]
Notifications, Reports, and Records
Sec. 63.2280 What notifications must I submit and when?
(a) You must submit all of the notifications in Sec. Sec. 63.7(b)
and (c), 63.8(e), (f)(4) and (f)(6), 63.9 (b) through (e), and (g) and
(h) by the dates specified.
(b) You must submit an Initial Notification no later than 120
calendar days after September 28, 2004, or after initial startup,
whichever is later, as specified in Sec. 63.9(b)(2).
(c) If you are required to conduct a performance test, you must
submit a written notification of intent to conduct a performance test at
least 60 calendar days before the performance test is scheduled to begin
as specified in Sec. 63.7(b)(1).
(d) If you are required to conduct a performance test, design
evaluation, or other initial compliance demonstration as specified in
Tables 4, 5, and 6 to this subpart, you must submit a Notification of
Compliance Status as specified in Sec. 63.9(h)(2)(ii).
(1) For each initial compliance demonstration required in Table 5 or
6 to this subpart that does not include a performance test, you must
submit the Notification of Compliance Status before the close of
business on the 30th calendar day following the completion of the
initial compliance demonstration.
(2) For each initial compliance demonstration required in Tables 5
and 6 to this subpart that includes a performance test conducted
according to the requirements in Table 4 to this subpart, you must
submit the Notification of Compliance Status, including the performance
test results, before the close of business on the 60th calendar day
following the completion of the performance test according to Sec.
63.10(d)(2).
(e) If you request a routine control device maintenance exemption
according to Sec. 63.2251, you must submit your request for the
exemption no later than 30 days before the compliance date.
(f) If you use the emissions averaging compliance option in Sec.
63.2240(c), you must submit an Emissions Averaging Plan to the EPA
Administrator for approval no later than 1 year before the compliance
date or no later than 1 year before the date you would begin using an
emissions average, whichever is later. The Emissions Averaging Plan must
include the information in paragraphs (f)(1) through (6) of this
section.
(1) Identification of all the process units to be included in the
emissions average indicating which process units will be used to
generate credits, and which process units that are subject to compliance
options in Tables 1A and 1B to this subpart will be uncontrolled (used
to generate debits) or under-controlled (used to generate debits and
credits).
(2) Description of the control system used to generate emission
credits for each process unit used to generate credits.
(3) Determination of the total HAP control efficiency for the
control system used to generate emission credits for each credit-
generating process unit.
(4) Calculation of the RMR and AMR, as calculated using Equations 1
through 3 of Sec. 63.2240(c)(1).
(5) Documentation of total HAP measurements made according to Sec.
63.2240(c)(2)(iv) and other relevant documentation to support
calculation of the RMR and AMR.
(6) A summary of the operating parameters you will monitor and
monitoring methods for each debit-generating and credit-generating
process unit.
(g) You must notify the EPA Administrator within 30 days before you
take any of the actions specified in paragraphs (g)(1) through (3) of
this section.
(1) You modify or replace the control system for any process unit
subject to the compliance options and operating requirements in this
subpart.
(2) You shut down any process unit included in your Emissions
Averaging Plan.
(3) You change a continuous monitoring parameter or the value or
range of values of a continuous monitoring parameter for any process
unit or control device.
[[Page 234]]
Sec. 63.2281 What reports must I submit and when?
(a) You must submit each report in Table 9 to this subpart that
applies to you.
(b) Unless the EPA Administrator has approved a different schedule
for submission of reports under Sec. 63.10(a), you must submit each
report by the date in Table 9 to this subpart and as specified in
paragraphs (b)(1) through (5) of this section.
(1) The first compliance report must cover the period beginning on
the compliance date that is specified for your affected source in Sec.
63.2233 ending on June 30 or December 31, and lasting at least 6 months,
but less than 12 months. For example, if your compliance date is March
1, then the first semiannual reporting period would begin on March 1 and
end on December 31.
(2) The first compliance report must be postmarked or delivered no
later than July 31 or January 31 for compliance periods ending on June
30 and December 31, respectively.
(3) Each subsequent compliance report must cover the semiannual
reporting period from January 1 through June 30 or the semiannual
reporting period from July 1 through December 31.
(4) Each subsequent compliance report must be postmarked or
delivered no later than July 31 or January 31 for the semiannual
reporting period ending on June 30 and December 31, respectively.
(5) For each affected source that is subject to permitting
regulations pursuant to 40 CFR part 70 or 40 CFR part 71, and if the
permitting authority has established dates for submitting semiannual
reports pursuant to Sec. 70.6(a)(3)(iii)(A) or Sec.
71.6(a)(3)(iii)(A), you may submit the first and subsequent compliance
reports according to the dates the permitting authority has established
instead of according to the dates in paragraphs (b)(1) through (4) of
this section.
(c) The compliance report must contain the information in paragraphs
(c)(1) through (8) of this section.
(1) Company name and address.
(2) Statement by a responsible official with that official's name,
title, and signature, certifying the truth, accuracy, and completeness
of the content of the report.
(3) Date of report and beginning and ending dates of the reporting
period.
(4) If you had a startup, shutdown, or malfunction during the
reporting period and you took actions consistent with your SSMP, the
compliance report must include the information specified in Sec.
63.10(d)(5)(i).
(5) A description of control device maintenance performed while the
control device was offline and one or more of the process units
controlled by the control device was operating, including the
information specified in paragraphs (c)(5)(i) through (iii) of this
section.
(i) The date and time when the control device was shut down and
restarted.
(ii) Identification of the process units that were operating and the
number of hours that each process unit operated while the control device
was offline.
(iii) A statement of whether or not the control device maintenance
was included in your approved routine control device maintenance
exemption developed pursuant to Sec. 63.2251. If the control device
maintenance was included in your approved routine control device
maintenance exemption, then you must report the information in
paragraphs (c)(5)(iii)(A) through (C) of this section.
(A) The total amount of time that each process unit controlled by
the control device operated during the semiannual compliance period and
during the previous semiannual compliance period.
(B) The amount of time that each process unit controlled by the
control device operated while the control device was down for
maintenance covered under the routine control device maintenance
exemption during the semiannual compliance period and during the
previous semiannual compliance period.
(C) Based on the information recorded under paragraphs
(c)(5)(iii)(A) and (B) of this section for each process unit, compute
the annual percent of process unit operating uptime during which the
control device was offline for routine maintenance using Equation 1 of
this section.
[[Page 235]]
[GRAPHIC] [TIFF OMITTED] TR72AD04.007
Where:
RM = Annual percentage of process unit uptime during which control
device is down for routine control device maintenance;
PUp = Process unit uptime for the previous semiannual
compliance period;
PUc = Process unit uptime for the current semiannual
compliance period;
DTp = Control device downtime claimed under the routine
control device maintenance exemption for the previous semiannual
compliance period;
DTc = Control device downtime claimed under the routine
control device maintenance exemption for the current semiannual
compliance period.
(6) The results of any performance tests conducted during the
semiannual reporting period.
(7) If there are no deviations from any applicable compliance option
or operating requirement, and there are no deviations from the
requirements for work practice requirements in Table 8 to this subpart,
a statement that there were no deviations from the compliance options,
operating requirements, or work practice requirements during the
reporting period.
(8) If there were no periods during which the continuous monitoring
system (CMS), including CEMS and CPMS, was out-of-control as specified
in Sec. 63.8(c)(7), a statement that there were no periods during which
the CMS was out-of-control during the reporting period.
(d) For each deviation from a compliance option or operating
requirement and for each deviation from the work practice requirements
in Table 8 to this subpart that occurs at an affected source where you
are not using a CMS to comply with the compliance options, operating
requirements, or work practice requirements in this subpart, the
compliance report must contain the information in paragraphs (c)(1)
through (6) of this section and in paragraphs (d)(1) and (2) of this
section. This includes periods of startup, shutdown, and malfunction and
routine control device maintenance.
(1) The total operating time of each affected source during the
reporting period.
(2) Information on the number, duration, and cause of deviations
(including unknown cause, if applicable), as applicable, and the
corrective action taken.
(e) For each deviation from a compliance option or operating
requirement occurring at an affected source where you are using a CMS to
comply with the compliance options and operating requirements in this
subpart, you must include the information in paragraphs (c)(1) through
(6) and paragraphs (e)(1) through (11) of this section. This includes
periods of startup, shutdown, and malfunction and routine control device
maintenance.
(1) The date and time that each malfunction started and stopped.
(2) The date and time that each CMS was inoperative, except for zero
(low-level) and high-level checks.
(3) The date, time, and duration that each CMS was out-of-control,
including the information in Sec. 63.8(c)(8).
(4) The date and time that each deviation started and stopped, and
whether each deviation occurred during a period of startup, shutdown, or
malfunction; during a period of control device maintenance covered in
your approved routine control device maintenance exemption; or during
another period.
(5) A summary of the total duration of the deviation during the
reporting period and the total duration as a percent of the total source
operating time during that reporting period.
(6) A breakdown of the total duration of the deviations during the
reporting period into those that are due to startup, shutdown, control
system problems, control device maintenance, process problems, other
known causes, and other unknown causes.
(7) A summary of the total duration of CMS downtime during the
reporting period and the total duration of CMS downtime as a percent of
the total source operating time during that reporting period.
(8) A brief description of the process units.
(9) A brief description of the CMS.
(10) The date of the latest CMS certification or audit.
(11) A description of any changes in CMS, processes, or controls
since the last reporting period.
[[Page 236]]
(f) If you comply with the emissions averaging compliance option in
Sec. 63.2240(c), you must include in your semiannual compliance report
calculations based on operating data from the semiannual reporting
period that demonstrate that actual mass removal equals or exceeds the
required mass removal.
(g) Each affected source that has obtained a title V operating
permit pursuant to 40 CFR part 70 or 40 CFR part 71 must report all
deviations as defined in this subpart in the semiannual monitoring
report required by Sec. 70.6(a)(3)(iii)(A) or Sec. 71.6(a)(3)(iii)(A).
If an affected source submits a compliance report pursuant to Table 9 to
this subpart along with, or as part of, the semiannual monitoring report
required by Sec. 70.6(a)(3)(iii)(A) or Sec. 71.6(a)(3)(iii)(A), and
the compliance report includes all required information concerning
deviations from any compliance option, operating requirement, or work
practice requirement in this subpart, submission of the compliance
report shall be deemed to satisfy any obligation to report the same
deviations in the semiannual monitoring report. However, submission of a
compliance report shall not otherwise affect any obligation the affected
source may have to report deviations from permit requirements to the
permitting authority.
Sec. 63.2282 What records must I keep?
(a) You must keep the records listed in paragraphs (a)(1) through
(4) of this section.
(1) A copy of each notification and report that you submitted to
comply with this subpart, including all documentation supporting any
Initial Notification or Notification of Compliance Status that you
submitted, according to the requirements in Sec. 63.10(b)(2)(xiv).
(2) The records in Sec. 63.6(e)(3)(iii) through (v) related to
startup, shutdown, and malfunction.
(3) Documentation of your approved routine control device
maintenance exemption, if you request such an exemption under Sec.
63.2251.
(4) Records of performance tests and performance evaluations as
required in Sec. 63.10(b)(2)(viii).
(b) You must keep the records required in Tables 7 and 8 to this
subpart to show continuous compliance with each compliance option,
operating requirement, and work practice requirement that applies to
you.
(c) For each CEMS, you must keep the following records.
(1) Records described in Sec. 63.10(b)(2)(vi) through (xi).
(2) Previous (i.e., superseded) versions of the performance
evaluation plan as required in Sec. 63.8(d)(3).
(3) Request for alternatives to relative accuracy testing for CEMS
as required in Sec. 63.8(f)(6)(i).
(4) Records of the date and time that each deviation started and
stopped, and whether the deviation occurred during a period of startup,
shutdown, or malfunction or during another period.
(d) If you comply with the emissions averaging compliance option in
Sec. 63.2240(c), you must keep records of all information required to
calculate emission debits and credits.
(e) If you operate a catalytic oxidizer, you must keep records of
annual catalyst activity checks and subsequent corrective actions.
Sec. 63.2283 In what form and how long must I keep my records?
(a) Your records must be in a form suitable and readily available
for expeditious review as specified in Sec. 63.10(b)(1).
(b) As specified in Sec. 63.10(b)(1), you must keep each record for
5 years following the date of each occurrence, measurement, maintenance,
corrective action, report, or record.
(c) You must keep each record on site for at least 2 years after the
date of each occurrence, measurement, maintenance, corrective action,
report, or record according to Sec. 63.10(b)(1). You can keep the
records offsite for the remaining 3 years.
Other Requirements and Information
Sec. 63.2290 What parts of the General Provisions apply to me?
Table 10 to this subpart shows which parts of the General Provisions
in Sec. Sec. 63.1 through 63.13 apply to you.
[[Page 237]]
Sec. 63.2291 Who implements and enforces this subpart?
(a) This subpart can be implemented and enforced by the U.S. EPA or
a delegated authority such as your State, local, or tribal agency. If
the EPA Administrator has delegated authority to your State, local, or
tribal agency, then that agency has the authority to implement and
enforce this subpart. You should contact your EPA Regional Office to
find out if this subpart is delegated to your State, local, or tribal
agency.
(b) In delegating implementation and enforcement authority of this
subpart to a State, local, or tribal agency under 40 CFR part 63,
subpart E, the authorities contained in paragraph (c) of this section
are retained by the EPA Administrator and are not transferred to the
State, local, or tribal agency.
(c) The authorities that will not be delegated to State, local, or
tribal agencies are listed in paragraphs (c)(1) through (5) of this
section.
(1) Approval of alternatives to the compliance options, operating
requirements, and work practice requirements in Sec. Sec. 63.2240 and
63.2241 as specified in Sec. 63.6(g). For the purposes of delegation
authority under 40 CFR part 63, subpart E, ``compliance options''
represent ``emission limits''; ``operating requirements'' represent
``operating limits''; and ``work practice requirements'' represent
``work practice standards.''
(2) Approval of major alternatives to test methods as specified in
Sec. 63.7(e)(2)(ii) and (f) and as defined in Sec. 63.90.
(3) Approval of major alternatives to monitoring as specified in
Sec. 63.8(f) and as defined in Sec. 63.90.
(4) Approval of major alternatives to recordkeeping and reporting as
specified in Sec. 63.10(f) and as defined in Sec. 63.90.
(5) Approval of PCWP sources demonstrations of eligibility for the
low-risk subcategory developed according to appendix B of this subpart.
Sec. 63.2292 What definitions apply to this subpart?
Terms used in this subpart are defined in the Clean Air Act (CAA),
in 40 CFR 63.2, the General Provisions, and in this section as follows:
Affected source means the collection of dryers, refiners, blenders,
formers, presses, board coolers, and other process units associated with
the manufacturing of plywood and composite wood products. The affected
source includes, but is not limited to, green end operations, refining,
drying operations (including any combustion unit exhaust stream
routinely used to direct fire process unit(s)), resin preparation,
blending and forming operations, pressing and board cooling operations,
and miscellaneous finishing operations (such as sanding, sawing,
patching, edge sealing, and other finishing operations not subject to
other NESHAP). The affected source also includes onsite storage of raw
materials used in the manufacture of plywood and/or composite wood
products, such as resins; onsite wastewater treatment operations
specifically associated with plywood and composite wood products
manufacturing; and miscellaneous coating operations (defined elsewhere
in this section). The affected source includes lumber kilns at PCWP
manufacturing facilities and at any other kind of facility.
Agricultural fiber means the fiber of an annual agricultural crop.
Examples of agricultural fibers include, but are not limited to, wheat
straw, rice straw, and bagasse.
Biofilter means an enclosed control system such as a tank or series
of tanks with a fixed roof that contact emissions with a solid media
(such as bark) and use microbiological activity to transform organic
pollutants in a process exhaust stream to innocuous compounds such as
carbon dioxide, water, and inorganic salts. Wastewater treatment systems
such as aeration lagoons or activated sludge systems are not considered
to be biofilters.
Capture device means a hood, enclosure, or other means of collecting
emissions into a duct so that the emissions can be measured.
Capture efficiency means the fraction (expressed as a percentage) of
the pollutants from an emission source that are collected by a capture
device.
Catalytic oxidizer means a control system that combusts or oxidizes,
in the presence of a catalyst, exhaust gas from a process unit.
Catalytic oxidizers
[[Page 238]]
include regenerative catalytic oxidizers and thermal catalytic
oxidizers.
Combustion unit means a dryer burner, process heater, or boiler.
Combustion units may be used for combustion of organic HAP emissions.
Control device means any equipment that reduces the quantity of HAP
emitted to the air. The device may destroy the HAP or secure the HAP for
subsequent recovery. Control devices include, but are not limited to,
thermal or catalytic oxidizers, combustion units that incinerate process
exhausts, biofilters, and condensers.
Control system or add-on control system means the combination of
capture and control devices used to reduce HAP emissions to the
atmosphere.
Conveyor strand dryer means a conveyor dryer used to reduce the
moisture of wood strands used in the manufacture of oriented
strandboard, laminated strand lumber, or other wood strand-based
products. A conveyor strand dryer is a process unit.
Conveyor strand dryer zone means each portion of a conveyor strand
dryer with a separate heat exchange system and exhaust vent(s). Conveyor
strand dryers contain multiple zones (e.g., three zones), which may be
divided into multiple sections.
Deviation means any instance in which an affected source subject to
this subpart, or an owner or operator of such a source:
(1) Fails to meet any requirement or obligation established by this
subpart including, but not limited to, any compliance option, operating
requirement, or work practice requirement;
(2) Fails to meet any term or condition that is adopted to implement
an applicable requirement in this subpart, and that is included in the
operating permit for any affected source required to obtain such a
permit; or
(3) Fails to meet any compliance option, operating requirement, or
work practice requirement in this subpart during startup, shutdown, or
malfunction, regardless of whether or not such failure is permitted by
this subpart. A deviation is not always a violation. The determination
of whether a deviation constitutes a violation of the standard is up to
the discretion of the entity responsible for enforcement of the
standards.
Direct-fired process unit means a process unit that is heated by the
passing of combustion exhaust through the process unit such that the
process material is contacted by the combustion exhaust.
Dryer heated zones means the zones of a softwood veneer dryer or
fiberboard mat dryer that are equipped with heating and hot air
circulation units. The cooling zone(s) of the dryer through which
ambient air is blown are not part of the dryer heated zones.
Dry forming means the process of making a mat of resinated fiber to
be compressed into a reconstituted wood product such as particleboard,
oriented strandboard, medium density fiberboard, or hardboard.
Dry rotary dryer means a rotary dryer that dries wood particles or
fibers with a maximum inlet moisture content of less than or equal to 30
percent (by weight, dry basis) and operates with a maximum inlet
temperature of less than or equal to 600 [deg]F. A dry rotary dryer is a
process unit.
Engineered wood product means a product made with lumber, veneers,
strands of wood, or from other small wood elements that are bound
together with resin. Engineered wood products include, but are not
limited to, laminated strand lumber, laminated veneer lumber, parallel
strand lumber, wood I-joists, and glue-laminated beams.
Fiber means the discrete elements of wood or similar cellulosic
material, which are separated by mechanical means, as in refining, that
can be formed into boards.
Fiberboard means a composite panel composed of cellulosic fibers
(usually wood or agricultural material) made by wet forming and
compacting a mat of fibers. Fiberboard density generally is less than
0.50 grams per cubic centimeter (31.5 pounds per cubic foot).
Fiberboard mat dryer means a dryer used to reduce the moisture of
wet-formed wood fiber mats by applying heat. A fiberboard mat dryer is a
process unit.
Flame zone means the portion of the combustion chamber in a
combustion unit that is occupied by the flame envelope.
[[Page 239]]
Furnish means the fibers, particles, or strands used for making
boards.
Glue-laminated beam means a structural wood beam made by bonding
lumber together along its faces with resin.
Green rotary dryer means a rotary dryer that dries wood particles or
fibers with an inlet moisture content of greater than 30 percent (by
weight, dry basis) at any dryer inlet temperature or operates with an
inlet temperature of greater than 600 [deg]F with any inlet moisture
content. A green rotary dryer is a process unit.
Group 1 miscellaneous coating operations means application of edge
seals, nail lines, logo (or other information) paint, shelving edge
fillers, trademark/gradestamp inks, and wood putty patches to plywood
and composite wood products (except kiln-dried lumber) on the same site
where the plywood and composite wood products are manufactured. Group 1
miscellaneous coating operations also include application of synthetic
patches to plywood at new affected sources.
Hardboard means a composite panel composed of inter-felted
cellulosic fibers made by dry or wet forming and pressing of a resinated
fiber mat. Hardboard generally has a density of 0.50 grams per cubic
centimeter (31.5 pounds per cubic foot) or greater.
Hardboard oven means an oven used to heat treat or temper hardboard
after hot pressing. Humidification chambers are not considered as part
of hardboard ovens. A hardboard oven is a process unit.
Hardwood means the wood of a broad-leafed tree, either deciduous or
evergreen. Examples of hardwoods include, but are not limited to, aspen,
birch, poplar, and oak.
Hardwood veneer dryer means a dryer that removes excess moisture
from veneer by conveying the veneer through a heated medium on rollers,
belts, cables, or wire mesh. Hardwood veneer dryers are used to dry
veneer with less than 30 percent softwood species on an annual volume
basis. Veneer kilns that operate as batch units, veneer dryers heated by
radio frequency or microwaves that are used to redry veneer, and veneer
redryers (defined elsewhere in this section) that are heated by
conventional means are not considered to be hardwood veneer dryers. A
hardwood veneer dryer is a process unit.
Kiln-dried lumber means solid wood lumber that has been dried in a
lumber kiln.
Laminated strand lumber (LSL) means a composite product formed into
a billet made of thin wood strands cut from whole logs, resinated, and
pressed together with the grain of each strand oriented parallel to the
length of the finished product.
Laminated veneer lumber (LVL) means a composite product formed into
a billet made from layers of resinated wood veneer sheets or pieces
pressed together with the grain of each veneer aligned primarily along
the length of the finished product. Laminated veneer lumber is also
known as parallel strand lumber (PSL).
Lumber means boards or planks sawed or split from logs or timber,
including logs or timber processed for use as utility poles or other
wood components. Lumber can be either green (non-dried) or dried. Lumber
is typically either air-dried or kiln-dried.
Lumber kiln means an enclosed dryer operated by applying heat to
reduce the moisture content of lumber.
Medium density fiberboard (MDF) means a composite panel composed of
cellulosic fibers (usually wood or agricultural fiber) made by dry
forming and pressing of a resinated fiber mat.
Method detection limit means the minimum concentration of an analyte
that can be determined with 99 percent confidence that the true value is
greater than zero.
Miscellaneous coating operations means application of any of the
following to plywood or composite wood products: edge seals, moisture
sealants, anti-skid coatings, company logos, trademark or grade stamps,
nail lines, synthetic patches, wood patches, wood putty, concrete
forming oils, glues for veneer composing, and shelving edge fillers.
Miscellaneous coating operations also include the application of primer
to oriented strandboard siding that occurs at the same site as oriented
strandboard manufacture and application of asphalt, clay slurry, or
titanium dioxide coatings to fiberboard at the same site of fiberboard
manufacture.
[[Page 240]]
Molded particleboard means a shaped composite product (other than a
composite panel) composed primarily of cellulosic materials (usually
wood or agricultural fiber) generally in the form of discrete pieces or
particles, as distinguished from fibers, which are pressed together with
resin.
MSF means thousand square feet (92.9 square meters). Square footage
of panels is usually measured on a thickness basis, such as \3/8\-inch,
to define the total volume of panels. Equation 6 of Sec. 63.2262(j)
shows how to convert from one thickness basis to another.
Nondetect data means, for the purposes of this subpart, any value
that is below the method detection limit.
Non-HAP coating means a coating with HAP contents below 0.1 percent
by mass for Occupational Safety and Health Administration-defined
carcinogens as specified in 29 CFR 1910.1200(d)(4), and below 1.0
percent by mass for other HAP compounds.
1-hour period means a 60-minute period.
Oriented strandboard (OSB) means a composite panel produced from
thin wood strands cut from whole logs, formed into resinated layers
(with the grain of strands in one layer oriented perpendicular to the
strands in adjacent layers), and pressed.
Oven-dried ton(s) (ODT) means tons of wood dried until all of the
moisture in the wood is removed. One oven-dried ton equals 907 oven-
dried kilograms.
Parallel strand lumber (PSL) means a composite product formed into a
billet made from layers of resinated wood veneer sheets or pieces
pressed together with the grain of each veneer aligned primarily along
the length of the finished product. Parallel strand lumber is also known
as laminated veneer lumber (LVL).
Partial wood products enclosure means an enclosure that does not
meet the design criteria for a wood products enclosure as defined in
this subpart.
Particle means a discrete, small piece of cellulosic material
(usually wood or agricultural fiber) produced mechanically and used as
the aggregate for a particleboard.
Particleboard means a composite panel composed primarily of
cellulosic materials (usually wood or agricultural fiber) generally in
the form of discrete pieces or particles, as distinguished from fibers,
which are pressed together with resin.
Plywood means a panel product consisting of layers of wood veneers
hot pressed together with resin. Plywood includes panel products made by
hot pressing (with resin) veneers to a substrate such as particleboard,
medium density fiberboard, or lumber. Plywood products may be flat or
curved.
Plywood and composite wood products (PCWP) manufacturing facility
means a facility that manufactures plywood and/or composite wood
products by bonding wood material (fibers, particles, strands, veneers,
etc.) or agricultural fiber, generally with resin under heat and
pressure, to form a panel, engineered wood product, or other product
defined in Sec. 63.2292. Plywood and composite wood products
manufacturing facilities also include facilities that manufacture dry
veneer and lumber kilns located at any facility. Plywood and composite
wood products include, but are not limited to, plywood, veneer,
particleboard, molded particleboard, oriented strandboard, hardboard,
fiberboard, medium density fiberboard, laminated strand lumber,
laminated veneer lumber, wood I-joists, kiln-dried lumber, and glue-
laminated beams.
Press predryer means a dryer used to reduce the moisture and elevate
the temperature by applying heat to a wet-formed fiber mat before the
mat enters a hot press. A press predryer is a process unit.
Pressurized refiner means a piece of equipment operated under
pressure for preheating (usually by steaming) wood material and refining
(rubbing or grinding) the wood material into fibers. Pressurized
refiners are operated with continuous infeed and outfeed of wood
material and maintain elevated internal pressures (i.e., there is no
pressure release) throughout the preheating and refining process. A
pressurized refiner is a process unit.
Primary tube dryer means a single-stage tube dryer or the first
stage of a multi-stage tube dryer. Tube dryer stages are separated by
vents for removal of moist gases between stages (e.g., a product cyclone
at the end of a
[[Page 241]]
single-stage dryer or between the first and second stages of a multi-
stage tube dryer). The first stage of a multi-stage tube dryer is used
to remove the majority of the moisture from the wood furnish (compared
to the moisture reduction in subsequent stages of the tube dryer). Blow-
lines used to apply resin are considered part of the primary tube dryer.
A primary tube dryer is a process unit.
Process unit means equipment classified according to its function
such as a blender, dryer, press, former, or board cooler.
Reconstituted wood product board cooler means a piece of equipment
designed to reduce the temperature of a board by means of forced air or
convection within a controlled time period after the board exits the
reconstituted wood product press unloader. Board coolers include wicket
and star type coolers commonly found at medium density fiberboard and
particleboard plants. Board coolers do not include cooling sections of
dryers (e.g., veneer dryers or fiberboard mat dryers) or coolers
integrated into or following hardboard bake ovens or humidifiers. A
reconstituted wood product board cooler is a process unit.
Reconstituted wood product press means a press, including (if
applicable) the press unloader, that presses a resinated mat of wood
fibers, particles, or strands between hot platens or hot rollers to
compact and set the mat into a panel by simultaneous application of heat
and pressure. Reconstituted wood product presses are used in the
manufacture of hardboard, medium density fiberboard, particleboard, and
oriented strandboard. Extruders are not considered to be reconstituted
wood product presses. A reconstituted wood product press is a process
unit.
Representative operating conditions means operation of a process
unit during performance testing under the conditions that the process
unit will typically be operating in the future, including use of a
representative range of materials (e.g., wood material of a typical
species mix and moisture content or typical resin formulation) and
representative operating temperature range.
Resin means the synthetic adhesive (including glue) or natural
binder, including additives, used to bond wood or other cellulosic
materials together to produce plywood and composite wood products.
Responsible official means responsible official as defined in 40 CFR
70.2 and 40 CFR 71.2.
Rotary strand dryer means a rotary dryer operated by applying heat
and used to reduce the moisture of wood strands used in the manufacture
of oriented strandboard, laminated strand lumber, or other wood strand-
based products. A rotary strand dryer is a process unit.
Secondary tube dryer means the second stage and subsequent stages
following the primary stage of a multi-stage tube dryer. Secondary tube
dryers, also referred to as relay dryers, operate at lower temperatures
than the primary tube dryer they follow. Secondary tube dryers are used
to remove only a small amount of the furnish moisture compared to the
furnish moisture reduction across the primary tube dryer. A secondary
tube dryer is a process unit.
Softwood means the wood of a coniferous tree. Examples of softwoods
include, but are not limited to, Southern yellow pine, Douglas fir, and
White spruce.
Softwood veneer dryer means a dryer that removes excess moisture
from veneer by conveying the veneer through a heated medium, generally
on rollers, belts, cables, or wire mesh. Softwood veneer dryers are used
to dry veneer with greater than or equal to 30 percent softwood species
on an annual volume basis. Veneer kilns that operate as batch units,
veneer dryers heated by radio frequency or microwaves that are used to
redry veneer, and veneer redryers (defined elsewhere in this section)
that are heated by conventional means are not considered to be softwood
veneer dryers. A softwood veneer dryer is a process unit.
Startup means bringing equipment online and starting the production
process.
Startup, initial means the first time equipment is put into
operation. Initial startup does not include operation solely for testing
equipment. Initial
[[Page 242]]
startup does not include subsequent startups (as defined in this
section) following malfunction or shutdowns or following changes in
product or between batch operations. Initial startup does not include
startup of equipment that occurred when the source was an area source.
Startup, shutdown, and malfunction plan (SSMP) means a plan
developed according to the provisions of Sec. 63.6(e)(3).
Strand means a long (with respect to thickness and width), flat wood
piece specially cut from a log for use in oriented strandboard,
laminated strand lumber, or other wood strand-based product.
Temporary total enclosure (TTE) means an enclosure constructed for
the purpose of measuring the capture efficiency of pollutants emitted
from a given source, as defined in Method 204 of 40 CFR part 51,
appendix M.
Thermal oxidizer means a control system that combusts or oxidizes
exhaust gas from a process unit. Thermal oxidizers include regenerative
thermal oxidizers and combustion units.
Total hazardous air pollutant emissions means, for purposes of this
subpart, the sum of the emissions of the following six compounds:
acetaldehyde, acrolein, formaldehyde, methanol, phenol, and
propionaldehyde.
Tube dryer means a single-stage or multi-stage dryer operated by
applying heat to reduce the moisture of wood fibers or particles as they
are conveyed (usually pneumatically) through the dryer. Resin may or may
not be applied to the wood material before it enters the tube dryer.
Tube dryers do not include pneumatic fiber transport systems that use
temperature and humidity conditioned pneumatic system supply air in
order to prevent cooling of the wood fiber as it is moved through the
process. A tube dryer is a process unit.
Veneer means thin sheets of wood peeled or sliced from logs for use
in the manufacture of wood products such as plywood, laminated veneer
lumber, or other products.
Veneer redryer means a dryer heated by conventional means, such as
direct wood-fired, direct-gas-fired, or steam heated, that is used to
redry veneer that has been previously dried. Because the veneer dried in
a veneer redryer has been previously dried, the inlet moisture content
of the veneer entering the redryer is less than 25 percent (by weight,
dry basis). Batch units used to redry veneer (such as redry cookers) are
not considered to be veneer redryers. A veneer redryer is a process
unit.
Wet control device means any equipment that uses water as a means of
collecting an air pollutant. Wet control devices include scrubbers, wet
electrostatic precipitators, and electrified filter beds. Wet control
devices do not include biofilters or other equipment that destroys or
degrades HAP.
Wet forming means the process of making a slurry of water, fiber,
and additives into a mat of fibers to be compressed into a fiberboard or
hardboard product.
Wood I-joists means a structural wood beam with an I-shaped cross
section formed by bonding (with resin) wood or laminated veneer lumber
flanges onto a web cut from a panel such as plywood or oriented
strandboard.
Wood products enclosure means a permanently installed containment
that was designed to meet the following physical design criteria:
(1) Any natural draft opening shall be at least four equivalent
opening diameters from each HAP-emitting point, except for where board
enters and exits the enclosure, unless otherwise specified by the EPA
Administrator.
(2) The total area of all natural draft openings shall not exceed 5
percent of the surface area of the enclosure's four walls, floor, and
ceiling.
(3) The average facial velocity of air through all natural draft
openings shall be at least 3,600 meters per hour (200 feet per minute).
The direction of airflow through all natural draft openings shall be
into the enclosure.
(4) All access doors and windows whose areas are not included in
item 2 of this definition and are not included in the calculation of
facial velocity in item 3 of this definition shall be closed during
routine operation of the process.
(5) The enclosure is designed and maintained to capture all
emissions for discharge through a control device.
[[Page 243]]
Work practice requirement means any design, equipment, work
practice, or operational standard, or combination thereof, that is
promulgated pursuant to section 112(h) of the CAA.
[69 FR 46011, July 30, 2004, as amended at 71 FR 8372, Feb. 16, 2006]
Table 1A to Subpart DDDD of Part 63--Production-Based Compliance Options
------------------------------------------------------------------------
You must meet the following
production-based compliance
For the following process units . . . option (total HAP \a\ basis) .
. .
------------------------------------------------------------------------
(1) Fiberboard mat dryer heated zones 0.022 lb/MSF \1/2\.
(at new affected sources only).
(2) Green rotary dryers................ 0.058 lb/ODT.
(3) Hardboard ovens.................... 0.022 lb/MSF \1/8\.
(4) Press predryers (at new affected 0.037 lb/MSF \1/2\.
sources only).
(5) Pressurized refiners............... 0.039 lb/ODT.
(6) Primary tube dryers................ 0.26 lb/ODT.
(7) Reconstituted wood product board 0.014 lb/MSF \3/4\.
coolers (at new affected sources only).
(8) Reconstituted wood product presses. 0.30 lb/MSF \3/4\.
(9) Softwood veneer dryer heated zones. 0.022 lb/MSF \3/8\.
(10) Rotary strand dryers.............. 0.18 lb/ODT.
(11) Secondary tube dryers............. 0.010 lb/ODT.
------------------------------------------------------------------------
\a\ Total HAP, as defined in Sec. 63.2292, includes acetaldehyde,
acrolein, formaldehyde, methanol, phenol, and propionaldehyde. lb/ODT
= pounds per oven-dried ton; lb/MSF = pounds per thousand square feet
with a specified thickness basis (inches). Section 63.2262(j) shows
how to convert from one thickness basis to another.
Note: There is no production-based compliance option for conveyor strand
dryers.
Table 1B to Subpart DDDD of Part 63--Add-on Control Systems Compliance
Options
------------------------------------------------------------------------
You must comply with one of the
For each of the following process units following six compliance
. . . options by using an emissions
control system . . .
------------------------------------------------------------------------
Fiberboard mat dryer heated zones (at (1) Reduce emissions of total
new affected sources only); green HAP, measured as THC (as
rotary dryers; hardboard ovens; press carbon) \a\, by 90 percent; or
predryers (at new affected sources (2) Limit emissions of total
only); pressurized refiners; primary HAP, measured as THC (as
tube dryers; secondary tube dryers; carbon) \a\, to 20 ppmvd; or
reconstituted wood product board (3) Reduce methanol emissions
coolers (at new affected sources by 90 percent; or
only); reconstituted wood product (4) Limit methanol emissions to
presses; softwood veneer dryer heated less than or equal to 1 ppmvd
zones; rotary strand dryers; conveyor if uncontrolled methanol
strand dryer zone one (at existing emissions entering the control
affected sources); and conveyor strand device are greater than or
dryer zones one and two (at new equal to 10 ppmvd; or
affected sources). (5) Reduce formaldehyde
emissions by 90 percent; or
(6) Limit formaldehyde
emissions to less than or
equal to 1 ppmvd if
uncontrolled formaldehyde
emissions entering the control
device are greater than or
equal to 10 ppmvd.
------------------------------------------------------------------------
\a\ You may choose to subtract methane from THC as carbon measurements.
Table 2 to Subpart DDDD of Part 63--Operating Requirements
------------------------------------------------------------------------
If you operate a(n) . . . You must . . . Or you must . . .
------------------------------------------------------------------------
(1) Thermal oxidizer............ Maintain the 3- Maintain the 3-
hour block hour block
average firebox average THC
temperature above concentration \a\
the minimum in the thermal
temperature oxidizer exhaust
established below the maximum
during the concentration
performance test. established
during the
performance test.
(2) Catalytic oxidizer.......... Maintain the 3- Maintain the 3-
hour block hour block
average catalytic average THC
oxidizer concentration \a\
temperature above in the catalytic
the minimum oxidizer exhaust
temperature below the maximum
established concentration
during the established
performance test; during the
AND check the performance test.
activity level of
a representative
sample of the
catalyst at least
every 12 months.
(3) Biofilter................... Maintain the 24- Maintain the 24-
hour block hour block
biofilter bed average THC
temperature concentration \a\
within the range in the biofilter
established exhaust below the
according to Sec. maximum
63.2262(m). concentration
established
during the
performance test.
[[Page 244]]
(4) Control device other than a Petition the EPA Maintain the 3-
thermal oxidizer, catalytic Administrator for hour block
oxidizer, or biofilter. site-specific average THC
operating concentration \a\
parameter(s) to in the control
be established device exhaust
during the below the maximum
performance test concentration
and maintain the established
average operating during the
parameter(s) performance test.
within the
range(s)
established
during the
performance test.
(5) Process unit that meets a Maintain on a Maintain the 3-
compliance option in Table 1A daily basis the hour block
of this subpart, or a process process unit average THC
unit that generates debits in controlling concentration \a\
an emissions average without operating in the process
the use of a control device. parameter(s) unit exhaust
within the ranges below the maximum
established concentration
during the established
performance test during the
according to Sec. performance test.
63.2262(n).
------------------------------------------------------------------------
\a\ You may choose to subtract methane from THC measurements.
Table 3 to Subpart DDDD of Part 63--Work Practice Requirements
------------------------------------------------------------------------
For the following process units at
existing or new affected sources . You must . . .
. .
------------------------------------------------------------------------
(1) Dry rotary dryers............. Process furnish with a 24-hour block
average inlet moisture content of
less than or equal to 30 percent
(by weight, dry basis); AND operate
with a 24-hour block average inlet
dryer temperature of less than or
equal to 600 [deg]F.
(2) Hardwood veneer dryers........ Process less than 30 volume percent
softwood species on an annual
basis.
(3) Softwood veneer dryers........ Minimize fugitive emissions from the
dryer doors through (proper
maintenance procedures) and the
green end of the dryers (through
proper balancing of the heated zone
exhausts).
(4) Veneer redryers............... Process veneer that has been
previously dried, such that the 24-
hour block average inlet moisture
content of the veneer is less than
or equal to 25 percent (by weight,
dry basis).
(5) Group 1 miscellaneous coating Use non-HAP coatings as defined in
operations. Sec. 63.2292.
------------------------------------------------------------------------
Table 4 to Subpart DDDD of Part 63--Requirements for Performance Tests
------------------------------------------------------------------------
For . . . You must . . . Using . . .
------------------------------------------------------------------------
(1) each process unit select sampling Method 1 or 1A of 40
subject to a compliance port's location and CFR part 60,
option in table 1A or 1B to the number of appendix A (as
this subpart or used in traverse ports. appropriate).
calculation of an emissions
average under Sec.
63.2240(c).
(2) each process unit determine velocity Method 2 in addition
subject to a compliance and volumetric flow to Method 2A, 2C,
option in table 1A or 1B to rate. 2D, 2F, or 2G in
this subpart or used in appendix A to 40
calculation of an emissions CFR part 60 (as
average under Sec. appropriate).
63.2240(c).
(3) each process unit conduct gas Method 3, 3A, or 3B
subject to a compliance molecular weight in appendix A to 40
option in table 1A or 1B to analysis. CFR part 60 (as
this subpart or used in appropriate).
calculation of an emissions
average under Sec.
63.2240(c).
(4) each process unit measure moisture Method 4 in appendix
subject to a compliance content of the A to 40 CFR part
option in table 1A or 1B to stack gas. 60; OR Method 320
this subpart or used in in appendix A to 40
calculation of an emissions CFR part 63; OR
average under Sec. ASTM D6348-03 (IBR,
63.2240(c). see Sec.
63.14(b)).
(5) each process unit measure emissions of Method 25A in
subject to a compliance total HAP as THC. appendix A to 40
option in table 1B to this CFR part 60. You
subpart for which you may measure
choose to demonstrate emissions of
compliance using a total methane using EPA
HAP as THC compliance Method 18 in
option. appendix A to 40
CFR part 60 and
subtract the
methane emissions
from the emissions
of total HAP as
THC.
(6) each process unit measure emissions of Method 320 in
subject to a compliance total HAP (as appendix A to 40
option in table 1A to this defined in Sec. CFR part 63; OR the
subpart; OR for each 63.2292). NCASI Method IM/CAN/
process unit used in WP-99.02 (IBR, see
calculation of an emissions Sec. 63.14(f));
average under Sec. OR the NCASI Method
63.2240(c). ISS/FP-A105.01
(IBR, see Sec.
63.14(f)); OR ASTM
D6348-03 (IBR, see
Sec. 63.14(b))
provided that
percent R as
determined in Annex
A5 of ASTM D6348-03
is equal or greater
than 70 percent and
less than or equal
to 130 percent.
[[Page 245]]
(7) each process unit measure emissions of Method 308 in
subject to a compliance methanol. appendix A to 40
option in table 1B to this CFR part 63; OR
subpart for which you Method 320 in
choose to demonstrate appendix A to 40
compliance using a methanol CFR part 63; OR the
compliance option. NCASI Method CI/WP-
98.01 (IBR, see
Sec. 63.14(f));
OR the NCASI Method
IM/CAN/WP-99.02
(IBR, see Sec.
63.14(f)); OR the
NCASI Method ISS/FP-
A105.01 (IBR, see
Sec. 63.14(f)).
(8) each process unit measure emissions of Method 316 in
subject to a compliance formaldehyde. appendix A to 40
option in table 1B to this CFR part 63; OR
subpart for which you Method 320 in
choose to demonstrate appendix A to 40
compliance using a CFR part 63; OR
formaldehyde compliance Method 0011 in
option. ``Test Methods for
Evaluating Solid
Waste, Physical/
Chemical Methods''
(EPA Publication
No. SW-846) for
formaldehyde; OR
the NCASI Method CI/
WP-98.01 (IBR, see
Sec. 63.14(f));
OR the NCASI Method
IM/CAN/WP-99.02
(IBR, see Sec.
63.14(f)); OR the
NCASI Method ISS/FP-
A105.01 (IBR, see
Sec. 63.14(f)).
(9) each reconstituted wood meet the design Methods 204 and 204A
product press at a new or specifications through 204F of 40
existing affected source or included in the CFR part 51,
reconstituted wood product definition of wood appendix M, to
board cooler at a new products enclosure determine capture
affected source subject to in Sec. 63.2292; efficiency (except
a compliance option in or for wood products
table 1B to this subpart or determine the enclosures as
used in calculation of an percent capture defined in Sec.
emissions average under efficiency of the 63.2292).
Sec. 63.2240(c). enclosure directing Enclosures that
emissions to an add- meet the definition
on control device. of wood products
enclosure or that
meet Method 204
requirements for a
permanent total
enclosure (PTE) are
assumed to have a
capture efficiency
of 100 percent.
Enclosures that do
not meet either the
PTE requirements or
design criteria for
a wood products
enclosure must
determine the
capture efficiency
by constructing a
TTE according to
the requirements of
Method 204 and
applying Methods
204A through 204F
(as appropriate).
As an alternative
to Methods 204 and
204A through 204F,
you may use the
tracer gas method
contained in
appendix A to this
subpart.
(10) each reconstituted wood determine the a TTE and Methods
product press at a new or percent capture 204 and 204A
existing affected source or efficiency. through 204F (as
reconstituted wood product appropriate) of 40
board cooler at a new CFR part 51,
affected source subject to appendix M. As an
a compliance option in alternative to
table 1A to this subpart. installing a TTE
and using Methods
204 and 204A
through 204F, you
may use the tracer
gas method
contained in
appendix A to this
subpart. Enclosures
that meet the
design criteria (1)
through (4) in the
definition of wood
products enclosure,
or that meet Method
204 requirements
for a PTE (except
for the criteria
specified in
section 6.2 of
Method 204) are
assumed to have a
capture efficiency
of 100 percent.
Measured emissions
divided by the
capture efficiency
provides the
emission rate.
(11) each process unit establish the site- data from the
subject to a compliance specific operating parameter
option in tables 1A and 1B requirements monitoring system
to this subpart or used in (including the or THC CEMS and the
calculation of an emissions parameter limits or applicable
average under Sec. THC concentration performance test
63.2240(c). limits) in table 2 method(s).
to this subpart.
------------------------------------------------------------------------
[71 FR 8373, Feb. 16, 2006]
[[Page 246]]
Table 5 to Subpart DDDD of Part 63--Performance Testing and Initial
Compliance Demonstrations for the Compliance Options and Operating
Requirements
------------------------------------------------------------------------
For the following You have
compliance options demonstrated
For each . . . and operating initial compliance
requirements . . . if . . .
------------------------------------------------------------------------
(1) Process unit listed in Table Meet the The average total
1A to this subpart. production-based HAP emissions
compliance measured using
options listed in the methods in
Table 1A to this Table 4 to this
subpart. subpart over the
3-hour
performance test
are no greater
than the
compliance option
in Table 1A to
this subpart; AND
you have a record
of the operating
requirement(s)
listed in Table 2
to this subpart
for the process
unit over the
performance test
during which
emissions did not
exceed the
compliance option
value.
(2) Process unit listed in Table Reduce emissions Total HAP
1B to this subpart. of total HAP, emissions,
measured as THC, measured using
by 90 percent. the methods in
Table 4 to this
subpart over the
3-hour
performance test,
are reduced by at
least 90 percent,
as calculated
using the
procedures in
Sec. 63.2262;
AND you have a
record of the
operating
requirement(s)
listed in Table 2
to this subpart
for the process
unit over the
performance test
during which
emissions were
reduced by at
least 90 percent.
(3) Process unit listed in Table Limit emissions of The average total
1B to this subpart. total HAP, HAP emissions,
measured as THC, measured using
to 20 ppmvd. the methods in
Table 4 to this
subpart over the
3-hour
performance test,
do not exceed 20
ppmvd; AND you
have a record of
the operating
requirement(s)
listed in Table 2
to this subpart
for the process
unit over the
performance test
during which
emissions did not
exceed 20 ppmvd.
(4) Process unit listed in Table Reduce methanol or The methanol or
1B to this subpart. formaldehyde formaldehyde
emissions by 90 emissions
percent. measured using
the methods in
Table 4 to this
subpart over the
3-hour
performance test,
are reduced by at
least 90 percent,
as calculated
using the
procedures in
Sec. 63.2262;
AND you have a
record of the
operating
requirement(s)
listed in Table 2
to this subpart
for the process
unit over the
performance test
during which
emissions were
reduced by at
least 90 percent.
(5) Process unit listed in Table Limit methanol or The average
1B to this subpart. formaldehyde methanol or
emissions to less formaldehyde
than or equal to emissions,
1 ppmvd (if measured using
uncontrolled the methods in
emissions are Table 4 to this
greater than or subpart over the
equal to 10 3-hour
ppmvd). performance test,
do not exceed 1
ppmvd; AND you
have a record of
the operating
requirement(s)
listed in Table 2
to this subpart
for the process
unit over the
performance test
during which
emissions did not
exceed 1 ppmvd.
If the process
unit is a
reconstituted
wood product
press or a
reconstituted
wood product
board cooler,
your capture
device either
meets the EPA
Method 204
criteria for a
PTE or achieves a
capture
efficiency of
greater than or
equal to 95
percent.
(6) Reconstituted wood product Compliance options You submit the
press at a new or existing in Tables 1A and results of
affected source, or 1B to this capture
reconstituted wood product subpart or the efficiency
board cooler at a new affected emissions verification
source. averaging using the methods
compliance option in Table 4 to
in Sec. this subpart with
63.2240(c). your Notification
of Compliance
Status.
(7) Process unit listed in Table Compliance options You submit with
1B to this subpart controlled in Table 1B to your Notification
by routing exhaust to a this subpart or of Compliance
combustion unit. the emissions Status
averaging documentation
compliance option showing that the
in Sec. process exhausts
63.2240(c). controlled enter
into the flame
zone of your
combustion unit.
[[Page 247]]
(8) Process unit listed in Table Compliance options You submit with
1B to this subpart using a wet in Table 1B to your Notification
control device as the sole this subpart or of Compliance
means of reducing HAP emissions. the emissions Status your plan
averaging to address how
compliance option organic HAP
in Sec. captured in the
63.2240(c). wastewater from
the wet control
device is
contained or
destroyed to
minimize re-
release to the
atmosphere.
------------------------------------------------------------------------
Table 6 to Subpart DDDD of Part 63--Initial Compliance Demonstrations
for Work Practice Requirements
------------------------------------------------------------------------
You have
For the following demonstrated
For each . . . work practice initial compliance
requirements . . . if . . .
------------------------------------------------------------------------
(1) Dry rotary dryer............ Process furnish You meet the work
with an inlet practice
moisture content requirement AND
less than or you submit a
equal to 30 signed statement
percent (by with the
weight, dry Notification of
basis) AND Compliance Status
operate with an that the dryer
inlet dryer meets the
temperature of criteria of a
less than or ``dry rotary
equal to 600 dryer'' AND you
[deg]F. have a record of
the inlet
moisture content
and inlet dryer
temperature (as
required in Sec.
63.2263).
(2) Hardwood veneer dryer....... Process less than You meet the work
30 volume percent practice
softwood species. requirement AND
you submit a
signed statement
with the
Notification of
Compliance Status
that the dryer
meets the
criteria of a
``hardwood veneer
dryer'' AND you
have a record of
the percentage of
softwoods
processed in the
dryer (as
required in Sec.
63.2264).
(3) Softwood veneer dryer....... Minimize fugitive You meet the work
emissions from practice
the dryer doors requirement AND
and the green end. you submit with
the Notification
of Compliance
Status a copy of
your plan for
minimizing
fugitive
emissions from
the veneer dryer
heated zones (as
required in Sec.
63.2265).
(4) Veneer redryers............. Process veneer You meet the work
with an inlet practice
moisture content requirement AND
of less than or you submit a
equal to 25 signed statement
percent (by with the
weight, dry Notification of
basis). Compliance Status
that the dryer
operates only as
a redryer AND you
have a record of
the veneer inlet
moisture content
of the veneer
processed in the
redryer (as
required in Sec.
63.2266).
(5) Group 1 miscellaneous Use non-HAP You meet the work
coating operations. coatings as practice
defined in Sec. requirement AND
63.2292. you submit a
signed statement
with the
Notification of
Compliance Status
that you are
using non-HAP
coatings AND you
have a record
showing that you
are using non-HAP
coatings.
------------------------------------------------------------------------
Table 7 to Subpart DDDD of Part 63--Continuous Compliance With the
Compliance Options and Operating Requirements
------------------------------------------------------------------------
You must
For the following demonstrate
For . . . compliance options continuous
and operating compliance by . .
requirements . . . .
------------------------------------------------------------------------
(1) Each process unit listed in Compliance options Collecting and
Table 1B to this subpart or in Table 1B to recording the
used in calculation of an this subpart or operating
emissions average under Sec. the emissions parameter
63.2240(c). averaging monitoring system
compliance option data listed in
in Sec. Table 2 to this
63.2240(c) and subpart for the
the operating process unit
requirements in according to Sec.
Table 2 to this 63.2269(a)
subpart based on through (b) and
monitoring of Sec. 63.2270;
operating AND reducing the
parameters. operating
parameter
monitoring system
data to the
specified
averages in units
of the applicable
requirement
according to
calculations in
Sec. 63.2270;
AND maintaining
the average
operating
parameter at or
above the
minimum, at or
below the
maximum, or
within the range
(whichever
applies)
established
according to Sec.
63.2262.
[[Page 248]]
(2) Each process unit listed in Compliance options Collecting and
Tables 1A and 1B to this in Tables 1A and recording the THC
subpart or used in calculation 1B to this monitoring data
of an emissions average under subpart or the listed in Table 2
Sec. 63.2240(c). emissions to this subpart
averaging for the process
compliance option unit according to
in Sec. Sec.
63.2240(c) and 63.2269(d); AND
the operating reducing the CEMS
requirements in data to 3-hour
Table 2 of this block averages
subpart based on according to
THC CEMS data. calculations in
Sec.
63.2269(d); AND
maintaining the 3-
hour block
average THC
concentration in
the exhaust gases
less than or
equal to the THC
concentration
established
according to Sec.
63.2262.
(3) Each process unit using a Compliance options Conducting a
biofilter. in Tables 1B to repeat
this subpart or performance test
the emissions using the
averaging applicable
compliance option method(s)
in Sec. specified in
63.2240(c). Table 4 to this
subpart within 2
years following
the previous
performance test
and within 180
days after each
replacement of
any portion of
the biofilter bed
media with a
different type of
media or each
replacement of
more than 50
percent (by
volume) of the
biofilter bed
media with the
same type of
media.
(4) Each process unit using a Compliance options Checking the
catalytic oxidizer. in Table 1B to activity level of
this subpart or a representative
the emissions sample of the
averaging catalyst at least
compliance option every 12 months
in Sec. and taking any
63.2240(c). necessary
corrective action
to ensure that
the catalyst is
performing within
its design range.
(5) Each process unit listed in Compliance options Collecting and
Table 1A to this subpart, or in Table 1A to recording on a
each process unit without a this subpart or daily basis
control device used in the emissions process unit
calculation of an emissions averaging controlling
averaging debit under Sec. compliance option operating
63.2240(c). in Sec. parameter data;
63.2240(c) and AND maintaining
the operating the operating
requirements in parameter at or
Table 2 to this above the
subpart based on minimum, at or
monitoring of below the
process unit maximum, or
controlling within the range
operating (whichever
parameters. applies)
established
according to Sec.
63.2262.
(6) Each Process unit listed in Compliance options Implementing your
Table 1B to this subpart using in Table 1B to plan to address
a wet control device as the this subpart or how organic HAP
sole means of reducing HAP the emissions captured in the
emissions. averaging wastewater from
compliance option the wet control
in Sec. device is
63.2240(c). contained or
destroyed to
minimize re-
release to the
atmosphere.
------------------------------------------------------------------------
Table 8 to Subpart DDDD of Part 63--Continuous Compliance With the Work
Practice Requirements
------------------------------------------------------------------------
You must
For the following demonstrate
For . . . work practice continuous
requirements . . . compliance by . .
.
------------------------------------------------------------------------
(1) Dry rotary dryer............ Process furnish Maintaining the 24-
with an inlet hour block
moisture content average inlet
less than or furnish moisture
equal to 30 content at less
percent (by than or equal to
weight, dry 30 percent (by
basis) AND weight, dry
operate with an basis) AND
inlet dryer maintaining the
temperature of 24-hour block
less than or average inlet
equal to 600 dryer temperature
[deg]F. at less than or
equal to 600
[deg]F; AND
keeping records
of the inlet
temperature of
furnish moisture
content and inlet
dryer
temperature.
(2) Hardwood veneer dryer....... Process less than Maintaining the
30 volume percent volume percent
softwood species. softwood species
processed below
30 percent AND
keeping records
of the volume
percent softwood
species
processed.
(3) Softwood veneer dryer....... Minimize fugitive Following (and
emissions from documenting that
the dryer doors you are
and the green end. following) your
plan for
minimizing
fugitive
emissions.
(4) Veneer redryers............. Process veneer Maintaining the 24-
with an inlet hour block
moisture content average inlet
of less than or moisture content
equal to 25 of the veneer
percent (by processed at or
weight, dry below of less
basis). than or 25
percent AND
keeping records
of the inlet
moisture content
of the veneer
processed.
[[Page 249]]
(5) Group 1 miscellaneous Use non-HAP Continuing to use
coating operations. coatings as non-HAP coatings
defined in Sec. AND keeping
63.2292. records showing
that you are
using non-HAP
coatings.
------------------------------------------------------------------------
Table 9 to Subpart DDDD of Part 63--Requirements for Reports
------------------------------------------------------------------------
The report must You must submit
You must submit a(n) . . . contain . . . the report . . .
------------------------------------------------------------------------
(1) Compliance report........... The information in Semiannually
Sec. 63.2281(c) according to the
through (g). requirements in
Sec.
63.2281(b).
(2) immediate startup, shutdown, (i) Actions taken By fax or
and malfunction report if you for the event. telephone within
had a startup, shutdown, or 2 working days
malfunction during the after starting
reporting period that is not actions
consistent with your SSMP. inconsistent with
the plan.
(ii) The By letter within 7
information in working days
Sec. after the end of
63.10(d)(5)(ii). the event unless
you have made
alternative
arrangements with
the permitting
authority.
------------------------------------------------------------------------
Table 10 to Subpart DDDD of Part 63--Applicability of General Provisions
to Subpart DDDD
----------------------------------------------------------------------------------------------------------------
Citation Subject Brief description Applies to subpart DDDD
----------------------------------------------------------------------------------------------------------------
Sec. 63.1......................... Applicability.......... Initial applicability Yes.
determination;
applicability after
standard established;
permit requirements;
extensions,
notifications.
Sec. 63.2......................... Definitions............ Definitions for part Yes.
63 standards.
Sec. 63.3......................... Units and Abbreviations Units and Yes.
abbreviations for
part 63 standards.
Sec. 63.4......................... Prohibited Activities.. Prohibited activities; Yes.
compliance date;
circumvention,
fragmentation.
Sec. 63.5......................... Construction/ Applicability; Yes.
Reconstruction. applications;
approvals.
Sec. 63.6(a)...................... Applicability.......... GP apply unless Yes.
compliance extension;
GP apply to area
sources that become
major.
Sec. 63.6(b)(1)-(4)............... Compliance Dates for Standards apply at Yes.
New and Reconstructed effective date; 3
Sources. years after effective
date; upon startup;
10 years after
construction or
reconstruction
commences for section
112(f).
Sec. 63.6(b)(5)................... Notification........... Must notify if Yes.
commenced
construction or
reconstruction after
proposal.
Sec. 63.6(b)(6)................... [Reserved].............
Sec. 63.6(b)(7)................... Compliance Dates for Area sources that Yes.
New and Reconstructed become major must
Area Sources that comply with major
Become Major. source standards
immediately upon
becoming major,
regardless of whether
required to comply
when they were an
area source.
Sec. 63.6(c)(1)-(2)............... Compliance Dates for Comply according to Yes.
Existing Sources. date in subpart,
which must be no
later than 3 years
after effective date;
for section 112(f)
standards, comply
within 90 days of
effective date unless
compliance extension.
Sec. 63.6(c)(3)-(4)............... [Reserved].............
Sec. 63.6(c)(5)................... Compliance Dates for Area sources that Yes.
Existing Area Sources become major must
that Become Major. comply with major
source standards by
date indicated in
subpart or by
equivalent time
period (e.g., 3
years).
Sec. 63.6(d)...................... [Reserved].............
[[Page 250]]
Sec. 63.6(e)(1)-(2)............... Operation & Maintenance Operate to minimize Yes.
emissions at all
times; correct
malfunctions as soon
as practicable;
operation and
maintenance
requirements
independently
enforceable;
information
Administrator will
use to determine if
operation and
maintenance
requirements were met.
Sec. 63.6(e)(3)................... Startup, Shutdown, and Requirement for SSM Yes.
Malfunction Plan and SSMP; content of
(SSMP). SSMP.
Sec. 63.6(f)(1)................... Compliance Except You must comply with Yes.
During SSM. emission standards at
all times except
during SSM.
Sec. 63.6(f)(2)-(3)............... Methods for Determining Compliance based on Yes.
Compliance. performance test,
operation and
maintenance plans,
records, inspection.
Sec. 63.6(g)(1)-(3)............... Alternative Standard... Procedures for getting Yes.
an alternative
standard.
Sec. 63.6(h)(1)-(9)............... Opacity/Visible Requirements for NA.
Emission (VE) opacity and visible
Standards. emission standards.
Sec. 63.6(i)(1)-(14).............. Compliance Extension... Procedures and Yes.
criteria for
Administrator to
grant compliance
extension.
Sec. 63.6(i)(15).................. [Reserved].............
Sec. 63.6(i)(16).................. Compliance Extension... Compliance extension Yes.
and Administrator's
authority.
Sec. 63.6(j)...................... Presidential Compliance President may exempt Yes.
Exemption. source category from
requirement to comply
with rule.
Sec. 63.7(a)(1)-(2)............... Performance Test Dates. Dates for conducting Yes.
initial performance
testing and other
compliance
demonstrations; must
conduct 180 days
after first subject
to rule.
Sec. 63.7(a)(3)................... Section 114 Authority.. Administrator may Yes.
require a performance
test under CAA
section 114 at any
time.
Sec. 63.7(b)(1)................... Notification of Must notify Yes.
Performance Test. Administrator 60 days
before the test.
Sec. 63.7(b)(2)................... Notification of If have to reschedule Yes.
Rescheduling. performance test,
must notify
Administrator as soon
as practicable.
Sec. 63.7(c)...................... Quality Assurance/Test Requirement to submit Yes.
Plan. site-specific test
plan 60 days before
the test or on date
Administrator agrees
with; test plan
approval procedures;
performance audit
requirements;
internal and external
QA procedures for
testing.
Sec. 63.7(d)...................... Testing Facilities..... Requirements for Yes.
testing facilities.
Sec. 63.7(e)(1)................... Conditions for Performance tests must Yes.
Conducting Performance be conducted under
Tests. representative
conditions; cannot
conduct performance
tests during SSM; not
a violation to exceed
standard during SSM.
Sec. 63.7(e)(2)................... Conditions for Must conduct according Yes.
Conducting Performance to rule and EPA test
Tests. methods unless
Administrator
approves alternative.
Sec. 63.7(e)(3)................... Test Run Duration...... Must have three test Yes.
runs for at least the
time specified in the
relevant standard;
compliance is based
on arithmetic mean of
three runs; specifies
conditions when data
from an additional
test run can be used.
Sec. 63.7(f)...................... Alternative Test Method Procedures by which Yes.
Administrator can
grant approval to use
an alternative test
method.
[[Page 251]]
Sec. 63.7(g)...................... Performance Test Data Must include raw data Yes.
Analysis. in performance test
report; must submit
performance test data
60 days after end of
test with the
notification of
compliance status;
keep data for 5 years.
Sec. 63.7(h)...................... Waiver of Tests........ Procedures for Yes.
Administrator to
waive performance
test.
Sec. 63.8(a)(1)................... Applicability of Subject to all Yes.
Monitoring monitoring
Requirements. requirements in
standard.
Sec. 63.8(a)(2)................... Performance Performance Yes.
Specifications. specifications in
appendix B of part 60
apply.
Sec. 63.8(a)(3)................... [Reserved].............
Sec. 63.8(a)(4)................... Monitoring with Flares. Requirements for NA.
flares in Sec.
63.11 apply.
Sec. 63.8(b)(1)................... Monitoring............. Must conduct Yes.
monitoring according
to standard unless
Administrator
approves alternative.
Sec. 63.8(b)(2)-(3)............... Multiple Effluents and Specific requirements Yes.
Multiple Monitoring for installing
Systems. monitoring systems;
must install on each
effluent before it is
combined and before
it is released to the
atmosphere unless
Administrator
approves otherwise;
if more than one
monitoring system on
an emission point,
must report all
monitoring system
results, unless one
monitoring system is
a backup.
Sec. 63.8(c)(1)................... Monitoring System Maintain monitoring Yes.
Operation and system in a manner
Maintenance. consistent with and
good air pollution
control practices.
Sec. 63.8(c)(1)(i)................ Operation and Must maintain and Yes.
Maintenance of CMS. operate CMS in
accordance with Sec.
63.6(e)(1).
Sec. 63.8(c)(1)(ii)............... Spare Parts for CMS.... Must maintain spare Yes.
parts for routine CMS
repairs.
Sec. 63.8(c)(1)(iii).............. SSMP for CMS........... Must develop and Yes.
implement SSMP for
CMS.
Sec. 63.8(c)(2)-(3)............... Monitoring System Must install to get Yes.
Installation. representative
emission of parameter
measurements; must
verify operational
status before or at
performance test.
Sec. 63.8(c)(4)................... Continuous Monitoring CMS must be operating Yes.
System (CMS) except during
Requirements. breakdown, out-of-
control, repair,
maintenance, and high-
level calibration
drifts; COMS must
have a minimum of one
cycle of sampling and
analysis for each
successive 10-second
period and one cycle
of data recording for
each successive 6-
minute period; CEMS
must have a minimum
of one cycle of
operation for each
successive 15-minute
period.
Sec. 63.8(c)(5)................... Continuous Opacity COMS minimum NA.
Monitoring System procedures.
(COMS) Minimum
Procedures.
Sec. 63.8(c)(6)-(8)............... CMS Requirements....... Zero and high-level Yes.
calibration check
requirements; out-of-
control periods.
Sec. 63.8(d)...................... CMS Quality Control.... Requirements for CMS Yes.
quality control,
including
calibration, etc.;
must keep quality
control plan on
record for 5 years.
Keep old versions for
5 years after
revisions.
Sec. 63.8(e)...................... CMS Performance Notification, Yes.
Evaluation. performance
evaluation test plan,
reports.
[[Page 252]]
Sec. 63.8(f)(1)-(5)............... Alternative Monitoring Procedures for Yes.
Method. Administrator to
approve alternative
monitoring.
Sec. 63.8(f)(6)................... Alternative to Relative Procedures for Yes.
Accuracy Test. Administrator to
approve alternative
relative accuracy
tests for CEMS.
Sec. 63.8(g)...................... Data Reduction......... COMS 6-minute averages Yes.
calculated over at
least 36 evenly
spaced data points;
CEMS 1 hour averages
computed over at
least 4 equally
spaced data points;
data that can't be
used in average;
rounding of data.
Sec. 63.9(a)...................... Notification Applicability and Yes.
Requirements. State delegation.
Sec. 63.9(b)(1)-(2)............... Initial Notifications.. Submit notification Yes.
120 days after
effective date;
contents of
notification.
Sec. 63.9(b)(3)................... [Reserved].............
Sec. 63.9(b)(4)-(5)............... Initial Notifications.. Submit notification Yes.
120 days after
effective date;
notification of
intent to construct/
reconstruct;
notification of
commencement of
construct/
reconstruct;
notification of
startup; contents of
each.
Sec. 63.9(c)...................... Request for Compliance Can request if cannot Yes.
Extension. comply by date or if
installed best
available control
technology/lowest
achievable emission
rate.
Sec. 63.9(d)...................... Notification of Special For sources that Yes.
Compliance commence construction
Requirements for New between proposal and
Source. promulgation and want
to comply 3 years
after effective date.
Sec. 63.9(e)...................... Notification of Notify EPA Yes.
Performance Test. Administrator 60 days
prior.
Sec. 63.9(f)...................... Notification of Visible Notify EPA No.
Emissions/Opacity Test. Administrator 30 days
prior.
Sec. 63.9(g)...................... Additional Notification of Yes.
Notifications When performance
Using CMS. evaluation;
notification using
COMS data;
notification that
exceeded criterion
for relative accuracy.
Sec. 63.9(h)(1)-(6)............... Notification of Contents; due 60 days Yes.
Compliance Status. after end of
performance test or
other compliance
demonstration, except
for opacity/VE, which
are due 30 days
after; when to submit
to Federal vs. State
authority.
Sec. 63.9(i)...................... Adjustment of Submittal Procedures for Yes.
Deadlines. Administrator to
approve change in
when notifications
must be submitted.
Sec. 63.9(j)...................... Change in Previous Must submit within 15 Yes.
Information. days after the change.
Sec. 63.10(a)..................... Recordkeeping/Reporting Applies to all, unless Yes.
compliance extension;
when to submit to
Federal vs. State
authority; procedures
for owners of more
than one source.
Sec. 63.10(b)(1).................. Recordkeeping/Reporting General Requirements; Yes.
keep all records
readily available;
keep for 5 years.
Sec. 63.10(b)(2)(i)-(iv).......... Records Related to Occurrence of each of Yes.
Startup, Shutdown, and operation (process
Malfunction. equipment);
occurrence of each
malfunction of air
pollution equipment;
maintenance on air
pollution control
equipment; actions
during startup,
shutdown, and
malfunction.
Sec. 63.10(b)(2)(vi) and (x)-(xi). CMS Records............ Malfunctions, Yes.
inoperative, out-of-
control.
[[Page 253]]
Sec. 63.10(b)(2)(vii)-(ix)........ Records................ Measurements to Yes.
demonstrate
compliance with
compliance options
and operating
requirements;
performance test,
performance
evaluation, and
visible emission
observation results;
measurements to
determine conditions
of performance tests
and performance
evaluations.
Sec. 63.10(b)(2)(xii)............. Records................ Records when under Yes.
waiver.
Sec. 63.10(b)(2)(xiii)............ Records................ Records when using Yes.
alternative to
relative accuracy
test.
Sec. 63.10(b)(2)(xiv)............. Records................ All documentation Yes.
supporting initial
notification and
notification of
compliance status.
Sec. 63.10(b)(3).................. Records................ Applicability Yes.
determinations.
Sec. 63.10(c)(1)-(6), (9)-(15).... Records................ Additional records for Yes.
CMS.
Sec. 63.10(c)(7)-(8).............. Records................ Records of excess No.
emissions and
parameter monitoring
exceedances for CMS.
Sec. 63.10(d)(1).................. General Reporting Requirement to report. Yes.
Requirements.
Sec. 63.10(d)(2).................. Report of Performance When to submit to Yes.
Test Results. Federal or State
authority.
Sec. 63.10(d)(3).................. Reporting Opacity or VE What to report and NA.
Observations. when.
Sec. 63.10(d)(4).................. Progress Reports....... Must submit progress Yes.
reports on schedule
if under compliance
extension.
Sec. 63.10(d)(5).................. Startup, Shutdown, and Contents and Yes.
Malfunction Reports. submission.
Sec. 63.10(e)(1)-(2).............. Additional CMS Reports. Must report results Yes.
for each CEM on a
unit; written copy of
performance
evaluation; 3 copies
of COMS performance
evaluation.
Sec. 63.10(e)(3).................. Reports................ Excess emission No.
reports.
Sec. 63.10(e)(4).................. Reporting COMS data.... Must submit COMS data NA.
with performance test
data.
Sec. 63.10(f)..................... Waiver for Procedures for EPA Yes.
Recordkeeping/ Administrator to
Reporting. waive.
Sec. 63.11........................ Flares................. Requirements for NA.
flares.
Sec. 63.12........................ Delegation............. State authority to Yes.
enforce standards.
Sec. 63.13........................ Addresses.............. Addresses where Yes.
reports,
notifications, and
requests are send.
Sec. 63.14........................ Incorporation by Test methods Yes.
Reference. incorporated by
reference.
Sec. 63.15........................ Availability of Public and Yes.
Information. confidential
information.
----------------------------------------------------------------------------------------------------------------
Appendix A to Subpart DDDD of Part 63--Alternative Procedure To
Determine Capture Efficiency From Enclosures Around Hot Presses in the
Plywood and Composite Wood Products Industry Using Sulfur Hexafluoride
Tracer Gas
1.0 Scope and Application
This procedure has been developed specifically for the rule for the
plywood and composite wood products (PCWP) industry and is used to
determine the capture efficiency of a partial hot press enclosure in
that industry. This procedure is applicable for the determination of
capture efficiency for enclosures around hot presses and is an
alternative to the construction of temporary total enclosures (TTE).
Sulfur hexafluoride (SF6) is used as a tracer gas (other
tracer gases may be used if approved by the EPA Administrator). This gas
is not indigenous to the ambient atmosphere and is nonreactive.
This procedure uses infrared spectrometry (IR) as the analytical
technique. When the infrared spectrometer used is a Fourier-Transform
Infrared spectrometer (FTIR), an alternate instrument calibration
procedure may be used; the alternate calibration procedure is the
calibration transfer standard (CTS) procedure of EPA Method 320
(appendix A to 40 CFR part 63). Other analytical
[[Page 254]]
techniques which are capable of equivalent Method Performance (Section
13.0) also may be used. Specifically, gas chromatography with electron
capture detection (GC/ECD) is an applicable technique for analysis of
SF6.
2.0 Summary of Method
A constant mass flow rate of SF6 tracer gas is released
through manifolds at multiple locations within the enclosure to mimic
the release of hazardous air pollutants during the press process. This
test method requires a minimum of three SF6 injection points
(two at the press unloader and one at the press) and provides details
about considerations for locating the injection points. A GC/ECD is used
to measure the concentration of SF6 at the inlet duct to the
control device (outlet duct from enclosure). Simultaneously, EPA Method
2 (appendix A to 40 CFR part 60) is used to measure the flow rate at the
inlet duct to the control device. The concentration and flow rate
measurements are used to calculate the mass emission rate of
SF6 at the control device inlet. Through calculation of the
mass of SF6 released through the manifolds and the mass of
SF6 measured at the inlet to the control device, the capture
efficiency of the enclosure is calculated.
In addition, optional samples of the ambient air may be taken at
locations around the perimeter of the enclosure to quantify the ambient
concentration of SF6 and to identify those areas of the
enclosure that may be performing less efficiently; these samples would
be taken using disposable syringes and would be analyzed using a GC/ECD.
Finally, in addition to the requirements specified in this
procedure, the data quality objectives (DQO) or lower confidence limit
(LCL) criteria specified in appendix A to 40 CFR part 63, subpart KK,
Data Quality Objective and Lower Confidence Limit Approaches for
Alternative Capture Efficiency Protocols and Test Methods, must also be
satisfied. A minimum of three test runs are required for this procedure;
however, additional test runs may be required based on the results of
the DQO or LCL analysis.
3.0 Definitions
3.1 Capture efficiency (CE). The weight per unit time of
SF6 entering the control device divided by the weight per
unit time of SF6 released through manifolds at multiple
locations within the enclosure.
3.2 Control device (CD). The equipment used to reduce, by
destruction or removal, press exhaust air pollutants prior to discharge
to the ambient air.
3.3 Control/destruction efficiency (DE). The volatile organic
compound or HAP removal efficiency of the control device.
3.4 Data Quality Objective (DQO) Approach. A statistical procedure
to determine the precision of the data from a test series and to qualify
the data in the determination of capture efficiency for compliance
purposes. If the results of the DQO analysis of the initial three test
runs do not satisfy the DQO criterion, the LCL approach can be used or
additional test runs must be conducted. If additional test runs are
conducted, then the DQO or LCL analysis is conducted using the data from
both the initial test runs and all additional test runs.
3.5 Lower Confidence Limit (LCL) Approach. An alternative
statistical procedure that can be used to qualify data in the
determination of capture efficiency for compliance purposes. If the
results of the LCL approach produce a CE that is too low for
demonstrating compliance, then additional test runs must be conducted
until the LCL or DQO is met. As with the DQO, data from all valid test
runs must be used in the calculation.
3.6 Minimum Measurement Level (MML). The minimum tracer gas
concentration expected to be measured during the test series. This value
is selected by the tester based on the capabilities of the IR
spectrometer (or GC/ECD) and the other known or measured parameters of
the hot press enclosure to be tested. The selected MML must be above the
low-level calibration standard and preferably below the mid-level
calibration standard.
3.7 Method 204. The U.S. EPA Method 204, ``Criteria For and
Verification of a Permanent or Temporary Total Enclosure'' (40 CFR part
51, appendix M).
3.8 Method 205. The U.S. EPA Method 205, ``Verification of Gas
Dilution Systems for Field Instrument Calibrations'' (40 CFR part 51,
appendix M).
3.9 Method 320. The U.S. EPA Method 320, ``Measurement of Vapor
Phase Organic and Inorganic Emissions by Extractive Fourier Transform
Infrared (FTIR) Spectroscopy'' (40 CFR part 63, appendix A).
3.10 Overall capture and control efficiency (CCE). The collection
and control/destruction efficiency of both the PPE and CD combined. The
CCE is calculated as the product of the CE and DE.
3.11 Partial press enclosure (PPE). The physical barrier that
``partially'' encloses the press equipment, captures a significant
amount of the associated emissions, and transports those emissions to
the CD.
3.12 Test series. A minimum of three test runs or, when more than
three runs are conducted, all of the test runs conducted.
4.0 Interferences
There are no known interferences.
5.0 Safety
Sulfur hexafluoride is a colorless, odorless, nonflammable liquefied
gas. It is stable and nonreactive and, because it is noncorrosive,
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most structural materials are compatible with it. The Occupational
Safety and Health Administration Permissible Emission Limit-Time
Weighted Average (PEL-TWA) and Threshold Limit Value-Time Weighted
Average (TLV-TWA) concentrations are 1,000 parts per million. Sulfur
hexafluoride is an asphyxiant. Exposure to an oxygen-deficient
atmosphere (less than 19.5 percent oxygen) may cause dizziness,
drowsiness, nausea, vomiting, excess salivation, diminished mental
alertness, loss of consciousness, and death. Exposure to atmospheres
containing less than 12 percent oxygen will bring about unconsciousness
without warning and so quickly that the individuals cannot help
themselves. Contact with liquid or cold vapor may cause frostbite. Avoid
breathing sulfur hexafluoride gas. Self-contained breathing apparatus
may be required by rescue workers. Sulfur hexafluoride is not listed as
a carcinogen or a potential carcinogen.
6.0 Equipment and Supplies
This method requires equipment and supplies for: (a) the injection
of tracer gas into the enclosure, (b) the measurement of the tracer gas
concentration in the exhaust gas entering the control device, and (c)
the measurement of the volumetric flow rate of the exhaust gas entering
the control device. In addition, the requisite equipment needed for EPA
Methods 1-4 in appendix A to 40 CFR part 60 will be required. Equipment
and supplies for optional ambient air sampling are discussed in Section
8.6.
6.1 Tracer Gas Injection.
6.1.1 Manifolds. This method requires the use of tracer gas supply
cylinder(s) along with the appropriate flow control elements. Figure 1
shows a schematic drawing of the injection system showing potential
locations for the tracer gas manifolds. Figure 2 shows a schematic
drawing of the recommended configuration of the injection manifold.
Three tracer gas discharge manifolds are required at a minimum.
6.1.2 Flow Control Meter. Flow control and measurement meter for
measuring the quantity of tracer gas injected. A mass flow, volumetric
flow, or critical orifice control meter can be used for this method. The
meter must be accurate to within 5 percent at the
flow rate used. This means that the flow meter must be calibrated
against a primary standard for flow measurement at the appropriate flow
rate.
6.2 Measurement of Tracer Gas Concentration.
6.2.1 Sampling Probes. Use Pyrex or stainless steel sampling probes
of sufficient length to reach the traverse points calculated according
to EPA Method 1 (appendix A to 40 CFR part 60).
6.2.2 Sampling Line. Use a heated Teflon sampling line to transport
the sample to the analytical instrument.
6.2.3 Sampling Pump. Use a sampling pump capable of extracting
sufficient sample from the duct and transporting to the analytical
instrument.
6.2.4 Sample Conditioning System. Use a particulate filter
sufficient to protect the sampling pump and analytical instrument. At
the discretion of the tester and depending on the equipment used and the
moisture content of the exhaust gas, it may be necessary to further
condition the sample by removing moisture using a condenser.
6.2.5 Analytical Instrument. Use one of the following analytical
instruments.
6.2.5.1 Spectrometer. Use an infrared spectrometer designed to
measuring SF6 tracer gas and capable of meeting or exceeding
the specifications of this procedure. An FTIR meeting the specifications
of Method 320 in appendix A to 40 CFR part 63 may be used.
6.2.5.2 GC/ECD. Use a GC/ECD designed to measure SF6
tracer gas and capable of meeting or exceeding the specifications of
this procedure.
6.2.6 Recorder. At a minimum, use a recorder with linear strip
chart. An automated data acquisition system (DAS) is recommended.
6.3 Exhaust Gas Flow Rate Measurement. Use equipment specified for
EPA Methods 2, 3, and 4 in appendix A to 40 CFR part 60 for measuring
flow rate of exhaust gas at the inlet to the control device.
7.0 Reagents and Standards
7.1 Tracer Gas. Use SF6 as the tracer gas. The
manufacturer of the SF6 tracer gas should provide a
recommended shelf life for the tracer gas cylinder over which the
concentration does not change more than 2 percent
from the certified value. A gas mixture of SF6 diluted with
nitrogen should be used; based on experience and calculations, pure
SF6 gas is not necessary to conduct tracer gas testing.
Select a concentration and flow rate that is appropriate for the
analytical instrument's detection limit, the MML, and the exhaust gas
flow rate from the enclosure (see section 8.1.1). You may use a tracer
gas other than SF6 with the prior approval of the EPA
Administrator. If you use an approved tracer gas other than
SF6, all references to SF6 in this protocol
instead refer to the approved tracer gas.
7.2 Calibration Gases. The SF6 calibration gases required
will be dependent on the selected MML and the appropriate span selected
for the test. Commercial cylinder gases certified by the manufacturer to
be accurate to within 1 percent of the certified label value are
preferable, although cylinder gases certified by the manufacturer to 2
percent accuracy are allowed. Additionally, the manufacturer of the
SF6 calibration gases should provide a recommended shelf life
for each calibration gas cylinder over which the concentration does not
change more than 2
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percent from the certified value. Another option allowed by this method
is for the tester to obtain high concentration certified cylinder gases
and then use a dilution system meeting the requirements of EPA Method
205, 40 CFR part 51, appendix M, to make multi-level calibration gas
standards. Low-level, mid-level, and high-level calibration gases will
be required. The MML must be above the low-level standard, the high-
level standard must be no more than four times the low-level standard,
and the mid-level standard must be approximately halfway between the
high- and low-level standards. See section 12.1 for an example
calculation of this procedure.
Note: If using an FTIR as the analytical instrument, the tester has
the option of following the CTS procedures of Method 320 in appendix A
to 40 CFR part 63; the calibration standards (and procedures) specified
in Method 320 may be used in lieu of the calibration standards and
procedures in this protocol.
7.2.1 Zero Gas. High purity nitrogen.
7.2.2 Low-Level Calibration Gas. An SF6 calibration gas
in nitrogen with a concentration equivalent to 20 to 30 percent of the
applicable span value.
7.2.3 Mid-Level Calibration Gas. An SF6 calibration gas
in nitrogen with a concentration equivalent to 45 to 55 percent of the
applicable span value.
7.2.4 High-Level Calibration Gas. An SF6 calibration gas
in nitrogen with a concentration equivalent to 80 to 90 percent of the
applicable span value.
8.0 Sample Collection, Preservation, Storage, and Transport
8.1 Test Design.
8.1.1 Determination of Minimum Tracer Gas Flow Rate.
8.1.1.1 Determine (via design calculations or measurements) the
approximate flow rate of the exhaust gas through the enclosure, actual
cubic feet per minute (acfm).
8.1.1.2 Calculate the minimum tracer gas injection rate necessary to
assure a detectable SF6 concentration at the exhaust gas
measurement point (see section 12.1 for calculation).
8.1.1.3 Select a flow meter for the injection system with an
operating range appropriate for the injection rate selected.
8.1.2 Determination of the Approximate Time to Reach Equilibrium.
8.1.2.1 Determine the volume of the enclosure.
8.1.2.2 Calculate the air changes per minute of the enclosure by
dividing the approximate exhaust flow rate (8.1.1.1 above) by the
enclosed volume (8.1.2.1 above).
8.1.2.3 Calculate the time at which the tracer concentration in the
enclosure will achieve approximate equilibrium. Divide 3 by the air
changes per minute (8.1.2.2 above) to establish this time. This is the
approximate length of time for the system to come to equilibrium.
Concentration equilibrium occurs when the tracer concentration in the
enclosure stops changing as a function of time for a constant tracer
release rate. Because the press is continuously cycling, equilibrium may
be exhibited by a repeating, but stable, cyclic pattern rather than a
single constant concentration value. Assure sufficient tracer gas is
available to allow the system to come to equilibrium, and to sample for
a minimum of 20 minutes and repeat the procedure for a minimum of three
test runs. Additional test runs may be required based on the results of
the DQO and LCL analyses described in 40 CFR part 63, subpart KK,
appendix A.
8.1.3 Location of Injection Points. This method requires a minimum
of three tracer gas injection points. The injection points should be
located within leak prone, volatile organic compound/hazardous air
pollutant (VOC/HAP) producing areas around the press, or horizontally
within 12 inches of the defined equipment. One potential configuration
of the injection points is depicted in Figure 1. The effect of wind,
exfiltration through the building envelope, and air flowing through open
building doors should be considered when locating tracer gas injection
points within the enclosure. The injection points should also be located
at a vertical elevation equal to the VOC/HAP generating zones. The
injection points should not be located beneath obstructions that would
prevent a natural dispersion of the gas. Document the selected injection
points in a drawing(s).
8.1.4 Location of Flow Measurement and Tracer Sampling. Accurate CD
inlet gas flow rate measurements are critical to the success of this
procedure. Select a measurement location meeting the criteria of EPA
Method 1 (40 CFR part 60, appendix A), Sampling and Velocity Traverses
for Stationary Sources. Also, when selecting the measurement location,
consider whether stratification of the tracer gas is likely at the
location (e.g., do not select a location immediately after a point of
air in-leakage to the duct).
8.2 Tracer Gas Release. Release the tracer gas at a calculated flow
rate (see section 12.1 for calculation) through a minimum of three
injection manifolds located as described above in 8.1.3. The tracer gas
delivery lines must be routed into the enclosure and attached to the
manifolds without violating the integrity of the enclosure.
8.3 Pretest Measurements.
8.3.1 Location of Sampling Point(s). If stratification is not
suspected at the measurement location, select a single sample point
located at the centroid of the CD inlet duct or at a point no closer to
the CD inlet duct walls than 1 meter. If stratification is suspected,
establish a ``measurement line'' that passes through the centroidal area
and
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in the direction of any expected stratification. Locate three traverse
points at 16.7, 50.0 and 83.3 percent of the measurement line and sample
from each of these three points during each run, or follow the procedure
in section 8.3.2 to verify whether stratification does or does not
exist.
8.3.2 Stratification Verification. The presence or absence of
stratification can be verified by using the following procedure. While
the facility is operating normally, initiate tracer gas release into the
enclosure. For rectangular ducts, locate at least nine sample points in
the cross section such that the sample points are the centroids of
similarly-shaped, equal area divisions of the cross section. Measure the
tracer gas concentration at each point. Calculate the mean value for all
sample points. For circular ducts, conduct a 12-point traverse (i.e.,
six points on each of the two perpendicular diameters) locating the
sample points as described in 40 CFR part 60, appendix A, Method 1.
Perform the measurements and calculations as described above. Determine
if the mean pollutant concentration is more than 10 percent different
from any single point. If so, the cross section is considered to be
stratified, and the tester may not use a single sample point location,
but must use the three traverse points at 16.7, 50.0, and 83.3 percent
of the entire measurement line. Other traverse points may be selected,
provided that they can be shown to the satisfaction of the Administrator
to provide a representative sample over the stack or duct cross section.
8.4 CD Inlet Gas Flow Rate Measurements. The procedures of EPA
Methods 1-4 (40 CFR part 60, appendix A) are used to determine the CD
inlet gas flow rate. Molecular weight (Method 3) and moisture (Method 4)
determinations are only required once for each test series. However, if
the test series is not completed within 24 hours, then the molecular
weight and moisture measurements should be repeated daily. As a minimum,
velocity measurements are conducted according to the procedures of
Methods 1 and 2 before and after each test run, as close to the start
and end of the run as practicable. A velocity measurement between two
runs satisfies both the criterion of ``after'' the run just completed
and ``before'' the run to be initiated. Accurate exhaust gas flow rate
measurements are critical to the success of this procedure. If
significant temporal variations of flow rate are anticipated during the
test run under normal process operating conditions, take appropriate
steps to accurately measure the flow rate during the test. Examples of
steps that might be taken include: (1) conducting additional velocity
traverses during the test run; or (2) continuously monitoring a single
point of average velocity during the run and using these data, in
conjunction with the pre- and post-test traverses, to calculate an
average velocity for the test run.
8.5 Tracer Gas Measurement Procedure.
8.5.1 Calibration Error Test. Immediately prior to the emission test
(within 2 hours of the start of the test), introduce zero gas and high-
level calibration gas at the calibration valve assembly. Zero and
calibrate the analyzer according to the manufacturer's procedures using,
respectively, nitrogen and the calibration gases. Calculate the
predicted response for the low-level and mid-level gases based on a
linear response line between the zero and high-level response. Then
introduce the low-level and mid-level calibration gases successively to
the measurement system. Record the analyzer responses for the low-level
and mid-level calibration gases and determine the differences between
the measurement system responses and the predicted responses using the
equation in section 12.3. These differences must be less than 5 percent
of the respective calibration gas value. If not, the measurement system
must be replaced or repaired prior to testing. No adjustments to the
measurement system shall be conducted after the calibration and before
the drift determination (section 8.5.4). If adjustments are necessary
before the completion of the test series, perform the drift checks prior
to the required adjustments and repeat the calibration following the
adjustments. If multiple electronic ranges are to be used, each
additional range must be checked with a mid-level calibration gas to
verify the multiplication factor.
Note: If using an FTIR for the analytical instrument, you may choose
to follow the pretest preparation, evaluation, and calibration
procedures of Method 320 (section 8.0) (40 CFR part 63, appendix A) in
lieu of the above procedure.
8.5.2 Response Time Test. Conduct this test once prior to each test
series. Introduce zero gas into the measurement system at the
calibration valve assembly. When the system output has stabilized,
switch quickly to the high-level calibration gas. Record the time from
the concentration change to the measurement system response equivalent
to 95 percent of the step change. Repeat the test three times and
average the results.
8.5.3 SF6 Measurement. Sampling of the enclosure exhaust
gas at the inlet to the CD should begin at the onset of tracer gas
release. If necessary, adjust the tracer gas injection rate such that
the measured tracer gas concentration at the CD inlet is within the
spectrometer's calibration range (i.e., between the MML and the span
value). Once the tracer gas concentration reaches equilibrium, the
SF6 concentration should be measured using the infrared
spectrometer continuously for at least 20 minutes per run. Continuously
record (i.e., record at least once per minute) the concentration.
Conduct at least three test runs. On the recording
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chart, in the data acquisition system, or in a log book, make a note of
periods of process interruption or cyclic operation such as the cycles
of the hot press operation. Table 1 to this appendix summarizes the
physical measurements required for the enclosure testing.
Note: If a GC/ECD is used as the analytical instrument, a continuous
record (at least once per minute) likely will not be possible; make a
minimum of five injections during each test run. Also, the minimum test
run duration criterion of 20 minutes applies.
8.5.4 Drift Determination. Immediately following the completion of
the test run, reintroduce the zero and mid-level calibration gases, one
at a time, to the measurement system at the calibration valve assembly.
(Make no adjustments to the measurement system until both the zero and
calibration drift checks are made.) Record the analyzer responses for
the zero and mid-level calibration gases and determine the difference
between the instrument responses for each gas prior to and after the
emission test run using the equation in section 12.4. If the drift
values exceed the specified limits (section 13), invalidate the test
results preceding the check and repeat the test following corrections to
the measurement system. Alternatively, recalibrate the test measurement
system as in section 8.5.1 and report the results using both sets of
calibration data (i.e., data determined prior to the test period and
data determined following the test period). Note: If using an FTIR for
the analytical instrument, you may choose to follow the post-test
calibration procedures of Method 320 in appendix A to 40 CFR part 63
(section 8.11.2) in lieu of the above procedures.
8.6 Ambient Air Sampling (Optional). Sampling the ambient air
surrounding the enclosure is optional. However, taking these samples
during the capture efficiency testing will identify those areas of the
enclosure that may be performing less efficiently.
8.6.1 Location of Ambient Samples Outside the Enclosure (Optional).
In selecting the sampling locations for collecting samples of the
ambient air surrounding the enclosure, consider potential leak points,
the direction of the release, and laminar flow characteristics in the
area surrounding the enclosure. Samples should be collected from all
sides of the enclosure, downstream in the prevailing room air flow, and
in the operating personnel occupancy areas.
8.6.2 Collection of Ambient Samples (Optional). During the tracer
gas release, collect ambient samples from the area surrounding the
enclosure perimeter at predetermined location using disposable syringes
or some other type of containers that are non-absorbent, inert, and that
have low permeability (i.e., polyvinyl fluoride film or polyester film
sample bags or polyethylene, polypropylene, nylon or glass bottles). The
use of disposable syringes allows samples to be injected directly into a
gas chromatograph. Concentration measurements taken around the perimeter
of the enclosure provide evidence of capture performance and will assist
in the identification of those areas of the enclosure that are
performing less efficiently.
8.6.3 Analysis and Storage of Ambient Samples (Optional). Analyze
the ambient samples using an analytical instrument calibrated and
operated according to the procedures in this appendix or ASTM E 260 and
ASTM E 697. Samples may be analyzed immediately after a sample is taken,
or they may be stored for future analysis. Experience has shown no
degradation of concentration in polypropylene syringes when stored for
several months as long as the needle or syringe is plugged.
Polypropylene syringes should be discarded after one use to eliminate
the possibility of cross contamination of samples.
9.0 Quality Control
9.1 Sampling, System Leak Check. A sampling system leak check should
be conducted prior to and after each test run to ensure the integrity of
the sampling system.
9.2 Zero and Calibration Drift Tests.
------------------------------------------------------------------------
Section Quality control measure Effect
------------------------------------------------------------------------
8.5.4.................. Zero and calibration Ensures that bias
drift tests. introduced by drift
in the measurement
system output during
the run is no greater
than 3 percent of
span.
------------------------------------------------------------------------
10.0 Calibration and Standardization
10.1 Control Device Inlet Air Flow Rate Measurement Equipment.
Follow the equipment calibration requirements specified in Methods 2, 3,
and 4 (appendix A to 40 CFR part 60) for measuring the velocity,
molecular weight, and moisture of the control device inlet air.
10.2 Tracer Gas Injection Rate. A dry gas volume flow meter, mass
flow meter, or orifice can be used to measure the tracer gas injection
flow rate. The selected flow measurement device must have an accuracy of
greater than 5 percent at the field operating
range. Prior to the test, verify the calibration of the selected flow
measurement device using either a wet test meter, spirometer, or liquid
displacement meter as the calibration device. Select a minimum of two
flow rates to bracket the expected field operating range of the flow
meter. Conduct three calibration
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runs at each of the two selected flow rates. For each run, note the
exact quantity of gas as determined by the calibration standard and the
gas volume indicated by the flow meter. For each flow rate, calculate
the average percent difference of the indicated flow compared to the
calibration standard.
10.3 Spectrometer. Follow the calibration requirements specified by
the equipment manufacturer for infrared spectrometer measurements and
conduct the pretest calibration error test specified in section 8.5.1.
Note: if using an FTIR analytical instrument see Method 320, section 10
(appendix A to 40 CFR part 63).
10.4 Gas Chromatograph. Follow the pre-test calibration requirements
specified in section 8.5.1.
10.5 Gas Chromatograph for Ambient Sampling (Optional). For the
optional ambient sampling, follow the calibration requirements specified
in section 8.5.1 or ASTM E 260 and E 697 and by the equipment
manufacturer for gas chromatograph measurements.
11.0 Analytical Procedures
The sample collection and analysis are concurrent for this method
(see section 8.0).
12.0 Calculations and Data Analysis
12.1 Estimate MML and Span. The MML is the minimum measurement
level. The selection of this level is at the discretion of the tester.
However, the MML must be higher than the low-level calibration standard,
and the tester must be able to measure at this level with a precision of
<=10 percent. As an example, select the MML as 10 times the instrument's
published detection limit. The detection limit of one instrument is 0.01
parts per million by volume (ppmv). Therefore, the MML would be 0.10
ppmv. Select the low-level calibration standard as 0.08 ppmv. The high-
level standard would be four times the low-level standard or 0.32 ppmv.
A reasonable mid-level standard would then be 0.20 ppmv (halfway between
the low-level standard and the high-level standard). Finally, the span
value would be approximately 0.40 ppmv (the high-level value is 80
percent of the span). In this example, the following MML, calibration
standards, and span values would apply:
MML = 0.10 ppmv
Low-level standard = 0.08 ppmv
Mid-level standard = 0.20 ppmv
High-level standard = 0.32 ppmv
Span value = 0.40 ppmv
12.2 Estimate Tracer Gas Injection Rate for the Given Span. To
estimate the minimum and maximum tracer gas injection rate, assume a
worst case capture efficiency of 80 percent, and calculate the tracer
gas flow rate based on known or measured parameters. To estimate the
minimum tracer gas injection rate, assume that the MML concentration (10
times the IR detection limit in this example) is desired at the
measurement location. The following equation can be used to estimate the
minimum tracer gas injection rate:
((QT-MIN x 0.8)/QE) x (CT / 100) x
10\6\ = MML
QT-MIN = 1.25 x MML x (QE/CT) x
10-4
Where:
QT-MIN = minimum volumetric flow rate of tracer gas injected,
standard cubic feet per minute (scfm);
QE = volumetric flow rate of exhaust gas, scfm;
CT = Tracer gas (SF6) concentration in gas blend,
percent by volume;
MML = minimum measured level, ppmv = 10 x IRDL (for this
example);
IRDL = IR detection limit, ppmv.
Standard conditions: 20 [deg]C, 760 millimeters of mercury (mm Hg).
To estimate the maximum tracer gas injection rate, assume that the
span value is desired at the measurement location. The following
equation can be used to estimate the maximum tracer gas injection rate:
((QT-MAX x 0.8)/QE) x (CT / 100) x
10\6\ = span value
QT-MAX = 1.25 x span value x (QE/CT) x
10-4
Where:
QT-MAX = maximum volumetric flow rate of tracer gas injected,
scfm;
Span value = instrument span value, ppmv.
The following example illustrates this calculation procedure:
Find the range of volumetric flow rate of tracer gas to be injected
when the following parameters are known:
QE = 60,000 scfm (typical exhaust gas flow rate from an
enclosure);
CT = 2 percent SF6 in nitrogen;
IRDL = 0.01 ppmv (per manufacturer's specifications);
MML = 10 x IRDL = 0.10 ppmv;
Span value = 0.40 ppmv;
QT = ?
Minimum tracer gas volumetric flow rate:
QT-MIN = 1.25 x MML x (QE/CT) x
10-4
QT-MIN = 1.25 x 0.10 x (60,000/2) x 10-4 = 0.375
scfm
Maximum tracer gas volumetric flow rate:
QT-MAX = 1.25 x span value x (QE/CT) x
10-4
QT-MAX = 1.25 x 0.40 x (60,000/2) x 10-4 = 1.5
scfm
In this example, the estimated total volumetric flow rate of the two
percent SF6 tracer gas injected through the manifolds in the
enclosure lies between 0.375 and 1.5 scfm.
12.3 Calibration Error. Calculate the calibration error for the low-
level and mid-level calibration gases using the following equation:
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Err = verbar;Cstd-Cmeasverbar; /
Cstd x 100
Where:
Err = calibration error, percent;
Cstd = low-level or mid-level calibration gas value, ppmv;
Cmeas = measured response to low-level or mid-level
concentration gas, ppmv.
12.4 Calibration Drift. Calculate the calibration drift for the zero
and low-level calibration gases using the following equation:
D = [bond]verbar;Cinitial - Cfinal [bond]verbar; /
Cspan x 100
Where:
D = calibration drift, percent;
Cinitial = low-level or mid-level calibration gas value
measured before test run, ppmv;
Cfinal = low-level or mid-level calibration gas value
measured after test run, ppmv;
Cspan = span value, ppmv.
12.5 Calculate Capture Efficiency. The equation to calculate
enclosure capture efficiency is provided below:
CE = (SF6-CD / SF6-INJ) x 100
Where:
CE = capture efficiency;
SF6-CD = mass of SF6 measured at the inlet to the
CD;
SF6-INJ= mass of SF6 injected from the tracer
source into the enclosure.
Calculate the CE for each of the initial three test runs. Then follow
the procedures outlined in section 12.6 to calculate the overall capture
efficiency.
12.6 Calculate Overall Capture Efficiency. After calculating the
capture efficiency for each of the initial three test runs, follow the
procedures in 40 CFR part 63, subpart KK, appendix A, to determine if
the results of the testing can be used in determining compliance with
the requirements of the rule. There are two methods that can be used:
the DQO and LCL methods. The DQO method is described in section 3 of 40
CFR part 63, subpart KK, appendix A, and provides a measure of the
precision of the capture efficiency testing conducted. Section 3 of 40
CFR part 63, subpart KK, appendix A, provides an example calculation
using results from a facility. If the DQO criteria are met using the
first set of three test runs, then the facility can use the average
capture efficiency of these test results to determine the capture
efficiency of the enclosure. If the DQO criteria are not met, then the
facility can conduct another set of three runs and run the DQO analysis
again using the results from the six runs OR the facility can elect to
use the LCL approach.
The LCL method is described in section 4 of 40 CFR part 63, subpart
KK, appendix A, and provides sources that may be performing much better
than their regulatory requirement, a screening option by which they can
demonstrate compliance. The LCL approach compares the 80 percent lower
confidence limit for the mean measured CE value to the applicable
regulatory requirement. If the LCL capture efficiency is higher than the
applicable limit, then the facility is in initial compliance and would
use the LCL capture efficiency as the capture efficiency to determine
compliance. If the LCL capture efficiency is lower than the applicable
limit, then the facility must perform additional test runs and re-run
the DQO or LCL analysis.
13.0 Method Performance
13.1 Measurement System Performance Specifications.
13.1.1 Zero Drift. Less than 3 percent of the
span value.
13.1.2 Calibration Drift. Less than 3 percent
of the span value.
13.1.3 Calibration Error. Less than 5 percent
of the calibration gas value.
13.2 Flow Measurement Specifications. The mass flow, volumetric
flow, or critical orifice control meter used should have an accuracy of
greater than 5 percent at the flow rate used.
13.3 Calibration and Tracer Gas Specifications. The manufacturer of
the calibration and tracer gases should provide a recommended shelf life
for each calibration gas cylinder over which the concentration does not
change more than 2 percent from the certified
value.
14.0 Pollution Prevention [Reserved]
15.0 Waste Management [Reserved]
16.0 References
1. 40 CFR part 60, appendix A, EPA Method 1--Sample and velocity
traverses for stationary sources.
2. 40 CFR part 60, appendix A, EPA Method 2--Determination of stack
gas velocity and volumetric flow rate.
3. 40 CFR part 60, appendix A, EPA Method 3--Gas analysis for the
determination of dry molecular weight.
4. 40 CFR part 60, appendix A, EPA Method 4--Determination of
moisture content in stack gases.
5. SEMI F15-93 Test Method for Enclosures Using Sulfur Hexafluoride
Tracer Gas and Gas Chromotography.
6. Memorandum from John S. Seitz, Director, Office of Air Quality
Planning and Standards, to EPA Regional Directors, Revised Capture
Efficiency Guidance for Control of Volatile Organic Compound Emissions,
February 7, 1995. (That memorandum contains an attached technical
document from Candace Sorrell, Emission Monitoring and Analysis
Division, ``Guidelines for Determining Capture Efficiency,'' January 9,
1994).
7. Technical Systems Audit of Testing at Plant ``C,'' EPA-454/R-00-
26, May 2000.
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8. Material Safety Data Sheet for SF6 Air Products and
Chemicals, Inc. Website: www3.airproducts.com. October 2001.
17.0 Tables, Diagrams, Flowcharts, and Validation Data
Table 1 to Appendix A to Subpart DDDD of 40 CFR Part 63--Summary of Critical Physical Measurements for Enclosure
Testing
----------------------------------------------------------------------------------------------------------------
Measurement
Measurement instrumentation Measurement frequency Measurement site
----------------------------------------------------------------------------------------------------------------
Tracer gas injection rate............ Mass flow meter, Continuous............. Injection manifolds
volumetric flow meter (cylinder gas).
or critical orifice.
Tracer gas concentration at control Infrared Spectrometer Continuous (at least Inlet duct to the
device inlet. or GC/ECD. one reading per control device (outlet
minute) for a minimum duct of enclosure).
of 20 minutes.
Volumetric air flow rate............. EPA Methods 1, 2, 3, 4 Each test run for Inlet duct to the
(40 CFR part 60, velocity (minimum); control device (outlet
appendix A). Daily for moisture and duct of enclosure).
molecular weight.
Velocity sensor
(Manometer/Pitot tube).
Thermocouple.
Midget Impinger
sampler
Orsat or Fyrite
----------------------------------------------------------------------------------------------------------------
[[Page 262]]
[GRAPHIC] [TIFF OMITTED] TR72AD04.008
[[Page 263]]
[GRAPHIC] [TIFF OMITTED] TR72AD04.009
[69 FR 46011, July 30, 2004, as amended at 71 FR 8375, Feb. 16, 2006]
Appendix B to Subpart DDDD of Part 63--Methodology and Criteria for
Demonstrating That an Affected Source Is Part of the Low-Risk
Subcategory of Plywood and Composite Wood Products Manufacturing
Affected Sources
1. Purpose
This appendix provides the methodology and criteria for
demonstrating that your affected source is part of the low-risk
subcategory of plywood and composite wood products (PCWP) manufacturing
facilities. You must demonstrate that your affected source is part of
the low-risk subcategory using either a look-up table analysis (based on
the look-up tables included in this appendix) or using a site-specific
risk assessment performed according to the criteria specified in this
appendix. This appendix also specifies how and when you must obtain
approval of the low-risk demonstrations for your affected source and how
to ensure that your affected source remains in the low-risk subcategory
of PCWP facilities.
2. Who is eligible to demonstrate that they are part of the low-risk
subcategory of PCWP affected sources?
Each new, reconstructed, or existing affected source at a PCWP
manufacturing facility may demonstrate that they are part of the low-
risk subcategory of PCWP affected sources. Section 63.2232 of 40 CFR
part 63, subpart DDDD, defines the affected source and explains which
affected sources are new, existing, or reconstructed.
3. What parts of my affected source have to be included in the low-risk
demonstration?
Every process unit that is part of the PCWP affected source (as
defined in Sec. 63.2292 of 40 CFR part 63, subpart DDDD) and that emits
one or more hazardous air pollutant (HAP) listed in table 1 to this
appendix must be included in the low-risk demonstration. You are not
required to include process units outside of the affected source in the
low-risk demonstration.
4. What are the criteria for determining if my affected source is low
risk?
(a) Determine the individual HAP emission rates from each process
unit emission point within the affected source using the procedures
specified in section 5 of this appendix.
(b) Perform chronic and acute risk assessments using the dose-
response values, as specified in paragraphs (b)(1) through (3) of this
section.
(1) For a look-up table analysis or site-specific chronic inhalation
risk assessment, you should use the cancer and noncancer dose-response
values listed on the Environmental Protection Agency (EPA) Air Toxics
Web site (http://www.epa.gov/ttn/atw/toxsource/summary.html) to estimate
carcinogenic and noncarcinogenic chronic inhalation risk, respectively.
(2) For site-specific acute inhalation risk assessment, you should
use the acute exposure guidance level (AEGL-1) value for acrolein and
the acute reference exposure level
[[Page 264]]
(REL) value for formaldehyde for estimating acute inhalation risk found
at http://www.epa.gov/ttn/atw/toxsource/summary.html.
(3) You may use dose-response values more health-protective than
those posted on the EPA Air Toxics Web site (http://www.epa.gov/ttn/atw/
toxsource/summary.html) to facilitate ongoing certification (as required
in section 13 of this appendix) that your affected source remains in the
low-risk subcategory.
(c) Demonstrate that your affected source is part of the low-risk
subcategory by estimating the maximum impacts of your affected source
using the methods described in either section 6 of this appendix (look-
up table analysis) or section 7 of this appendix (site-specific risk
assessment) and comparing the results to the low-risk criteria presented
in the applicable section.
5. How do I determine HAP emissions from my affected source?
(a) You must determine HAP emissions for every process unit emission
point within the affected source that emits one or more of the HAP
listed in table 1 to this appendix as specified in table 2A to this
appendix. For each process unit type, table 2A to this appendix
specifies whether emissions testing is required or if emissions
estimation is allowed as an alternative to emissions testing. If
emissions estimation is allowed according to table 2A, you must develop
your emission estimates according to the requirements in paragraph (k)
of this section. You may choose to perform emissions testing instead of
emissions estimation. You must conduct HAP emissions tests according to
the requirements in paragraphs (b) through (j) of this section and the
methods specified in table 2B to this appendix. If you conduct fuel
analyses, you must follow the requirements of paragraph (m) of this
section. For each of the emission points at your affected source, you
must obtain the emission rates in pounds per hour (lb/hr) for each of
the pollutants listed in table 1 to this appendix.
(b) Periods when emissions tests must be conducted.
(1) You must not conduct emissions tests during periods of startup,
shutdown, or malfunction, as specified in 40 CFR 63.7(e)(1).
(2) You must test under worst-case operating conditions as defined
in this appendix. You must describe your worst-case operating conditions
in your performance test report for the process and control systems (if
applicable) and explain why the conditions are worst-case.
(c) Number of test runs. You must conduct three separate test runs
for each test required in this section, as specified in 40 CFR
63.7(e)(3). Each test run must last at least 1 hour except for: testing
of a temporary total enclosure (TTE) conducted using Methods 204A
through 204F in 40 CFR part 51, appendix M, which require three separate
test runs of at least 3 hours each; and testing of an enclosure
conducted using the alternative tracer gas method in appendix A to 40
CFR part 63, subpart DDDD, which requires a minimum of three separate
runs of at least 20 minutes each.
(d) Sampling locations. Sampling sites must be located at the
emission point and prior to any releases to the atmosphere. For example,
at the outlet of the control device, including wet control devices, and
prior to any releases to the atmosphere.
(e) Collection of monitoring data for HAP control devices. During
the emissions test, you must collect operating parameter monitoring
system or continuous emissions monitoring system (CEMS) data at least
every 15 minutes during the entire emissions test and establish the
site-specific operating requirements (including the parameter limits or
total hydrocarbon (THC) concentration limit) in table 2 to 40 CFR part
63, subpart DDDD, using data from the monitoring system and the
procedures specified in paragraphs (k) through (o) of Sec. 63.2262 of
subpart DDDD of 40 CFR part 63.
(f) Nondetect data. You may treat emissions of an individual HAP as
zero if all of the test runs result in a nondetect measurement and the
conditions in paragraphs (1) and (2) of this section are met for the
relevant test method. Otherwise, nondetect data (as defined in Sec.
63.2292 of 40 CFR part 63, subpart DDDD) for individual HAP must be
treated as one-half of the method detection limit.
(1) The method detection limit is less than or equal to 1 part per
million by volume, dry (ppmvd) for pollutant emissions measured using
Method 320 in appendix A to 40 CFR part 63; or Method 18 in appendix A
to 40 CFR part 60; or the NCASI Method IM/CAN/WP-99.02 (incorporated by
reference (IBR), see 40 CFR 63.14(f)); or NCASI Method ISS/FP-A105.01
(IBR, see 40 CFR 63.14(f); or ASTM D6348-03 (IBR, see 40 CFR 63.14(b)).
(2) For pollutants measured using Method 29 in appendix A to 40 CFR
part 60, you analyze samples using atomic absorption spectroscopy (AAS)
or another laboratory method specified in Method 29 in appendix A to 40
CFR part 60 with detection limits lower than or equal to AAS.
(g) For purposes of your low-risk demonstration, you must assume
that 17 percent of your total chromium measured using EPA Method 29 in
appendix A to 40 CFR part 60 is chromium VI. You must assume that 65
percent of your total nickel measured using EPA Method 29 in appendix A
to 40 CFR part 60 is nickel subsulfide.
(h) You may use emission rates higher than your measured emission
rates (e.g., emissions rates 10 times your measured emission rate) to
facilitate ongoing certification (as required in section 13 of this
appendix) that your affected source remains in the low-risk subcategory.
[[Page 265]]
(i) Use of previous emissions tests. You may use the results of
previous emissions tests provided that the following conditions are met:
(1) The previous emissions tests must have been conducted using the
methods specified in table 2B to this appendix. Previous emission test
results obtained using NCASI Method IM/CAN/WP-99.01 are acceptable.
(2) The previous emissions tests must meet the requirements in
paragraphs (b) through (j) of this section.
(3) The subject process unit(s) must be operated in a manner (e.g.,
with raw material type, operating temperature, etc.) that would be
expected to result in the same or lower emissions than observed during
the previous emissions test(s) and the process unit(s) may not have been
modified such that emissions would be expected to exceed
(notwithstanding normal test-to-test variability) the results from
previous emissions test(s).
(4) The previous emissions test(s) must have been conducted in 1997
or later.
(j) Use of test data for similar process units. If you have multiple
similar process units at the same plant site, you may apply the test
results from one of these process units to the other similar process
units for purposes of your low-risk demonstration provided that the
following conditions are met:
(1) You must explain how the process units are similar in terms of
design, function, heating method, raw materials processed, residence
time, change in material moisture content, operating temperature, resin
type processed, age, and any other parameters that may affect emissions.
(2) If the process units have different throughput rates, then you
must convert the emission test results to terms of pounds of HAP per
unit throughput prior to applying the emissions test data to other
similar process units.
(3) If one of the process units would be expected to exhibit higher
emissions due to minor differences in process parameters, then you must
explain and test the process unit that would be expected to exhibit
greater emissions (for example, the unit with a slightly higher
temperature set point, dryer processing furnish with slightly higher
inlet moisture content, press processing thicker panels, unit with the
greater throughput, considerably older unit, etc.).
(k) If emissions estimation is allowed, you must follow the
procedures in (1) through (3) of this paragraph.
(1) You must use the emission factors or other emission estimation
techniques specified in table 2A to this appendix when developing
emission estimates.
(2) You must base your emission estimates on the maximum process
unit throughput you will incorporate into your permit according to
section 11(b) of this appendix.
(3) For process units with multiple emission points, you must
apportion the estimate emissions evenly across each emission point. For
example, if you have a process unit with two emission points, and the
process unit is estimated to emit 6 lb/hr, you would assign 3 lb/hr to
each emission point.
(l) Testing of multiple stacks. You may test one of multiple stacks
for a process unit provided that the following conditions are met:
(1) The emissions are produced by the same process unit.
(2) The emissions originate from the same duct.
(3) The emissions are sufficiently mixed so that the gaseous
pollutant concentrations from one stack are not expected to differ from
concentrations from another stack.
(m) Conducting a fuel analysis. For process units that require
testing of metals according to table 2A to this appendix, you may
conduct a fuel analysis in lieu of emissions tests. You must follow the
procedures described in Sec. 63.7521 (a) and (c) through (e) of subpart
DDDDD; Sec. 63.7530(d)(1), (2), and (4) of subpart DDDDD, and line 2 of
table 6 to subpart DDDDD. For purposes of this appendix, the total
selected metals analyzed by fuel analysis are the metals included in
table 1 to this appendix.
6. How do I conduct a look-up table analysis?
Use the look-up tables (tables 3 and 4 to this appendix) to
demonstrate that your affected source is part of the low-risk
subcategory, following the procedures in paragraphs (a) through (d) of
this section.
(a) Using the emission rate of each HAP required to be included in
your low-risk demonstration (determined according to section 5 of this
appendix), calculate your total toxicity-weighted carcinogen and
noncarcinogen emission rates for each of your emission points using
Equations 1 and 2 of this appendix, respectively. Calculate your
carcinogen and non-carcinogen weighted stack height using Equations 3
and 4 of this appendix, respectively.
[GRAPHIC] [TIFF OMITTED] TR16FE06.000
TWCER = Toxicity-weighted carcinogenic emission rate for each emission
point (lb/hr)/([mu]g/m\3\)
ERi = Emission rate of pollutant i (lb/hr)
UREi = Unit risk estimate for pollutant i, 1 per microgram
per cubic meter ([mu]g/m\3\)-1
[GRAPHIC] [TIFF OMITTED] TR16FE06.001
TWNER = Toxicity-weighted noncarcinogenic emission rate for each
emission point (lb/hr)/([mu]g/m\3\)
ERi = Emission rate of pollutant i (lb/hr)
[[Page 266]]
RfCi = Reference concentration for pollutant i, micrograms
per cubic meter ([mu]g/m\3\)
[GRAPHIC] [TIFF OMITTED] TR16FE06.002
WHC = Carcinogen weighted stack height for use in the carcinogen look-up
table (table 3 to this appendix)
H = Height of each individual stack or emission point (m)
ep = Individual stacks or emission points
n = Total number of stacks and emission points
[GRAPHIC] [TIFF OMITTED] TR16FE06.003
WHN = Non-carcinogen weighted stack height for use in the non-carcinogen
look-up table (table 4 to this appendix)
H = Height of each individual stack or emission point (m)
ep = Individual stacks or emission points
n = Total number of stacks and emission points
(b) Cancer risk. Calculate the total toxicity-weighted carcinogen
emission rate for your affected source by summing the toxicity-weighted
carcinogen emission rates for each of your emission points. Identify the
appropriate maximum allowable toxicity-weighted carcinogen emission rate
from table 3 to this appendix for your affected source using the
carcinogen weighted stack height of your emission points and the minimum
distance between any emission point at the affected source and the
property boundary. If one or both of these values do not match the exact
values in the look-up table, then use the next lowest table value.
(Note: If your weighted stack height is less than 5 meters (m), you must
use the 5 m row.) Your affected source is considered low risk for
carcinogenic effects if your toxicity-weighted carcinogen emission rate,
determined using the methods specified in this appendix, does not exceed
the values specified in table 3 to this appendix.
(c) Noncancer risk. Calculate the total central nervous system (CNS)
and respiratory target organ specific toxicity-weighted noncarcinogen
emission rate for your affected source by summing the toxicity-weighted
emission rates for each of your emission points. Identify the
appropriate maximum allowable toxicity-weighted noncarcinogen emission
rate from table 4 to this appendix for your affected source using the
non-carcinogen weighted stack height of your emission points and the
minimum distance between any emission point at the affected source and
the property boundary. If one or both of these values do not match the
exact values in the look-up table, then use the next lowest table value.
(Note: If your weighted stack height is less than 5 m, you must use the
5 m row.) Your affected source is considered low risk for
noncarcinogenic effects if your toxicity-weighted noncarcinogen emission
rate, determined using the methods specified in this appendix, does not
exceed the values specified in table 4 to this appendix.
(d) Low-risk demonstration. The EPA will approve your affected
source as eligible for membership in the low-risk subcategory of PCWP
affected sources if it determines that: (1) Your affected source is low
risk for both carcinogenic and noncarcinogenic effects using the look-up
table analysis described in this section and (2) you meet the criteria
specified in section 11 of this appendix.
7. How do I conduct a site-specific risk assessment?
(a) Perform a site-specific risk assessment following the procedures
specified in this section. You may use any scientifically-accepted peer-
reviewed assessment methodology for your site-specific risk assessment.
An example of one approach to performing a site-specific risk assessment
for air toxics that may be appropriate for your affected source can be
found in the ``Air Toxics Risk Assessment Guidance Reference Library,
Volume 2, Site-Specific Risk Assessment Technical Resource Document.''
You may obtain a copy of the ``Air Toxics Risk Assessment Reference
Library'' through EPA's air toxics Web site at http://www.epa.gov/ttn/
fera/risk--atra--main.html.
(b) At a minimum, your site-specific risk assessment must:
(1) Estimate the long-term inhalation exposures through the
estimation of annual or multi-year average ambient concentrations for
the chronic portion of the assessment.
[[Page 267]]
(2) Estimate the acute exposures for formaldehyde and acrolein
through the estimation of maximum 1-hour average ambient concentrations
for the acute portion of the assessment.
(3) Estimate the inhalation exposure of the individual most exposed
to the affected source's emissions.
(4) Estimate the individual risks over a 70-year lifetime for the
chronic cancer risk assessment.
(5) Use site-specific, quality-assured data wherever possible.
(6) Use health-protective default assumptions wherever site-specific
data are not available.
(7) Contain adequate documentation of the data and methods used for
the assessment so that it is transparent and can be reproduced by an
experienced risk assessor and emission measurement expert.
(c) Your site-specific risk assessment need not:
(1) Assume any attenuation of exposure concentrations due to the
penetration of outdoor pollutants into indoor exposure areas.
(2) Assume any reaction or deposition of the emitted pollutants
during transport from the emission point to the point of exposure.
(d) Your affected source is considered low risk for carcinogenic
chronic inhalation effects if your site-specific risk assessment
demonstrates that maximum off-site individual lifetime cancer risk at a
location where people live or congregate (e.g., school or day care
center) is less than 1 in 1 million.
(e) Your affected source is considered low risk for noncarcinogenic
chronic inhalation effects if your site-specific risk assessment
demonstrates that every maximum off-site target-organ specific hazard
index (TOSHI), or appropriate set of site-specific hazard indices based
on similar or complementary mechanisms of action that are reasonably
likely to be additive at low dose or dose-response data for mixtures, at
a location where people live is less than or equal to 1.0.
(f) Your affected source is considered low risk for noncarcinogenic
acute inhalation effects if your site-specific risk assessment
demonstrates that the maximum off-site acute hazard quotients for both
acrolein and formaldehyde are less than or equal to 1.0.
(g) The EPA will approve your affected source as eligible for
membership in the low-risk subcategory of PCWP affected sources if it
determines that: (1) your affected source is low risk for all of the
applicable effects listed in paragraphs (d) through (f) of this section
and (2) you meet the criteria specified in section 11 of this appendix.
8. What information must I submit for the low-risk demonstration?
(a) Your low-risk demonstration must include at a minimum the
information specified in paragraphs (a)(1) through (5) of this section
and the information specified in either paragraph (b) or (c) of this
section.
(1) Identification of each process unit at the affected source.
(2) Stack parameters for each emission point including, but not
limited to, the parameters listed in paragraphs (a)(2)(i) through (iv)
below:
(i) Emission release type.
(ii) Stack height, stack area, stack gas temperature, and stack gas
exit velocity.
(iii) Plot plan showing all emission points, nearby residences, and
fenceline.
(iv) Identification of any HAP control devices used to reduce
emissions from each process unit.
(3) Emission test reports for each pollutant and process unit based
on the testing requirements and methods specified in tables 2A and 2B to
this appendix, including a description of the process parameters
identified as being worst case. You must submit your emissions
calculations for each pollutant and process unit for which emissions
estimates are developed. You must submit fuel analyses for each fuel and
emission point which has been conducted, including collection and
analytical methods used.
(4) Identification of the dose-response values used in your risk
analysis (look-up table analysis or site-specific risk assessment),
according to section 4(b) of this appendix.
(5) Identification of the controlling process factors (including,
but not limited to, production rate, emission rate, type of control
devices, process parameters documented as worst-case conditions during
the emissions testing used for your low-risk demonstration) that will
become Federally enforceable permit conditions used to show that your
affected source remains in the low-risk subcategory.
(b) If you use the look-up table analysis in section 6 of this
appendix to demonstrate that your affected source is low risk, your low-
risk demonstration must contain at a minimum the information in
paragraphs (a) and (b)(1) through (4) of this section.
(1) Identification of the stack heights for each emission point
included in the calculations of weighted stack height.
(2) Identification of the emission point with the minimum distance
to the property boundary.
(3) Calculations used to determine the toxicity-weighted carcinogen
and noncarcinogen emission rates and weighted stack heights according to
section 6(a) of this appendix.
(4) Comparison of the values in the look-up tables (tables 3 and 4
to this appendix) to your toxicity-weighted emission rates for
carcinogenic and noncarcinogenic HAP.
(c) If you use a site-specific risk assessment as described in
section 7 of this appendix to demonstrate that your affected source
[[Page 268]]
is low risk (for carcinogenic and noncarcinogenic chronic inhalation and
acute inhalation risks), your low-risk demonstration must contain at a
minimum the information in paragraphs (a) and (c)(1) through (8) of this
section.
(1) Identification of the risk assessment methodology used.
(2) Documentation of the fate and transport model used.
(3) Documentation of the fate and transport model inputs, including
the information described in paragraphs (a)(1) through (4) of this
section converted to the dimensions required for the model and all of
the following that apply: meteorological data; building, land use, and
terrain data; receptor locations and population data; and other
facility-specific parameters input into the model.
(4) Documentation of the fate and transport model outputs.
(5) Documentation of exposure assessment and risk characterization
calculations.
(6) Comparison of the maximum off-site individual lifetime cancer
risk at a location where people live to 1 in 1 million, as required in
section 7(d) of this appendix for carcinogenic chronic inhalation risk.
(7) Comparison of the maximum off-site TOSHI for respiratory effects
and CNS effects at a location where people live to the limit of 1.0, as
required in section 7(e) of this appendix for noncarcinogenic chronic
inhalation risk.
(8) Comparison of the maximum off-site acute inhalation hazard
quotient (HQ) for both acrolein and formaldehyde to the limit of 1.0, as
required in section 7(f) of this appendix for noncancinogenic acute
inhalation effects.
(d) The EPA may request any additional information it determines is
necessary or appropriate to evaluate an affected source's low-risk
demonstration.
9. Where do I send my low-risk demonstration?
You must submit your low-risk demonstration to the EPA for review
and approval. Send your low-risk demonstration either by e-mail to
[email protected] or by U.S. mail or other mail delivery service to U.S. EPA,
Risk and Exposure Assessment Group, Emission Standards Division (C404-
01), Attn: Group Leader, Research Triangle Park, NC 27711, and send a
copy to your permitting authority. Your affected source is not part of
the low-risk subcategory of PCWP facilities unless and until EPA
notifies you that it has determined that you meet the requirements of
section 11 of this appendix.
10. When do I submit my low-risk demonstration?
(a) Existing affected sources. If you have an existing affected
source, you may complete and submit for approval your low-risk
demonstration (including the emission test results, fuel analyses, and
emission estimates required in this appendix) any time. Existing
affected sources that are not approved by EPA as being part of the low-
risk subcategory by October 1, 2008, must comply with the requirements
of 40 CFR part 63, subpart DDDD from October 1, 2008, unless and until
EPA approves them as part of the low-risk subcategory.
(b) Sources in compliance with 40 CFR part 63, subpart DDDD. If you
operate an affected source that is already in compliance with 40 CFR
part 63, subpart DDDD (including, but not limited to, an existing
source, a new or reconstructed affected source starting up before
September 28, 2004, or a new source starting up after September 28,
2004, but before February 16, 2006) and wish to become part of the low-
risk subcategory, then you may complete and submit for approval your
low-risk demonstration (including the emission test results, fuel
analyses, and emission estimates required in this appendix) any time.
Your affected source will become part of the low-risk subcategory when
EPA determines that the requirements in section 11 of this appendix are
met.
(c) New or reconstructed affected sources wanting to be part of the
low-risk subcategory at startup must comply with the requirements of
paragraphs (c)(1) through (c)(3) of this section.
(1)(i) You must complete and submit for review and approval a pre-
startup low-risk demonstration no later than nine months prior to
initial startup. The pre-startup low-risk demonstration must be based on
the information (e.g., equipment types, estimated emission rates, etc.)
that you will likely use to obtain your title V permit. You must base
your pre-startup low-risk demonstration on the maximum emissions that
will likely be allowed when you obtain your title V permit.
(ii) You must request that your affected source become part of the
low-risk subcategory based on your pre-startup low-risk demonstration.
(iii) If EPA approves your pre-startup low-risk demonstration, then
your affected source will be part of the low-risk subcategory upon
approval of the pre-startup low-risk demonstration and you may start up
your affected source without complying with the compliance options,
operating requirements, and work practice requirements in 40 CFR part
63, subpart DDDD, provided that you operate your affected source
consistently with the pre-startup low-risk demonstration until you meet
the criteria in section 11 of this appendix based on your verification
low-risk demonstration developed according to paragraph (c)(2) of this
[[Page 269]]
section. Failure to so operate will render approval of your pre-startup
low-risk demonstration null and void from the date you startup your
affected source.
(2)(i) You must complete and submit your verification low-risk
demonstration, including the results from emission tests (or fuel
analyses) required in this appendix, within 240 days following initial
startup. The verification low-risk demonstration must demonstrate to
EPA's satisfaction that the affected source is low risk. The
verification low-risk demonstration may be used to change operating
parameters ensuring low-risk status.
(ii) If you do not submit the verification low-risk demonstration as
required, or the verification low-risk demonstration does not verify
that the affected source is low risk, then approval of your pre-startup
low-risk demonstration is null and void from the date you startup your
affected source and you must comply immediately with subpart DDDD of 40
CFR part 63.
(3) To incorporate the low-risk parameters from your verification
low-risk demonstration into your title V permit, you must submit your
application for a significant modification to your title V permit within
1 year following initial startup, or earlier if so required under your
State's permit program approved under 40 CFR part 70. The parameters
that defined your affected source as part of the low-risk subcategory
(including, but not limited to, production rate, emission rate, type of
control devices, process parameters reflecting the emissions rates used
for your low-risk demonstration, and stack height) must be submitted for
incorporation as federally enforceable terms and conditions into your
title V permit. You must provide written certification to the permitting
authority that your affected source is operating consistently with its
EPA-approved pre-startup low-risk demonstration and verification low-
risk demonstration, as applicable, from startup until your title V
permit revision is issued.
(d) New or reconstructed affected sources that want to operate
consistently with a pre-startup low-risk demonstration at startup and
become part of the low-risk subcategory based on EPA approval of their
verification low-risk demonstration (rather than based on their pre-
startup low-risk demonstration), must comply with the requirements in
paragraphs (d)(1) through (d)(3) of this section.
(1)(i) You must complete and submit for review a pre-startup low-
risk demonstration no later than nine months prior to initial startup.
The pre-startup low-risk demonstration must be based on the information
(e.g., equipment types, estimated emission rates, etc.) that you will
likely use to obtain your title V permit. You must base your pre-startup
low-risk demonstration on the maximum emissions that will likely be
allowed when you obtain your title V permit.
(ii) If EPA concludes that your pre-startup low-risk demonstration
is complete and sufficiently shows that your affected source appears to
be eligible for inclusion in the low-risk subcategory, then you must
operate your affected source consistently with the pre-startup low-risk
demonstration until EPA determines that you meet the criteria in section
11 of this appendix based on your verification low-risk demonstration
developed according to paragraph (d)(2) of this section.
(2)(i) You must complete and submit for EPA review and approval your
verification low-risk demonstration, including the results from emission
tests (or fuel analyses) required in this appendix, within 240 days
following initial startup. The verification low-risk demonstration must
demonstrate to EPA's satisfaction that the affected source is low risk.
(ii) You will become part of the low-risk subcategory when EPA
determines that you meet the criteria in section 11 of this appendix
based upon your verification low-risk demonstration. If you do not
submit the verification low-risk demonstration as required, or the
verification low-risk demonstration does not verify that the affected
source is low risk, then EPA will not approve your low-risk
demonstration and you will remain subject to subpart DDDD of 40 CFR part
63.
(3) To incorporate the low-risk parameters from your verification
low-risk demonstration into your title V permit, you must submit your
application for a significant modification to your title V permit within
1 year following initial startup, or earlier if so required by your
State's permit program approved by EPA under 40 CFR part 70. The
parameters that defined your affected source as part of the low-risk
subcategory (including, but not limited to, production rate, emission
rate, type of control devices, process parameters reflecting the
emissions rates used for your low-risk demonstration, and stack height)
must be submitted for incorporation as federally enforceable terms and
conditions into your title V permit. You must provide written
certification to the permitting authority that your affected source is
operating consistently with its pre-startup LRD and your verification
LRD, as applicable, from startup until your title V permit revision is
issued.
(e) Area sources that become affected sources. If you have an
affected source that is an area source that increases its emissions or
its potential to emit such that it becomes a major source of HAP before
September 28, 2004, then you must complete and submit for approval your
low-risk demonstration as specified in paragraph (a) of this section. If
you have an affected source that is an area
[[Page 270]]
source that increases its emissions or its potential to emit such that
it becomes a major source of HAP after September 28, 2004, then you must
complete and submit for approval your low-risk demonstration as
specified in paragraphs (b), (c) or (d) of this section, whichever
applies.
11. How does my affected source become part of the low-risk subcategory
of PCWP facilities?
For existing sources to be included in the low-risk subcategory, EPA
must find that you meet the criteria in paragraphs (a) and (b) of this
section. For new sources to be included in the low-risk subcategory, EPA
must find that you meet the criteria in paragraph (a) of this section.
Unless and until EPA finds that you meet these criteria, your affected
source is subject to the applicable compliance options, operating
requirements, and work practice requirements in 40 CFR part 63, subpart
DDDD.
(a) Your demonstration of low risk must be approved by EPA.
(b) Following EPA approval, the parameters that defined your
affected source as part of the low-risk subcategory (including, but not
limited to, production rate, emission rate, type of control devices,
process parameters reflecting the emissions rates used for your low-risk
demonstration, and stack height) must be submitted for incorporation as
federally enforceable terms and conditions into your title V permit. You
must submit an application for a significant permit modification to
reopen your title V permit to incorporate such terms and conditions
according to the procedures and schedules of 40 CFR part 71 or the EPA-
approved program in effect under 40 CFR part 70, as applicable.
12. What must I do to ensure my affected source remains in the low-risk
subcategory of PCWP facilities?
You must meet the requirements in table 2 to 40 CFR part 63, subpart
DDDD, for each HAP control device used at the time when you completed
your low-risk demonstration. You must monitor and collect data according
to Sec. 63.2270 of subpart DDDD to show continuous compliance with your
control device operating requirements. You must demonstrate continuous
compliance with the control device operating requirements that apply to
you by collecting and recording the monitoring system data listed in
table 2 to 40 CFR part 63, subpart DDDD for the process unit according
to Sec. Sec. 63.2269(a), (b), and (d) of subpart DDDD; and reducing the
monitoring system data to the specified averages in units of the
applicable requirement according to calculations in Sec. 63.2270 of
subpart DDDD; and maintaining the average operating parameter at or
above the minimum, at or below the maximum, or within the range
(whichever applies) established according to section 5(e) of this
appendix.
13. What happens if the criteria used in the risk determination change?
(a) You must certify with each annual title V permit compliance
certification that the basis for your affected source's low-risk
determination has not changed. You must submit this certification to the
permitting authority. You must consider the changes in paragraphs (a)(1)
through (5) of this section.
(1) Process changes that increase HAP emissions, including, but not
limited to, a production rate increase, an emission rate increase, a
change in type of control device, changes in process parameters
reflecting emissions rates used for your approved low-risk
demonstration.
(2) Population shifts, such as if people move to a different
location such that their risks from the affected source increase.
(3) Unit risk estimate increases posted on the EPA Web site (http://
www.epa.gov/ttn/atw/toxsource/summary.html) for the pollutants included
in table 1 to this appendix.
(4) Reference concentration changes posted on the EPA Web site
(http://www.epa.gov/ttn/atw/toxsource/summary.html) for the pollutants
included in table 1 to this appendix.
(5) Acute dose-response value for formaldehyde or acrolein changes.
(b) If your affected source commences operating outside of the low-
risk subcategory, it is no longer part of the low-risk subcategory. You
must be in compliance with 40 CFR part 63, subpart DDDD as specified in
paragraphs (b)(1) through (3) of this section. Operating outside of the
low-risk subcategory means that one of the changes listed in paragraphs
(a)(1) through (5) of this section has occurred and that the change is
inconsistent with your affected source's title V permit terms and
conditions reflecting EPA's approval of the parameters used in your low-
risk demonstration.
(1) You must notify the permitting authority as soon as you know, or
could have reasonably known, that your affected source is or will be
operating outside of the low-risk subcategory.
(2) You must be in compliance with the requirements of 40 CFR part
63, subpart DDDD as specified in paragraph (b)(2)(i) or (ii) of this
section, whichever applies.
(i) If you are operating outside of the low-risk subcategory due to
a change described in paragraph (a)(1) of this section, then you must
comply with 40 CFR part 63, subpart DDDD beginning on the date when your
affected source commences operating outside the low-risk subcategory.
(ii) If you are operating outside of the low-risk subcategory due to
a change described in paragraphs (a)(2) through (5) of this section,
then you must comply with 40 CFR part 63, subpart DDDD no later than 3
years from
[[Page 271]]
the date your affected source commences operating outside the low-risk
subcategory.
(3)(i) You must conduct performance tests no later than 180 calendar
days after the applicable date specified in paragraph (b)(2) of this
section.
(ii) You must conduct initial compliance demonstrations that do not
require performance tests 30 calendar days after the applicable date
specified in paragraph (b)(2) of this section.
(iii) For the purposes of affected sources affected by this section,
you must refer to the requirements in paragraph (b) of this section
instead of the requirements of Sec. 63.2233 when complying with 40 CFR
part 63, subpart DDDD.
14. What records must I keep?
(a) You must keep records of the information used in developing the
low-risk demonstration for your affected source, including all of the
information specified in section 8 of this appendix.
(b) You must keep records demonstrating continuous compliance with
the operating requirements for control devices.
(c) For each THC CEMS, you must keep the records specified in Sec.
63.2282(c) of 40 CFR part 63, subpart DDDD.
15. Definitions
The definitions in Sec. 63.2292 of 40 CFR part 63, subpart DDDD,
apply to this appendix. Additional definitions applicable for this
appendix are as follows:
Agricultural fiber board press means a press used in the production
of an agricultural fiber based composite wood product. An agricultural
fiber board press is a process unit.
Agricultural fiberboard mat dryer means a dryer used to reduce the
moisture of wet-formed agricultural fiber mats by applying heat. An
agricultural fiberboard mat dryer is a process unit.
Ancillary processes mean equipment and process units that are part
of the PCWP affected source that are not defined elsewhere in this
section or in section 63.2292 of subpart DDDD. Ancillary processes at a
specific facility do not include the equipment and process units
identified as insignificant sources of HAP emissions by that facility,
and they do not include equipment and process units subject to another
standard under 40 CFR part 63. Ancillary processes may be or may not be
HAP emissions sources.
Ancillary processes are process units.
Atmospheric refiner means a piece of equipment operated under
atmospheric pressure for refining (rubbing or grinding) the wood
material into fibers or particles. Atmospheric refiners are operated
with continuous infeed and outfeed of wood material and atmospheric
pressures throughout the refining process. An atmospheric refiner is a
process unit.
Blending and forming operations means the process of mixing adhesive
and other additives with the (wood) furnish of the composite panel and
making a mat of resinated fiber, particles, or strands to be compressed
into a reconstituted wood product such as particleboard, oriented
strandboard, or medium density fiberboard. Blending and forming
operations are process units.
Emission point means an individual stack or vent from a process unit
that emits HAP required for inclusion in the low-risk demonstration
specified in this appendix. Process units may have multiple emission
points.
Fiber washer means a unit in which water-soluble components of wood
(hemicellulose and sugars) that have been produced during digesting and
refining are removed from the wood fiber. Typically wet fiber leaving a
refiner is further diluted with water and then passed over a filter,
leaving the cleaned fiber on the surface. A fiber washer is a process
unit.
Finishing sander means a piece of equipment that uses an abrasive
drum, belt, or pad to impart smoothness to the surface of a plywood or
composite wood product panel and to reduce the panel to the prescribed
thickness. A finishing sander is a process unit.
Finishing saw means a piece of equipment used to trim or cut
finished plywood and composite wood products panels to a certain size. A
finishing saw is a process unit.
Hardwood plywood press means a hot press which, through heat and
pressure, bonds assembled hardwood veneers (including multiple plies of
veneer and/or a substrate) and resin into a hardwood plywood panel. A
hardwood plywood press is a process unit.
Hardwood veneer kiln means an enclosed dryer operated in batch
cycles by applying heat to reduce the moisture content from stacked
hardwood veneer. A hardwood veneer kiln is a process unit.
Hazard Index (HI) means the sum of more than one hazard quotient for
multiple substances and/or multiple exposure pathways.
Hazard Quotient (HQ) means the ratio of the predicted media
concentration of a pollutant to the media concentration at which no
adverse effects are expected. For inhalation exposures, the HQ is
calculated as the air concentration divided by the reference
concentration (RfC).
Humidifier means a process unit used to increase the moisture
content of hardboard following pressing or after post-baking. Typically,
water vapor saturated air is blown over the hardboard surfaces in a
closed cabinet. A humidifier is a process unit.
I-joist curing chamber means an oven or a room surrounded by a solid
wall or heavy plastic flaps that uses heat, infrared, or
[[Page 272]]
radio-frequency techniques to cure the adhesive. An I-joist curing
chamber is a process unit.
Log chipping means the production of wood chips from logs.
Log vat means a process unit that raises the temperature of the logs
inside by applying a heated substance, usually hot water and steam, to
the outside of the logs by spraying or soaking. A log vat is a process
unit.
Look-up table analysis means a risk screening analysis based on
comparing the toxicity-weighted HAP emission rate from the affected
source to the maximum allowable toxicity-weighted HAP emission rates
specified in tables 3 and 4 to this appendix.
LSL press means a composite wood product press that presses a loose
mat of resinated strands into a billet by simultaneous application of
heat and pressure. The billet is cut into laminated strand lumber after
exiting the press. An LSL press is a process unit.
LVL or PSL press means a composite wood product press that presses
resinated stacks of veneers into a solid billet by application of heat
and/or pressure. The billet is cut into laminated veneer lumber or
parallel strand lumber after exiting the press. An LVL or PSL press is a
process unit.
Natural gas means a naturally occurring mixture of hydrocarbon and
non-hydrocarbon gases found in geologic formations beneath the earth's
surface. The principal hydrocarbon constituent is methane.
Paddle-type particleboard dryer means a dryer to which heat is
applied to remove moisture from particles and paddles to advance
materials through the dryer. This type of dryer removes moisture
absorbed by particles due to high ambient temperature. A paddle-type
particleboard dryer is a process unit.
Panel-trim chipper means a piece of equipment that accepts the
discarded pieces of veneer or pressed plywood and composite wood
products panels that are removed by finishing saws and reduces these
pieces to small elements. A panel-trim chipper is a process unit.
Particleboard extruder means a heated die oriented either
horizontally or vertically through which resinated particles are
continuously forced to form extruded particleboard products. A
particleboard extruder is a process unit.
Particleboard press mold means a press that consists of molds that
apply heat and pressure to form molded or shaped particleboard products.
A particleboard press mold is a process unit.
Propane means a colorless gas derived from petroleum and natural
gas, with the molecular structure C3H8.
Radio-frequency veneer redryer means a dryer heated by radio-
frequency waves that is used to redry veneer that has been previously
dried. A radio-frequency veneer redryer is a process unit.
Reference Concentration (RfC) means an estimate (with uncertainty
spanning perhaps an order of magnitude) of a continuous inhalation
exposure to the human population (including sensitive subgroups) that is
likely to be without an appreciable risk of deleterious effects during a
lifetime. It can be derived from various types of human or animal data,
with uncertainty factors generally applied to reflect limitations of the
data used.
Resin storage tank means any storage tank, container, or vessel
connected to plywood and composite wood product production that holds
resin additives (in liquid form) containing any of the HAP listed in
table 2A to this appendix. A resin storage tank is a process unit.
Rotary agricultural fiber dryer means a rotary dryer operated by
applying heat to reduce the moisture of agricultural fiber. A rotary
agricultural fiber dryer is a process unit.
Softwood plywood press means a hot press which, through heat and
pressure, bonds assembled softwood veneer plies and resin into a
softwood plywood panel. A softwood plywood press is a process unit.
Softwood veneer kiln means an enclosed dryer operated in batch
cycles by applying heat to reduce the moisture content from stacked
softwood veneer. A softwood veneer kiln is a process unit.
Stand-alone digester means a pressure vessel used to heat and soften
wood chips (usually by steaming) before the chips are sent to a separate
process unit for refining into fiber. A stand-alone digester is a
process unit.
Target organ specific hazard index (TOSHI) means the sum of hazard
quotients for individual chemicals that affect the same organ or organ
system (e.g., respiratory system, central nervous system).
Unit Risk Estimate (URE) means the upper-bound excess lifetime
cancer risk estimated to result from continuous exposure to an agent at
a concentration of 1 microgram per cubic meter ([mu]g/m\3\) in air.
Wastewater/process water operation means equipment that processes
water in plywood or composite wood product facilities for reuse or
disposal. Wastewater/process water operations includes but is not
limited to pumps, holding ponds and tanks, cooling and heating
operations, settling systems, filtration systems, aeration systems,
clarifiers, pH adjustment systems, log storage ponds, pollution control
device water (including wash water), vacuum distillation systems, sludge
drying and disposal systems, spray irrigation fields, and connections to
POTW facilities. Wastewater/process water operations are process units.
Worst-case operating conditions means operation of a process unit
during emissions testing under the conditions that result in the highest
HAP emissions or that result in the
[[Page 273]]
emissions stream composition (including HAP and non-HAP) that is most
challenging for the control device if a control device is used. For
example, worst case conditions could include operation of the process
unit at maximum throughput, at its highest temperature, with the wood
species mix likely to produce the most HAP, and/or with the resin
formulation containing the greatest HAP.
Table 1 to Appendix B to Subpart DDDD of 40 CFR Part 63--HAP That Must
Be Included in the Demonstration of Eligibility for the Low-risk PCWP
Subcategory
------------------------------------------------------------------------
For your analysis of the following You must include the following
effects . . . HAP . . .
------------------------------------------------------------------------
(1) Chronic inhalation carcinogenic acetaldehyde, benzene, arsenic,
effects. beryllium, cadmium, chromium,
lead, nickel, and
formaldehyde.
(2) Chronic inhalation noncarcinogenic acetaldehyde, acrolein,
respiratory effects. cadmium, formaldehyde, and
methylene diphenyl
diisocyanate (MDI).
(3) Chronic inhalation noncarcinogenic manganese, lead, and phenol.
CNS effects.
(4) Acute inhalation................... acrolein and formaldehyde.
------------------------------------------------------------------------
[[Page 274]]
Table 2A to Appendix B to Subpart DDDD of 40 CFR Part 63--Testing and Emissions Estimation Specifications for Process Units
------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
HAP metals from
Process unit type Acetaldehyde Acrolein Formaldehyde Phenol Benzene MDI direct-fired process
units \a\
------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
Agricultural fiberboard mat Test................. Test................. Test................. Test................. Test................. NA.................. Test or fuel
dryers, Dry rotary dryers, analysis.
Fiberboard mat dryer (heated
zones), Green rotary dryers,
Hardboard ovens, Hardwood veneer
dryers (heated zones), Paddle-
type particleboard dryers, Press
predryers, Rotary agricultural
fiber dryers, Rotary strand
dryers, Softwood veneer dryers
(heated zones), Veneer redryers
(heated by conventional means).
Atmospheric refiners, Conveyor Test................. Test................. Test................. Test................. Test................. NA.................. NA.
strand dryers, Pressurized
refiners.
Primary tube dryers, Secondary Test................. Test................. Test................. Test................. Test................. Test if processing Test or fuel
tube dryers. furnish with MDI analysis.
resin added prior
to drying.
Agricultural fiber board presses, Test................. Test................. Test................. Test................. Test................. Test if board NA
Reconstituted wood products contains MDI resin.
presses, Reconstituted wood
product board coolers.
Blending and forming operations-- NA................... NA................... 0.060 lb/ODT\b\...... NA................... NA................... Engineering estimate NA.
particleboard and MDF. if MDI resin used.
Blending and forming operations-- NA................... NA................... 0.0036 lb/MSF \3/ Engineering estimate. NA................... Engineering estimate NA.
OSB. 8\ press if MDI resin used.
throughput.
Dry forming--hardboard........... Engineering estimate. NA................... Engineering estimate. Engineering estimate. NA................... NA.................. NA.
Fiber washers.................... 0.015 lb/ODT......... NA................... 0.0026 lb/ODT........ NA................... NA................... NA.................. NA.
Fiberboard mat dryer (fugitive 0.0055 lb/MSF \1/ NA................... 0.031 lb/MSF \1/2\. thn-eq>.
Finishing sanders................ 0.0031 lb/MSF........ NA................... 0.0042 lb/MSF........ 0.015 lb/MSF......... NA................... Engineering estimate NA.
if MDI resin used.
Finishing saws................... 0.00092 lb/MSF \3/ NA................... 0.00034 lb/MSF \3/ 0.0057 lb/MSF........ NA................... Engineering estimate NA.
8\. 8\. if MDI resin used.
Hardwood plywood presses......... NA................... NA................... 0.0088 lb/MSF \3/ 0.016 lb/MSF \3/8\. thn-eq>.
Hardwood veneer dryer (cooling 0.058 lb/MSF \3/8\. thn-eq>.
Hardwood veneer kilns............ 0.067 lb/MSF \3/8\. thn-eq>. 8\,.
Humidifiers...................... 0.0018 lb/MSF \1/ 0.0087 lb/MSF \1/ 0.0010 lb/MSF \1/ 0.00057 lb/MSF \1/ 0.0000062 lb/MSF \1/ NA.................. NA.
8\. 8\. 8\. 8\. 8\.
I-joist curing chambers.......... NA................... NA................... 0.00018 lb/MLF....... NA................... NA................... Engineering estimate NA.
if MDI resin used.
[[Page 275]]
Log vats......................... 0.0047 lb/MSF \3/ NA................... NA................... NA................... NA................... NA.................. NA.
8\
removed from vat per
hour.
LSL presses...................... Engineering estimate. NA................... 0.029 lb/1000 ft\3\.. Engineering estimate. NA................... 0.18 lb/1000 ft\3\.. NA.
LVL presses...................... 0.29 lb/1000 ft\3\... NA................... 0.79 lb/1000 ft\3\... NA................... NA................... NA.................. NA.
Lumber kilns..................... 0.065 lb/MBF or 0.009 lb/MBF or 0.034 lb/MBF or 0.010 lb/MBF or NA................... NA.................. Engineering
conduct small-scale conduct small-scale conduct small-scale conduct small-scale estimate.
kiln testing kiln testing kiln testing kiln testing
according to according to according to according to
appendix C to appendix C to appendix C to appendix C to
subpart DDDD. subpart DDDD. subpart DDDD. subpart DDDD.
Panel-trim chippers.............. 0.00081 lb/MSF \3/ NA................... 0.00034 lb/MSF \3/ 0.0019 lb/MSF \3/ NA................... NA.................. NA.
8\ 8\ 8\
finished board finished board finished board
production. production. production.
Particleboard press molds, 0.034 lb/MSF \3/4\. 4\. thn-eq>. thn-eq>. 4\.
Radio-frequency veneer redryers.. 0.0029 lb/MSF \3/ NA................... 0.00065 lb/MSF \3/ NA................... NA................... NA.................. NA.
8\. 8\.
Resin storage tanks--closed roof. NA................... NA................... For tanks with resin For tanks with resin NA................... For tanks with MDI NA.
containing containing phenol, resin, 0.0013 lb/hr
formaldehyde, 0.001 0.0002 lb/hr per per tank OR model
lb/hr per tank OR tank OR model using using TANKS
model using TANKS TANKS software\c\. software\c\.
software\c\.
Resin storage tanks--open roof... NA................... NA................... Engineering estimate Engineering estimate NA................... Engineering estimate NA.
if resin contains if resin contains if resin contains
formaldehyde. phenol. MDI.
Softwood plywood presses......... 0.012 lb/MSF \3/8\. 8\. 8\.
Softwood veneer dryers (cooling 0.012 lb/MSF \3/8\. 8\. thn-eq>.
Softwood veneer kilns............ 0.097 lb/MSF \3/8\. thn-eq>. thn-eq>. thn-eq>. 8\.
Stand-alone digesters............ 0.030 lb/ODT......... 0.0024 lb/ODT........ 0.0045 lb/ODT........ 0.0012 lb/ODT........ NA................... NA.................. NA.
Wastewater/process water Engineering estimate Engineering estimate Engineering estimate Engineering estimate Engineering estimate NA.................. NA.
operations. (such as WATER9\c\ (such as WATER9\c\ (such as WATER9\c\ (such as WATER9\c\ (such as WATER9\c\
or other method). or other method). or other method). or other method). or other method).
Wet forming--fiberboard and 0.0075 lb/MSF \1/ NA................... 0.0036 lb/MSF \1/ NA................... NA................... NA.................. NA.
hardboard (without PF resin). 2\. 2\.
Wet forming--hardboard (PF resin) 0.0067 lb/ODT........ NA................... 0.00039 lb/ODT....... 0.00075 lb/ODT....... NA................... NA.................. NA.
Miscellaneous coating operations, NA................... NA................... NA................... NA................... NA................... NA.................. NA.
Log chipping, Softwood veneer
dryer fugitive emissions.
Other ancillary processes (not Engineering estimate. Engineering estimate. Engineering estimate. Engineering estimate. Engineering estimate. Engineering estimate Engineering
listed elsewhere in this table) estimate.
that may emit HAP listed in this
table.
------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
Test: Emissions testing must be conducted for the process unit and pollutant according to the test methods specified in table 2B to appendix B to subpart DDDD.
[[Page 276]]
NA: Not applicable. No emission estimates or emissions tests are required for purposes of the low-risk demonstration.
lb/MSF: Pounds of HAP per thousand square feet of board of the inches thickness specified (e.g., lb/MSF \3/4\ = pounds of HAP per thousand square feet of \3/4\-inch board). See equation in
Sec. 63.2262(j) of subpart DDDD to convert from one thickness basis to another.
lb/ODT: Pounds of HAP per oven dried ton of wood material.
lb/MBF: Pounds of HAP per thousand board feet.
lb/MLF: Pounds of HAP per thousand linear feet
\a\ Direct-fired process units firing natural gas or propane are NA; thus, no emissions estimates, emissions tests, or fuel analyses are required for the purposes of the low-risk
demonstration.
\b\ Estimation of formaldehyde emissions is only necessary for facilities that use resin containing formaldehyde.
\c\ TANKS and WATER9 software is available at http://www.epa.gov/ttn/chief/software/index.html.
[[Page 277]]
Table 2B to Appendix B to Subpart DDDD of 40 CFR part 63--Emission Test
Methods
------------------------------------------------------------------------
For . . . You must . . . Using . . .
------------------------------------------------------------------------
(1) each process unit select sampling Method 1 or 1A of 40
required to be tested ports' location and CFR part 60,
according to table 2A to the number of appendix A (as
this appendix. traverse points. appropriate).
(2) each process unit determine velocity Method 2 in addition
required to be tested and volumetric flow to Method 2A, 2C,
according to table 2A to rate;. 2D, 2F, or 2G in
this appendix. appendix A to 40
CFR part 60 (as
appropriate).
(3) each process unit conduct gas Method 3, 3A, or 3B
required to be tested molecular weight in appendix A to 40
according to table 2A to analysis. CFR part 60 (as
this appendix. appropriate).
(4) each process unit measure moisture Method 4 in appendix
required to be tested content of the A to 40 CFR part
according to table 2A to stack gas. 60.
this appendix.
(5) each process unit measure emissions of NCASI Method IM/CAN/
required to be tested acetaldehyde. WP-99.02 (IBR, see
according to table 2A to 40 CFR 63.14(f));
this appendix. OR Method 320 in
appendix A to 40
CFR part 63; OR the
NCASI Method ISS/FP-
A105.01 (IBR, see
Sec. 63.14(f));
OR Method 0011 in
``Test Methods for
Evaluating Solid
Waste, Physical/
Chemical Methods''
(EPA Publication
No. SW-846); OR
ASTM D6348-03\b\
(IBR, see 40 CFR
63.14(b)).
(6) each process unit measure emissions of NCASI Method IM/CAN/
required to be tested acrolein. WP-99.02 (IBR, see
according to table 2A to 40 CFR 63.14(f));
this appendix. OR Method 320 in
appendix A to 40
CFR part 63; OR the
NCASI Method ISS/FP-
A105.01 (IBR, see
Sec. 63.14(f));
OR ASTM D6348-03
\b\ (IBR, see 40
CFR 63.14(b)).
(7) each process unit measure emissions of NCASI Method IM/CAN/
required to be tested formaldehyde. WP-99.02 (IBR, see
according to table 2A to 40 CFR 63.14(f));
this appendix. OR Method 320 in
appendix A to 40
CFR part 63; OR the
NCASI Method ISS/FP-
A105.01 (IBR, see
Sec. 63.14(f));
OR the NCASI Method
CI/WP-98.01; OR
Method 316 in
appendix A to 40
CFR part 63; OR
Method 0011 in
``Test Methods for
Evaluating Solid
Waste, Physical/
Chemical Methods''
(EPA Publication
No. SW-846); OR
ASTM D6348-03 \b\
(IBR, see 40 CFR
63.14(b)).
(8) each process unit measure emissions of NCASI Method IM/CAN/
required to be tested phenol. WP-99.02 (IBR, see
according to table 2A to 40 CFR 63.14(f));
this appendix. OR Method 320 in
appendix A to 40
CFR part 63; OR the
NCASI Method ISS/FP-
A105.01 (IBR, see
Sec. 63.14(f));
OR the NCASI Method
CI/WP-98.01; OR
ASTM D6348-03 \b\
(IBR, see 40 CFR
63.14(b)).
(9) each process unit measure emissions of Method 18 in
required to be tested benzene. appendix A to 40
according to table 2A to CFR part 60; OR
this appendix. NCASI Method IM/CAN/
WP-99.02 (IBR, see
40 CFR 63.14(f));
OR Method 320 in
appendix A to 40
CFR part 63; OR
ASTM D6348-03 \b\
(IBR, see 40 CFR
63.14(b)).
(10) each process unit that measure emissions of Method 320 in
processes material MDI. appendix A to 40
containing MDI resin CFR part 63; OR
required to be tested Method 207 in
according to table 2A to appendix M to 40
this appendix. CFR part 51; OR
Conditional Test
Method (CTM) 031
which is posted on
http://www.epa.gov/
ttn/emc/ctm.html
(11) each direct-fired measure emissions of Method 29 in
process unit \a\ required the following HAP appendix A to 40
to be tested according to metals: Arsenic, CFR part 60 OR fuel
table 2A to this appendix. beryllium, cadmium, analysis (see
chromium, lead, section 5(m) of
manganese, and this appendix).
nickel..
[[Page 278]]
(12) each reconstituted wood meet the design Methods 204 and 204A
product press or specifications through 204F of 40
reconstituted wood product included in the CFR part 51,
board cooler with a HAP definition of wood appendix M to
control device. products enclosure determine capture
in Sec. 63.2292 efficiency (except
of subpart DDDD of for wood products
40 CFR part 63; or enclosures as
determine the defined in Sec.
percent capture 63.2292).
efficiency of the Enclosures that
enclosure directing meet the definition
emissions to an add- of wood products
on control device. enclosure or that
meet Method 204
requirements for a
PTE are assumed to
have a capture
efficiency of 100
percent. Enclosures
that do not meet
either the PTE
requirements or
design criteria for
a wood products
enclosure must
determine the
capture efficiency
by constructing a
TTE according to
the requirements of
Method 204 and
applying Methods
204A through 204F
(as appropriate).
As an alternative to
Methods 204 and
204A through 204F,
you may use the
tracer gas method
contained in
appendix A to
subpart DDDD.
(13) each reconstituted wood determine the a TTE and Methods
product press or percent capture 204 and 204A
reconstituted wood product efficiency. through 204F (as
board cooler required to be appropriate) of 40
tested according to table CFR part 51,
2A to this appendix. appendix M. As an
alternative to
installing a TTE
and using Methods
204 and 204A
through 204F, you
may use the tracer
gas method
contained in
appendix A to
subpart DDDD.
Enclosures that
meet the design
criteria (1)
through (4) in the
definition of wood
products enclosure,
or that meet Method
204 requirements
for a PTE (except
for the criteria
specified in
section 6.2 of
Method 204) are
assumed to have a
capture efficiency
of 100 percent.
Measured emissions
divided by the
capture efficiency
provides the
emission rate.
Fugitive emissions
are equal to the
difference in the
emission rate and
measured emissions.
(14) each process unit with establish the site- data from the
a HAP control device specific operating parameter
required to be tested requirements monitoring system
according to table 2A to (including the or THC CEMS and the
this appendix. parameter limits or applicable
THC concentration performance test
limits) in table 2 method(s).
to subpart DDDD.
------------------------------------------------------------------------
\a\ Excludes direct-fired process units fired with only natural gas or
propane.
\b\ Provided that percent R as determined in Annex A5 of ASTM D6348-03
is equal or greater than 70 percent and less than or equal to 130
percent.
[[Page 279]]
Table 3 to Appendix B to Subpart DDDD of 40 CFR Part 63--Maximum Allowable Toxicity-Weighted Carcinogen Emission Rate
[(lb/hr)/([mu]g/m\3\)]
--------------------------------------------------------------------------------------------------------------------------------------------------------
Distance to property boundary (m)
Stack height (m) -----------------------------------------------------------------------------------------------------------------------
0 50 100 150 200 250 500 1000 1500 2000 3000 5000
--------------------------------------------------------------------------------------------------------------------------------------------------------
5............................... 8.72E-07 8.72E-07 8.72E-07 9.63E-07 1.25E-06 1.51E-06 2.66E-06 4.25E-06 4.39E-06 4.39E-06 4.39E-06 5.00E-06
10.............................. 2.47E-06 2.47E-06 2.47E-06 2.47E-06 2.47E-06 2.61E-06 3.58E-06 5.03E-06 5.89E-06 5.89E-06 5.89E-06 6.16E-06
20.............................. 5.81E-06 5.81E-06 5.81E-06 5.81E-06 5.81E-06 5.81E-06 5.90E-06 7.39E-06 8.90E-06 9.97E-06 9.97E-06 1.12E-05
30.............................. 7.74E-06 7.74E-06 7.74E-06 7.74E-06 7.74E-06 7.74E-06 8.28E-06 9.49E-06 1.17E-05 1.35E-05 1.55E-05 1.61E-05
40.............................. 9.20E-06 9.20E-06 9.20E-06 9.20E-06 9.20E-06 9.20E-06 9.24E-06 1.17E-05 1.34E-05 1.51E-05 1.98E-05 2.22E-05
50.............................. 1.02E-05 1.02E-05 1.02E-05 1.02E-05 1.02E-05 1.02E-05 1.02E-05 1.36E-05 1.53E-05 1.66E-05 2.37E-05 2.95E-05
60.............................. 1.13E-05 1.13E-05 1.13E-05 1.13E-05 1.13E-05 1.13E-05 1.13E-05 1.53E-05 1.76E-05 1.85E-05 2.51E-05 3.45E-05
70.............................. 1.23E-05 1.23E-05 1.23E-05 1.23E-05 1.23E-05 1.23E-05 1.23E-05 1.72E-05 2.04E-05 2.06E-05 2.66E-05 4.07E-05
80.............................. 1.34E-05 1.34E-05 1.34E-05 1.34E-05 1.34E-05 1.34E-05 1.34E-05 1.92E-05 2.15E-05 2.31E-05 2.82E-05 4.34E-05
100............................. 1.52E-05 1.52E-05 1.52E-05 1.52E-05 1.52E-05 1.52E-05 1.52E-05 1.97E-05 2.40E-05 2.79E-05 3.17E-05 4.49E-05
200............................. 1.76E-05 1.76E-05 1.76E-05 1.76E-05 1.76E-05 1.76E-05 1.76E-05 2.06E-05 2.94E-05 3.24E-05 4.03E-05 5.04E-05
--------------------------------------------------------------------------------------------------------------------------------------------------------
MIR=1E-06.
Table 4 to Appendix B to Subpart DDDD of 40 CFR Part 63--Maximum Allowable Toxicity-Weighted Noncarcinogen Emission Rate
[(lb/hr)/([mu]g/m\3\)]
--------------------------------------------------------------------------------------------------------------------------------------------------------
Distance to property boundary (m)
Stack height (m) -----------------------------------------------------------------------------------------------------------------------
0 50 100 150 200 250 500 1000 1500 2000 3000 5000
--------------------------------------------------------------------------------------------------------------------------------------------------------
5............................... 2.51E-01 2.51E-01 3.16E-01 3.16E-01 3.16E-01 3.16E-01 3.16E-01 3.46E-01 4.66E-01 6.21E-01 9.82E-01 1.80E+00
10.............................. 5.62E-01 5.62E-01 5.62E-01 5.62E-01 5.62E-01 5.62E-01 5.62E-01 5.70E-01 6.33E-01 7.71E-01 1.13E+00 1.97E+00
20.............................. 1.43E+00 1.43E+00 1.43E+00 1.43E+00 1.43E+00 1.43E+00 1.43E+00 1.43E+00 1.68E+00 1.83E+00 2.26E+00 3.51E+00
30.............................. 2.36E+00 2.36E+00 2.36E+00 2.36E+00 2.36E+00 2.36E+00 2.53E+00 3.04E+00 3.04E+00 3.33E+00 4.45E+00 5.81E+00
40.............................. 3.11E+00 3.11E+00 3.11E+00 3.11E+00 3.11E+00 3.11E+00 3.42E+00 4.04E+00 5.07E+00 5.51E+00 6.39E+00 9.63E+00
50.............................. 3.93E+00 3.93E+00 3.93E+00 3.93E+00 3.93E+00 3.93E+00 4.49E+00 4.92E+00 6.95E+00 7.35E+00 8.99E+00 1.25E+01
60.............................. 4.83E+00 4.83E+00 4.83E+00 4.83E+00 4.83E+00 4.83E+00 5.56E+00 6.13E+00 7.80E+00 1.01E+01 1.10E+01 1.63E+01
70.............................. 5.77E+00 5.77E+00 5.77E+00 5.77E+00 5.77E+00 5.77E+00 6.45E+00 7.71E+00 8.83E+00 1.18E+01 1.36E+01 1.86E+01
80.............................. 6.74E+00 6.74E+00 6.74E+00 6.74E+00 6.74E+00 6.74E+00 7.12E+00 9.50E+00 1.01E+01 1.29E+01 1.72E+01 2.13E+01
100............................. 8.87E+00 8.87E+00 8.87E+00 8.87E+00 8.87E+00 8.87E+00 8.88E+00 1.19E+01 1.37E+01 1.55E+01 2.38E+01 2.89E+01
200............................. 1.70E+01 1.70E+01 1.70E+01 1.70E+01 1.70E+01 1.70E+01 1.70E+01 2.05E+01 2.93E+01 3.06E+01 4.02E+01 4.93E+01
--------------------------------------------------------------------------------------------------------------------------------------------------------
HI=1.
[[Page 280]]
[71 FR 8375, Feb. 16, 2006]
Appendix C to Subpart DDDD of Part 63--Considerations for a Small-Scale
Kiln Emission Testing Program
1.0 Purpose
Emissions test data from small-scale lumber kilns can be used to
reasonably approximate emissions from full-scale lumber kilns if
representative lumber samples are dried and the venting characteristics
of the small-scale kiln mimic those of the full-scale kiln. This
appendix provides a list of considerations that must be taken into
account by facilities conducting small-scale lumber kiln emissions
testing to approximate emissions from their full-scale lumber kilns for
purposes of the low-risk demonstration described under appendix B to
subpart DDDD of part 63.
The considerations described in this appendix apply only for small-
scale lumber kiln emissions testing conducted to provide data for the
low-risk demonstration described under appendix B to subpart DDDD of
part 63. Permitting authorities may require different procedures for
testing or estimating lumber kiln emissions for purposes other than the
low-risk demonstration described under appendix B to subpart DDDD of
part 63.
2.0 Considerations for Lumber Samples
2.1 A written plan must be developed for obtaining representative
lumber samples to use as charges at the small-scale kilns. The plan must
discuss how the samples are selected and handled and the basis upon
which they are considered to be representative. If possible, information
on the harvest site, date harvested, segregation from other lumber (if
segregated), and processing at the sawmill must be included. If this
information is unavailable, a general description of the sawmill's wood
procurement and processing practices must be provided. The affected
source and testing laboratory must approve the written test plan before
beginning the small-scale kiln testing.
2.2 Samples must not be subject to significant air drying during
processing, shipping, or storage prior to charging into the small-scale
kiln.
2.3 Enough lumber must be collected to provide for extra lumber
charges in case of testing failures.
2.4 Information on the lumber used for each small-scale kiln charge
must be reported including the items in paragraphs 2.4.1 though 2.4.4 of
this section:
2.4.1 Total kiln charge, board feet,
2.4.2 Nominal dimensions of lumber dried (for example, 2x4s),
2.4.3 Moisture content (dry basis) of the green lumber, and
2.4.4 Moisture content (dry basis) of the kiln dried lumber.
3.0 Considerations for Kiln Operating Parameters
The small-scale kiln must operate in a similar manner to the full-
scale kilns for items 3.1 through 3.3 of this section. The small-scale
kiln must operate in a reasonably consistent manner from charge-to-
charge for all items (3.1 through 3.5) listed in this section.
3.1 Air velocity through the kiln charge.
3.2 Temperature profiles or kiln schedules (wet-bulb/dry-bulb
temperatures throughout the kiln cycle).
3.3 Ending moisture content (dry basis) of the lumber (may need to
be mathematically adjusted for small-scale kilns).
3.4 Kiln venting profile (trend) for the sample event/kiln cycle
(normalized to a board foot or thousand board feet).
3.5 Mass emission rate profile (trend) for the sample event/kiln
cycle.
4.0 Considerations for Emission Sampling
4.1 Sample equipment must be able to sample gases with high moisture
content.
4.2 You must accurately measure/calculate total kiln exhaust and
exhaust moisture content. If direct measurements are impractical other
methods used must be explicitly discussed in the report.
4.3 You must accurately measure the concentration of the compounds
of concern either in the kiln exhaust or at a proper location within the
kiln.
5.0 Considerations for Sample Intervals and Sampling Runs
5.1 A minimum of two full kiln cycles or batches must be tested to
determine the emissions for a particular wood species or for a facility
utilizing only one wood species.
5.2 You may use a single kiln cycle for emission values for wood
species that require more than 3 days to dry.
5.3 Since kiln drying cycles typically exceed 20 hours, it is
suggested that sampling be conducted in intervals throughout the drying
cycle. Three hours provide a reasonable sample interval (sample run),
but sampling equipment or manpower may dictate other schedules. Sampling
equipment ``turnaround'' will result in gaps in the kiln emission data.
The gaps must not exceed 45% of the kiln cycle. Data for the gaps
occurring at certain periods of time in the drying cycle can be
calculated by linear interpolation from the sampling values on either
side of the gap. Other techniques may be required if the data gap occurs
when the measured data
[[Page 281]]
exhibit high levels of variability. As a minimum, sampling intervals
must include initial hours of the kiln operating cycle once the kiln has
warmed to target wet bulb and/or dry bulb temperatures and begins
venting, hours of kiln operation during the middle of the kiln drying
cycle, and hours of kiln operation towards the end of the kiln drying
cycle.
5.4 The final production-based mass emission rate for the small-
scale kiln sample event is determined by integrating the area under the
mass emission rate profile curve.
6.0 Considerations for Reporting
The emissions report must contain the information in paragraphs 6.1
through 6.9 of this section.
6.1 Graphical, charge-by-charge results for items 3.2, 3.4, and 3.5
above and numerical data for items 3.1 and 3.3. Describe how the full-
scale kiln operates in comparison to the small-scale kiln in order to
show that the full-scale kiln drying cycle was reasonably reproduced in
the small-scale kiln.
6.2 A moisture balance by comparing the water loss (from the green
versus dry lumber charge weight difference) to the water exhausted from
the kiln (using the exhaust flow rate and moisture content of the
exhaust).
6.3 A description of the sampling system and sampling methodology.
6.4 A summary and background data for all quality assurance measures
required by the sampling methods.
6.5 Discussion of method detection limits and treatment of values
below the detection limit.
6.6 An example of emission rate calculations.
6.7 Explanation or reference to the methodology used to calculate
emissions to the target or desired ending lumber moisture content.
6.8 Information outlined in section 2.0 of this appendix, including
a discussion of collection and handling of lumber samples.
6.9 Data and show calculations for developed emission factors.
7.0 Guidance
7.1 NCASI Technical Bulletin 845 provides a large amount of detail
that can be of assistance in many phases of a small-scale kiln testing
program. This report should be viewed as ``one way,'' not ``the only
way'' to conduct testing.
7.2 Oregon State University, Mississippi State University, the
University of Idaho, and others have published information regarding
operation and testing of small-scale kilns. These publications are a
very good source of information on small-scale kilns.
[71 FR 8387, Feb. 16, 2006]
Subpart EEEE_National Emission Standards for Hazardous Air Pollutants:
Organic Liquids Distribution (Non-Gasoline)
Source: 69 FR 5063, Feb. 3, 2004, unless otherwise noted.
What This Subpart Covers
Sec. 63.2330 What is the purpose of this subpart?
This subpart establishes national emission limitations, operating
limits, and work practice standards for organic hazardous air pollutants
(HAP) emitted from organic liquids distribution (OLD) (non-gasoline)
operations at major sources of HAP emissions. This subpart also
establishes requirements to demonstrate initial and continuous
compliance with the emission limitations, operating limits, and work
practice standards.
Sec. 63.2334 Am I subject to this subpart?
(a) Except as provided for in paragraphs (b) and (c) of this
section, you are subject to this subpart if you own or operate an OLD
operation that is located at, or is part of, a major source of HAP
emissions. An OLD operation may occupy an entire plant site or be
collocated with other industrial (e.g., manufacturing) operations at the
same plant site.
(b) Organic liquid distribution operations located at research and
development facilities, consistent with section 112(c)(7) of the Clean
Air Act (CAA), are not subject to this subpart.
(c) Organic liquid distribution operations do not include the
activities and equipment, including product loading racks, used to
process, store, or transfer organic liquids at facilities listed in
paragraph (c) (1) and (2) of this section.
(1) Oil and natural gas production field facilities, as the term
``facility'' is defined in Sec. 63.761 of subpart HH.
(2) Natural gas transmission and storage facilities, as the term
``facility'' is defined in Sec. 63.1271 of subpart HHH.
[[Page 282]]