National Emissions Standards for Hazardous Air Pollutants: Secondary Lead Smelting, 29032-29081 [2011-11220]
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Federal Register / Vol. 76, No. 97 / Thursday, May 19, 2011 / Proposed Rules
ENVIRONMENTAL PROTECTION
AGENCY
40 CFR Part 63
[EPA–HQ–OAR–2011–0344; FRL–9303–4]
RIN 2060–AQ68
National Emissions Standards for
Hazardous Air Pollutants: Secondary
Lead Smelting
Environmental Protection
Agency (EPA).
ACTION: Proposed rule.
AGENCY:
EPA is proposing
amendments to the national emissions
standards for hazardous air pollutants
for Secondary Lead Smelting to address
the results of the residual risk and
technology review that EPA is required
to conduct by the Clean Air Act. These
proposed amendments include revisions
to the stack emissions limits for lead;
revisions to the fugitive dust emissions
control requirements; the addition of
total hydrocarbons emissions limits for
reverberatory, electric, and rotary
furnaces; the addition of emissions
limits and work practice requirements
for dioxins and furans; and the
modification and addition of testing and
monitoring and related notification,
recordkeeping, and reporting
requirements. We are also proposing to
revise provisions addressing periods of
startup, shutdown, and malfunction to
ensure that the rules are consistent with
a recent court decision.
DATES: Comments must be received on
or before July 5, 2011. Under the
Paperwork Reduction Act, comments on
the information collection provisions
are best assured of having full effect if
the Office of Management and Budget
(OMB) receives a copy of your
comments on or before June 20, 2011.
Public Hearing. If anyone contacts
EPA requesting to speak at a public
hearing by May 31, 2011, a public
hearing will be held on June 3, 2011.
ADDRESSES: Submit your comments,
identified by Docket ID Number EPA–
HQ–OAR–2011–0344, by one of the
following methods:
• https://www.regulations.gov: Follow
the on-line instructions for submitting
comments.
• E-mail: a-and-r-docket@epa.gov,
Attention Docket ID Number EPA–HQ–
OAR–2011–0344.
• Fax: (202) 566–9744, Attention
Docket ID Number EPA–HQ–OAR–
2011–0344.
• Mail: U.S. Postal Service, send
comments to: EPA Docket Center, EPA
West (Air Docket), Attention Docket ID
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SUMMARY:
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Number EPA–HQ–OAR–2011–0344,
U.S. Environmental Protection Agency,
Mailcode: 2822T, 1200 Pennsylvania
Ave., NW., Washington, DC 20460.
Please include a total of two copies. In
addition, please mail a copy of your
comments on the information collection
provisions to the Office of Information
and Regulatory Affairs, Office of
Management and Budget (OMB), Attn:
Desk Officer for EPA, 725 17th Street,
NW., Washington, DC 20503.
• Hand Delivery: U.S. Environmental
Protection Agency, EPA West (Air
Docket), Room 3334, 1301 Constitution
Ave., NW., Washington, DC 20004,
Attention Docket ID Number EPA–HQ–
OAR–2011–0344. Such deliveries are
only accepted during the Docket’s
normal hours of operation, and special
arrangements should be made for
deliveries of boxed information.
Instructions. Direct your comments to
Docket ID Number EPA–HQ–OAR–
2011–0344. EPA’s policy is that all
comments received will be included in
the public docket without change and
may be made available on-line at https://
www.regulations.gov, including any
personal information provided, unless
the comment includes information
claimed to be confidential business
information (CBI) or other information
whose disclosure is restricted by statute.
Do not submit information that you
consider to be CBI or otherwise
protected through https://
www.regulations.gov or e-mail. The
https://www.regulations.gov Web site is
an ‘‘anonymous access’’ system, which
means EPA will not know your identity
or contact information unless you
provide it in the body of your comment.
If you send an e-mail comment directly
to EPA without going through https://
www.regulations.gov, your e-mail
address will be automatically captured
and included as part of the comment
that is placed in the public docket and
made available on the Internet. If you
submit an electronic comment, EPA
recommends that you include your
name and other contact information in
the body of your comment and with any
disk or CD–ROM you submit. If EPA
cannot read your comment due to
technical difficulties and cannot contact
you for clarification, EPA may not be
able to consider your comment.
Electronic files should avoid the use of
special characters, any form of
encryption, and be free of any defects or
viruses. For additional information
about EPA’s public docket, visit the EPA
Docket Center homepage at https://
www.epa.gov/epahome/dockets.htm.
Docket. EPA has established a docket
for this rulemaking under Docket ID
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Number EPA–HQ–OAR–2011–0344. All
documents in the docket are listed in
the https://www.regulations.gov index.
Although listed in the index, some
information is not publicly available,
e.g., CBI or other information whose
disclosure is restricted by statute.
Certain other material, such as
copyrighted material, is not placed on
the Internet and will be publicly
available only in hard copy. Publicly
available docket materials are available
either electronically in https://
www.regulations.gov or in hard copy at
the EPA Docket Center, EPA West,
Room 3334, 1301 Constitution Ave.,
NW., Washington, DC. The Public
Reading Room is open from 8:30 a.m. to
4:30 p.m., Monday through Friday,
excluding legal holidays. The telephone
number for the Public Reading Room is
(202) 566–1744, and the telephone
number for the EPA Docket Center is
(202) 566–1742.
Public Hearing. If a public hearing is
held, it will begin at 10 a.m. on June 3,
2011 and will be held at EPA’s campus
in Research Triangle Park, North
Carolina, or at an alternate facility
nearby. Persons interested in presenting
oral testimony or inquiring as to
whether a public hearing is to be held
should contact Ms. Virginia Hunt, Office
of Air Quality Planning and Standards,
Sector Policies and Programs Division,
(D243–02), U.S. Environmental
Protection Agency, Research Triangle
Park, North Carolina 27711; telephone
number: (919) 541–0832.
For
questions about this proposed action,
contact Mr. Chuck French, Sector
Policies and Programs Division (D243–
02), Office of Air Quality Planning and
Standards, U.S. Environmental
Protection Agency, Research Triangle
Park, North Carolina 27711, telephone
(919) 541–7912; fax number: (919) 541–
5450; and e-mail address:
french.chuck@epa.gov. For specific
information regarding the risk modeling
methodology, contact Ms. Elaine
Manning, Health and Environmental
Impacts Division (C539–02), Office of
Air Quality Planning and Standards,
U.S. Environmental Protection Agency,
Research Triangle Park, North Carolina
27711; telephone number: (919) 541–
5499; fax number: (919) 541–0840; and
e-mail address:
manning.elaine@epa.gov. For
information about the applicability of
the NESHAP to a particular entity,
contact the appropriate person listed in
Table 1 of this preamble.
FOR FURTHER INFORMATION CONTACT:
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TABLE 1—LIST OF EPA CONTACTS FOR THE NESHAP ADDRESSED IN THIS PROPOSED ACTION
OECA Contact 1
NESHAP for:
Secondary Lead Smelting ................................................
1 EPA
2 EPA
Chuck French, (919) 541–7912,
french.chuck@epa.gov
Office of Enforcement and Compliance Assurance.
Office of Air Quality Planning and Standards.
SUPPLEMENTARY INFORMATION:
Preamble Acronyms and Abbreviations
Several acronyms and terms used to
describe industrial processes, data
inventories, and risk modeling are
included in this preamble. While this
may not be an exhaustive list, to ease
the reading of this preamble and for
reference purposes, the following terms
and acronyms are defined here:
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Maria Malave, (202) 564–7027
malave.maria@epa.gov
OAQPS Contact 2
ADAF age-dependent adjustment factors
AEGL acute exposure guideline levels
AERMOD air dispersion model used by the
HEM–3 model
ANPRM advance notice of proposed
rulemaking
ATSDR Agency for Toxic Substances and
Disease Registry
BACT best available control technology
BLDS bag leak detection system
CAA Clean Air Act
CBI Confidential Business Information
CEMS continuous emissions monitoring
system
CFR Code of Federal Regulations
CTE central tendency exposure
D/F dioxins and furans
EJ environmental justice
EPA Environmental Protection Agency
ERPG Emergency Response Planning
Guidelines
ERT Electronic Reporting Tool
HAP hazardous air pollutants
HEM–3 Human Exposure Model, Version 3
HEPA high efficiency particulate air
HHRAP Human Health Risk Assessment
Protocols
HI Hazard Index
HON hazardous organic national emissions
standards for hazardous air pollutants
HQ Hazard Quotient
ICR information collection request
IRIS Integrated Risk Information System
Km kilometer
LAER lowest achievable emissions rate
lb/yr pounds per year
MACT maximum achievable control
technology
MACT Code Code within the NEI used to
identify processes included in a source
category
MDL method detection level
mg/acm milligrams per actual cubic meter
mg/dscm milligrams per dry standard cubic
meter
mg/m3 milligrams per cubic meter
MIR maximum individual risk
MRL minimum risk level
NAAQS National Ambient Air Quality
Standard
NAC/AEGL Committee National Advisory
Committee for Acute Exposure Guideline
Levels for Hazardous Substances
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NAICS North American Industry
Classification System
NAS National Academy of Sciences
NATA National Air Toxics Assessment
NEI National Emissions Inventory
NESHAP National Emissions Standards for
Hazardous Air Pollutants
NOAEL no observed adverse effects level
NRC National Research Council
NTTAA National Technology Transfer and
Advancement Act
O&M operation and maintenance
OAQPS Office of Air Quality Planning and
Standards
ODW Office of Drinking Water
OECA Office of Enforcement and
Compliance Assurance
OHEA Office of Health and Environmental
Assessment
OMB Office of Management and Budget
PB–HAP hazardous air pollutants known to
be persistent and bio-accumulative in the
environment
PM particulate matter
POM polycyclic organic matter
ppmv parts per million volume
RACT reasonably available control
technology
RBLC RACT/BACT/LAERClearinghouse
REL reference exposure level
RFA Regulatory Flexibility Act
RfC reference concentration
RfD reference dose
RIA Regulatory Impact Analysis
RME reasonable maximum exposure
RTR residual risk and technology review
SAB Science Advisory Board
SBA Small Business Administration
SCC Source Classification Codes
SF3 2000 Census of Population and
Housing Summary
SIP State Implementation Plan
SOP standard operating procedures
SSM startup, shutdown, and malfunction
TEF toxic equivalency factors
TEQ toxic equivalency quotient
THC total hydrocarbons
TOSHI target organ-specific hazard index
TPY tons per year
TRIM Total Risk Integrated Modeling
System
TTN Technology Transfer Network
UF uncertainty factor
μ/m3 microgram per cubic meter
UL upper limit
UMRA Unfunded Mandates Reform Act
UPL upper predictive limit
URE unit risk estimate
VOC volatile organic compounds
VOHAP volatile organic hazardous air
pollutants
WESP wet electrostatic precipitator
WHO World Health Organization
WWW worldwide Web
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Organization of this Document. The
information in this preamble is
organized as follows:
I. General Information
A. What is the statutory authority for this
action?
B. Does this action apply to me?
C. Where can I get a copy of this document
and other related information?
D. What should I consider as I prepare my
comments for EPA?
II. Background
A. Overview of the Source Category and
MACT Standards
B. What data collection activities were
conducted to support this action?
III. Analyses Performed
A. Addressing Unregulated Emissions
Sources
B. How did we estimate risks posed by the
source category?
C. How did we consider the risk results in
making decisions for this proposal?
D. How did we perform the technology
review?
E. What other issues are we addressing in
this proposal?
IV. Analyses Results and Proposed Decisions
A. What are the results of our analyses and
proposed decisions regarding
unregulated emissions sources?
B. What are the results of the risk
assessments and analyses?
C. What are our proposed decisions based
on risk acceptability and ample margin
of safety?
D. What are the results and proposed
decisions based on our technology
review?
E. What other actions are we proposing?
F. What is the relationship of the
Secondary Lead Smelting standards
proposed in today’s action and
implementation of the lead NAAQS?
G. Compliance Dates
V. Summary of Cost, Environmental, and
Economic Impacts
A. What are the affected sources?
B. What are the air quality impacts?
C. What are the cost impacts?
D. What are the economic impacts?
E. What are the benefits?
VI. Request for Comments
VII. Submitting Data Corrections
VIII. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory
Planning and Review and Executive
Order 13563: Improving Regulation and
Regulatory Review
B. Paperwork Reduction Act
C. Regulatory Flexibility Act
D. Unfunded Mandates Reform Act
E. Executive Order 13132: Federalism
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F. Executive Order 13175: Consultation
and Coordination With Indian Tribal
Governments
G. Executive Order 13045: Protection of
Children From Environmental Health
Risks and Safety Risks
H. Executive Order 13211: Actions
Concerning Regulations That
Significantly Affect Energy Supply,
Distribution, or Use
I. National Technology Transfer and
Advancement Act
J. Executive Order 12898: Federal Actions
To Address Environmental Justice in
Minority Populations and Low-Income
Populations
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I. General Information
A. What is the statutory authority for
this action?
Section 112 of the CAA establishes a
two-stage regulatory process to address
emissions of hazardous air pollutants
(HAP) from stationary sources. In the
first stage, after EPA has identified
categories of sources emitting one or
more of the HAP listed in CAA section
112(b), CAA section 112(d) calls for us
to promulgate NESHAP for those
sources. ‘‘Major sources’’ are those that
emit or have the potential to emit 10
tons per year (tpy) or more of a single
HAP or 25 tpy or more of any
combination of HAP. For major sources,
these technology-based standards must
reflect the maximum degree of
emissions reductions of HAP achievable
(after considering cost, energy
requirements, and non-air quality health
and environmental impacts) and are
commonly referred to as maximum
achievable control technology (MACT)
standards.
MACT standards must require the
maximum degree of emissions reduction
through the application of measures,
processes, methods, systems, or
techniques, including, but not limited
to, measures that (A) reduce the volume
of or eliminate pollutants through
process changes, substitution of
materials or other modifications; (B)
enclose systems or processes to
eliminate emissions; (C) capture or treat
pollutants when released from a
process, stack, storage, or fugitive
emissions point; (D) are design,
equipment, work practice, or
operational standards (including
requirements for operator training or
certification); or (E) are a combination of
the above (CAA section 112(d)(2)(A)–
(E)). The MACT standards may take the
form of design, equipment, work
practice, or operational standards where
EPA first determines either that, (A) a
pollutant cannot be emitted through a
conveyance designed and constructed to
emit or capture the pollutants, or that
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conveyance would be inconsistent with
law; or (B) the application of
measurement methodology to a
particular class of sources is not
practicable due to technological and
economic limitations (CAA sections
112(h)(1)–(2)).
The MACT ‘‘floor’’ is the minimum
control level allowed for MACT
standards promulgated under CAA
section 112(d)(3) and may not be based
on cost considerations. For new sources,
the MACT floor cannot be less stringent
than the emissions control that is
achieved in practice by the bestcontrolled similar source. The MACT
floors for existing sources can be less
stringent than floors for new sources,
but they cannot be less stringent than
the average emissions limitation
achieved by the best-performing
12 percent of existing sources in the
category or subcategory (or the bestperforming five sources for categories or
subcategories with fewer than 30
sources). In developing MACT
standards, we must also consider
control options that are more stringent
than the floor. We may establish
standards more stringent than the floor
based on considerations of the cost of
achieving the emissions reductions, any
non-air quality health and
environmental impacts, and energy
requirements.
EPA is then required to review these
technology-based standards and revise
them ‘‘as necessary (taking into account
developments in practices, processes,
and control technologies)’’ no less
frequently than every 8 years, under
CAA section 112(d)(6). In conducting
this review, EPA is not obliged to
completely recalculate the prior MACT
determination, and, in particular, is not
obligated to recalculate the MACT
floors. NRDC v. EPA, 529 F.3d 1077,
1084 (DC Cir., 2008).
The second stage in standard-setting
focuses on reducing any remaining
‘‘residual’’ risk according to CAA section
112(f). This provision requires, first, that
EPA prepare a Report to Congress
discussing (among other things)
methods of calculating the risks posed
(or potentially posed) by sources after
implementation of the MACT standards,
the public health significance of those
risks, and EPA’s recommendations as to
legislation regarding such remaining
risk. EPA prepared and submitted this
report (Residual Risk Report to
Congress, EPA–453/R–99–001) in March
1999. Congress did not act in response
to the report, thereby triggering EPA’s
obligation under CAA section 112(f)(2)
to analyze and address residual risk.
Section 112(f)(2) of the CAA requires
us to determine, for source categories
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subject to certain MACT standards,
whether those emissions standards
provide an ample margin of safety to
protect public health. If the MACT
standards that apply to a source
category emitting a HAP that is
‘‘classified as a known, probable, or
possible human carcinogen do not
reduce lifetime excess cancer risks to
the individual most exposed to
emissions from a source in the category
or subcategory to less than one-in-one
million,’’ EPA must promulgate residual
risk standards for the source category (or
subcategory) as necessary to provide an
ample margin of safety to protect public
health (CAA section 112(f)(2)(A)). This
requirement is procedural. It mandates
that EPA establish CAA section 112(f)
residual risk standards if certain risk
thresholds are not satisfied, but does not
determine the level of those standards.
NRDC v. EPA, 529 F. 3d at 1083. The
second sentence of CAA section
112(f)(2) sets out the substantive
requirements for residual risk standards:
protection of public health with an
ample margin of safety based on EPA’s
interpretation of this standard in effect
at the time of the Clean Air Act
amendments. Id. This refers to the
Benzene NESHAP, described in the next
paragraph. EPA may adopt residual risk
standards equal to existing MACT
standards if EPA determines that the
existing standards are sufficiently
protective, even if (for example) excess
cancer risks to a most exposed
individual are not reduced to less than
one-in-one million. Id. at 1083, (‘‘If EPA
determines that the existing technologybased standards provide an ‘ample
margin of safety,’ then the Agency is
free to readopt those standards during
the residual risk rulemaking’’). Section
112(f)(2) of the CAA further authorizes
EPA to adopt more stringent standards,
if necessary ‘‘to prevent, taking into
consideration costs, energy, safety, and
other relevant factors, an adverse
environmental effect.’’ 1
As just noted, CAA section 112(f)(2)
expressly preserves our use of the twostep process for developing standards to
address any residual risk and our
interpretation of ‘‘ample margin of
safety’’ developed in the National
Emissions Standards for Hazardous Air
Pollutants: Benzene Emissions From
Maleic Anhydride Plants, Ethylbenzene/
Styrene Plants, Benzene Storage Vessels,
1 ‘‘Adverse environmental effect’’ is defined in
CAA section 112(a)(7) as any significant and
widespread adverse effect, which may be
reasonably anticipated to wildlife, aquatic life, or
natural resources, including adverse impacts on
populations of endangered or threatened species or
significant degradation of environmental qualities
over broad areas.
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Benzene Equipment Leaks, and Coke
By-Product Recovery Plants (Benzene
NESHAP) (54 FR 38044, September 14,
1989). The first step in this process is
the determination of acceptable risk.
The second step provides for an ample
margin of safety to protect public health,
which is the level at which the
standards are set (unless a more
stringent standard is necessary to
prevent, taking into consideration costs,
energy, safety, and other relevant
factors, an adverse environmental
effect).
The terms ‘‘individual most exposed,’’
‘‘acceptable level,’’ and ‘‘ample margin of
safety’’ are not specifically defined in
the CAA. However, CAA section
112(f)(2)(B) preserves EPA’s
interpretation set out in the Benzene
NESHAP, and the court in NRDC v. EPA
concluded that EPA’s interpretation of
CAA section 112(f)(2) is a reasonable
one. See NRDC v. EPA, 529 F.3d at 1083
(DC Cir. 2008), which says ‘‘[S]ubsection
112(f)(2)(B) expressly incorporates
EPA’s interpretation of the Clean Air
Act from the Benzene standard,
complete with a citation to the Federal
Register.’’ See also, A Legislative History
of the Clean Air Act Amendments of
1990, volume 1, p. 877 (Senate debate
on Conference Report). We also notified
Congress in the Residual Risk Report to
Congress that we intended to use the
Benzene NESHAP approach in making
CAA section 112(f) residual risk
determinations (EPA–453/R–99–001, p.
ES–11).
In the Benzene NESHAP, we stated as
an overall objective:
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* * * in protecting public health with an
ample margin of safety, we strive to provide
maximum feasible protection against risks to
health from hazardous air pollutants by (1)
protecting the greatest number of persons
possible to an individual lifetime risk level
no higher than approximately 1-in-1 million;
and (2) limiting to no higher than
approximately 1-in-10 thousand [i.e., 100-in1 million] the estimated risk that a person
living near a facility would have if he or she
were exposed to the maximum pollutant
concentrations for 70 years.
The Agency also stated that, ‘‘The EPA
also considers incidence (the number of
persons estimated to suffer cancer or
other serious health effects as a result of
exposure to a pollutant) to be an
important measure of the health risk to
the exposed population. Incidence
measures the extent of health risks to
the exposed population as a whole, by
providing an estimate of the occurrence
of cancer or other serious health effects
in the exposed population.’’ The Agency
went on to conclude that ‘‘estimated
incidence would be weighed along with
other health risk information in judging
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acceptability.’’ As explained more fully
in our Residual Risk Report to Congress,
EPA does not define ‘‘rigid line[s] of
acceptability,’’ but rather considers
broad objectives to be weighed with a
series of other health measures and
factors (EPA–453/R–99–001, p. ES–11).
The determination of what represents an
‘‘acceptable’’ risk is based on a judgment
of ‘‘what risks are acceptable in the
world in which we live’’ (Residual Risk
Report to Congress, p. 178, quoting the
DC Circuit’s en banc Vinyl Chloride
decision at 824 F.2d 1165) recognizing
that our world is not risk-free.
In the Benzene NESHAP, we stated
that ‘‘EPA will generally presume that if
the risk to [the maximum exposed]
individual is no higher than
approximately 1-in-10 thousand, that
risk level is considered acceptable.’’ 54
FR 38045. We discussed the maximum
individual lifetime cancer risk as being
‘‘the estimated risk that a person living
near a plant would have if he or she
were exposed to the maximum pollutant
concentrations for 70 years.’’ Id. We
explained that this measure of risk ‘‘is
an estimate of the upper bound of risk
based on conservative assumptions,
such as continuous exposure for 24
hours per day for 70 years.’’ Id. We
acknowledge that maximum individual
lifetime cancer risk ‘‘does not
necessarily reflect the true risk, but
displays a conservative risk level which
is an upper-bound that is unlikely to be
exceeded.’’ Id.
Understanding that there are both
benefits and limitations to using
maximum individual lifetime cancer
risk as a metric for determining
acceptability, we acknowledged in the
1989 Benzene NESHAP that
‘‘consideration of maximum individual
risk * * * must take into account the
strengths and weaknesses of this
measure of risk.’’ Id. Consequently, the
presumptive risk level of 100-in-1
million (1-in-10 thousand) provides a
benchmark for judging the acceptability
of maximum individual lifetime cancer
risk, but does not constitute a rigid line
for making that determination.
The Agency also explained in the
1989 Benzene NESHAP the following:
‘‘In establishing a presumption for MIR
[maximum individual cancer risk],
rather than a rigid line for acceptability,
the Agency intends to weigh it with a
series of other health measures and
factors. These include the overall
incidence of cancer or other serious
health effects within the exposed
population, the numbers of persons
exposed within each individual lifetime
risk range and associated incidence
within, typically, a 50-kilometer (km)
exposure radius around facilities, the
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science policy assumptions and
estimation uncertainties associated with
the risk measures, weight of the
scientific evidence for human health
effects, other quantified or unquantified
health effects, effects due to co-location
of facilities, and co-emissions of
pollutants.’’ Id.
In some cases, these health measures
and factors taken together may provide
a more realistic description of the
magnitude of risk in the exposed
population than that provided by
maximum individual lifetime cancer
risk alone. As explained in the Benzene
NESHAP, ‘‘[e]ven though the risks
judged ‘acceptable’ by EPA in the first
step of the Vinyl Chloride inquiry are
already low, the second step of the
inquiry, determining an ‘ample margin
of safety,’ again includes consideration
of all of the health factors, and whether
to reduce the risks even further.’’ In the
ample margin of safety decision process,
the Agency again considers all of the
health risks and other health
information considered in the first step.
Beyond that information, additional
factors relating to the appropriate level
of control will also be considered,
including costs and economic impacts
of controls, technological feasibility,
uncertainties, and any other relevant
factors. Considering all of these factors,
the Agency will establish the standard
at a level that provides an ample margin
of safety to protect the public health, as
required by CAA section 112(f) (54 FR
38046).
B. Does this action apply to me?
The regulated industrial source
category that is the subject of this
proposal is listed in Table 2 of this
preamble. Table 2 of this preamble is
not intended to be exhaustive, but rather
provides a guide for readers regarding
the entities likely to be affected by this
proposed action. These standards, once
finalized, will be directly applicable to
affected sources. Federal, State, local,
and Tribal government entities are not
affected by this proposed action. As
defined in the source category listing
report published by EPA in 1992, the
Secondary Lead Smelting source
category is defined as any facility at
which lead-bearing scrap materials
(including, but not limited to lead acid
batteries) are recycled by smelting into
elemental lead or lead alloys.2 For
clarification purposes, all references to
lead emissions in this preamble mean
‘‘lead compounds’’ (which is a listed
HAP) and all references to lead
2 USEPA. Documentation for Developing the
Initial Source Category List—Final Report, USEPA/
OAQPS, EPA–450/3–91–030, July, 1992.
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production mean elemental lead (which
is not a listed HAP as provided under
CAA section 112(b)(7)).
is not a listed HAP as provided under
CAA section 112(b)(7)).
TABLE 2—NESHAP AND INDUSTRIAL SOURCE CATEGORIES AFFECTED BY THIS PROPOSED ACTION
NAICS code 1
Source category
NESHAP
Secondary Lead Smelting ........................................
Secondary Lead Smelting ........................................
331492
MACT code 2
0205
1 North
American Industry Classification System.
2 Maximum Achievable Control Technology.
jlentini on DSK4TPTVN1PROD with PROPOSALS2
C. Where can I get a copy of this
document and other related
information?
In addition to being available in the
docket, an electronic copy of this
proposal will also be available on the
World Wide Web (WWW) through the
EPA’s Technology Transfer Network
(TTN). Following signature by the EPA
Administrator, a copy of this proposed
action will be posted on the TTN’s
policy and guidance page for newly
proposed or promulgated rules at the
following address: https://www.epa.gov/
ttn/atw/rrisk/rtrpg.html. The TTN
provides information and technology
exchange in various areas of air
pollution control.
Additional information is available on
the residual risk and technology review
(RTR) Web page at: https://www.epa.gov/
ttn/atw/rrisk/rtrpg.html. This
information includes source category
descriptions and detailed emissions
estimates and other data that were used
as inputs to the risk assessments.
D. What should I consider as I prepare
my comments for EPA?
Submitting CBI. Do not submit
information containing CBI to EPA
through https://www.regulations.gov or
e-mail. Clearly mark the part or all of
the information that you claim to be
CBI. For CBI information on a disk or
CD–ROM that you mail to EPA, mark
the outside of the disk or CD–ROMas
CBI and then identify electronically
within the disk or CD–ROMthe specific
information that is claimed as CBI. In
addition to one complete version of the
comment that includes information
claimed as CBI, a copy of the comment
that does not contain the information
claimed as CBI must be submitted for
inclusion in the public docket. If you
submit a CD–ROMor disk that does not
contain CBI, mark the outside of the
disk or CD–ROMclearly that it does not
contain CBI. Information not marked as
CBI will be included in the public
docket and EPA’s electronic public
docket without prior notice. Information
marked as CBI will not be disclosed
except in accordance with procedures
set forth in 40 CFR part 2. Send or
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deliver information identified as CBI
only to the following address: Roberto
Morales, OAQPS Document Control
Officer (C404–02), Office of Air Quality
Planning and Standards, U.S.
Environmental Protection Agency,
Research Triangle Park, North Carolina
27711, Attention Docket ID Number
EPA–HQ–OAR–2011–0344.
II. Background
A. Overview of the Source Category and
MACT Standards
The NESHAP (or MACT rule) for the
Secondary Lead Smelting source
category was promulgated on June 13,
1997 (62 FR 32216) and codified at 40
CFR part 63, subpart X. As promulgated
in 1997, the NESHAP applies to affected
sources of HAP emissions at secondary
lead smelters. The 1997 NESHAP (40
CFR 63.542) defines ‘‘secondary lead
smelters’’ as ‘‘any facility at which leadbearing scrap material, primarily, but
not limited to, lead-acid batteries, is
recycled into elemental lead or lead
alloys by smelting.’’ The MACT rule for
the Secondary Lead Smelting source
category does not apply to primary lead
smelters, lead remelters, or lead refiners.
Today, there are 14 secondary lead
smelting facilities that are subject to the
MACT rule. No new secondary lead
smelters have been built in the last
20 years, and we anticipate no new
secondary lead smelting facilities in the
foreseeable future, although there is one
facility currently in the process of
expanding operations.
Lead is used to make various
construction, medical, industrial and
consumer products such as batteries,
glass, x-ray protection gear and various
fillers. The secondary lead smelting
process consists of: (1) Pre-processing of
lead bearing materials, (2) melting lead
metal and reducing lead compounds to
lead metal in the smelting furnace, and
(3) refining and alloying the lead to
customer specifications.
HAP are emitted from secondary lead
smelting as process emissions, process
fugitive emissions, and fugitive dust
emissions. Process emissions are the
exhaust gases from feed dryers and from
blast, reverberatory, rotary, and electric
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furnaces. The HAP in process emissions
are primarily composed of metals
(mostly lead compounds, but also some
arsenic, cadmium, and other metals)
and also may include organic
compounds that result from incomplete
combustion of coke that is charged to
the smelting furnaces as a fuel or fluxing
agent or from fuel natural gas and/or
small amounts of plastics or other
materials that get fed into the furnaces
along with the lead bearing materials.
Process fugitive emissions occur at
various points during the smelting
process (such as during charging and
tapping of furnaces) and are composed
primarily of metal HAP. Fugitive dust
emissions result from the entrainment of
HAP in ambient air due to material
handling, vehicle traffic, wind erosion
from storage piles, and other various
activities. Fugitive dust emissions are
composed of metal HAP only.
The MACT rule applies to process
emissions from blast, reverberatory,
rotary, and electric smelting furnaces,
agglomerating furnaces, and dryers;
process fugitive emissions from
smelting furnace charging points,
smelting furnace lead and slag taps,
refining kettles, agglomerating furnace
product taps, and dryer transition
pieces; and fugitive dust emissions
sources such as roadways, battery
breaking areas, furnace charging and
tapping areas, refining and casting areas,
and material storage areas. For process
sources, the NESHAP specifies
numerical emissions limits for lead
compounds (as a surrogate for metal
HAP) for the following types of smelting
furnaces: (1) Collocated reverberatory
and blast furnaces (reverberatory/blast),
(2) blast furnaces, and (3) reverberatory
furnaces not collocated with blast
furnaces, rotary furnaces, and electric
furnaces. Lead compound emissions
from all smelting furnace configurations
are limited to an outlet concentration of
2.0 milligrams per dry standard cubic
meter (mg/dscm) (0.00087 grains per dry
standard cubic foot (gr/dscf)), 40 CFR
63.543(a). Total hydrocarbon (THC)
emissions (as a surrogate for organic
HAP) from existing and new collocated
reverberatory/blast furnace
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configurations are limited to an outlet
concentration of 20 parts per million
volume (ppmv) (expressed as propane)
corrected to 4 percent carbon dioxide
(CO2) to account for dilution. THC
emissions are limited to 360 ppmv (as
propane) at 4 percent CO2 from existing
blast furnaces and 70 ppmv (as propane)
at 4 percent CO2 from new blast
furnaces (40 CFR 63.543(c)). The
NESHAP does not specify emissions
limits for THC emissions from
reverberatory furnaces not collocated
with blast furnaces, rotary furnaces, and
electric furnaces.
The 1997 NESHAP requires that
process fugitive emissions sources be
equipped with an enclosure hood
meeting minimum face velocity
requirements or be located in a total
enclosure subject to general ventilation
that maintains the building at negative
pressure (40 CFR 63.543(b)). Ventilation
air from the enclosure hoods and total
enclosures is required to be conveyed to
a control device. Lead emissions from
these control devices are limited to 2.0
mg/dscm (0.00087 gr/dscf) (40 CFR
63.544(c)). Lead emissions for all dryer
emissions vents and agglomerating
furnace vents are limited to 2.0 mg/
dscm (0.00087 gr/dscf) (40 CFR
63.544(d)). The 1997 NESHAP also
requires the use of bag leak detection
systems (BLDS) for continuous
monitoring of baghouses in cases where
a high efficiency particulate air (HEPA)
filter was not used in series with a
baghouse (40 CFR 63.548(c)(9)).
For fugitive dust sources, as defined
in 40 CFR 63.545, the 1997 NESHAP
requires that the smelting process and
all control devices be operated at all
times according to a standard operating
procedures (SOP) manual developed by
the facility. The SOP manual is required
to describe, in detail, the measures used
to control fugitive dust emissions from
plant roadways, battery breaking areas,
furnace areas, refining and casting areas,
and material storage and handling areas.
B. What data collection activities were
conducted to support this action?
In June 2010, EPA issued an
information collection request (ICR),
pursuant to CAA section 114, to six
companies that own and operate the 14
secondary lead smelting facilities. The
ICR requested available information
regarding process equipment, control
devices, point and fugitive emissions,
practices used to control fugitive
emissions, and other aspects of facility
operations. The six companies
completed the surveys for their facilities
and submitted the responses to us in the
fall of 2010. In addition to the ICR
survey, each facility was asked to
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submit reports for any emissions tests
conducted in 2003 or later. We received
lead emissions test data from all 14
facilities with some facilities submitting
data for multiple years. Additionally,
EPA requested that eight facilities
conduct additional emissions tests in
2010 for certain HAP from specific
processes that were considered
representative of the industry.
Pollutants tested included most HAP
metals, dioxins and furans, and certain
organic HAP. The results of these tests
were submitted to EPA in the fall of
2010 and are available in the docket for
this action.
III. Analyses Performed
In this section we describe the
analyses performed to support the
proposed decisions for the RTR for this
source category.
A. Addressing Unregulated Emissions
Sources
In the course of evaluating the
Secondary Lead Smelting source
category, we identified certain HAP for
which we failed to establish emission
standards in the original MACT. See
National Lime v. EPA, 233 F. 3d 625,
634 (DC Cir. 2000) (EPA has ‘‘clear
statutory obligation to set emissions
standards for each listed HAP’’).
Specifically, we evaluated emissions
standards for three HAP (or groups of
HAP), described below, that are not
specifically regulated in the existing
1997 MACT standard, or are only
regulated for certain emissions points.
As described below, for two of these
groups of HAP (i.e., organic HAP and
dioxins and furans) we are proposing
emissions limits pursuant to 112(d)(2)
and 112(d)(3). For the other HAP
(mercury compounds), we are proposing
standards based on work practices
pursuant to 112(h). The results and
proposed decisions based on the
analyses performed pursuant to CAA
section 112(d)(2), 112(d)(3), and 112(h)
are presented in Section IV.A of this
preamble.
1. Organic HAP
EPA did not establish standards for
organic HAP emitted from reverberatory
furnaces not collocated with blast
furnaces, rotary furnaces, and electric
furnaces in the 1997 NESHAP. EPA is
therefore proposing to set emissions
limits for organic HAP emissions from
these furnace configurations in today’s
action based on emissions data received
in response to the ICR.
2. Mercury
The 1997 NESHAP specified
emissions limits for metal HAP (e.g.,
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arsenic, cadmium, lead) in terms of a
lead emissions limit (i.e., lead is used as
a surrogate for metal HAP). There is no
explicit standard for mercury and we
are therefore proposing a standard
pursuant to section 112 (as described
further in section IV.A of this preamble).
3. Dioxins and Furans
Lastly, with regard to dioxin and
furan emissions, because the 1997
NESHAP did not include emissions
limits, we are proposing emissions
standards for dioxins and furans
pursuant to CAA section 112(d)(3). We
are also proposing work practices for
dioxins and furans.
B. How did we estimate risks posed by
the source category?
EPA conducted a risk assessment that
provided estimates of the maximum
individual cancer risk (MIR) posed by
the HAP emissions from the 14 sources
in the source category, the distribution
of cancer risks within the exposed
populations, total cancer incidence,
estimates of the maximum target organspecific hazard index (TOSHI) for
chronic exposures to HAP with the
potential to cause chronic non-cancer
health effects, worst-case screening
estimates of hazard quotients (HQ) for
acute exposures to HAP with the
potential to cause non-cancer health
effects, and an evaluation of the
potential for adverse environmental
effects. In June of 2009, the EPA’s
Science Advisory Board (SAB)
conducted a formal peer review of our
risk assessment methodologies in its
review of the document entitled, ‘‘Risk
and Technology Review (RTR)
Assessment Methodologies’’.3 We
received the final SAB report on this
review in May of 2010.4 Where
appropriate, we have responded to the
key messages from this review in
developing the current risk assessment;
we will be continuing our efforts to
improve our assessments by
incorporating updates based on the SAB
recommendations as they are developed
and become available. The risk
assessment consisted of seven primary
steps, as discussed below.
The docket for this rulemaking
contains the following document, which
provides more information on the risk
3 U.S. EPA, 2009. Risk and Technology Review
(RTR) Risk Assessment Methodologies: For Review
by the EPA’s Science Advisory Board with Case
Studies—MACT I Petroleum Refining Sources and
Portland Cement Manufacturing. EPA–452/R–09–
006. https://www.epa.gov/ttn/atw/rrisk/rtrpg.html.
4 U.S. EPA, 2010. SAB’s Response to EPA’s RTR
Risk Assessment Methodologies. https://
yosemite.epa.gov/sab/sabproduct.nsf/
4AB3966E263D943A8525771F00668381/$File/EPASAB-10-007-unsigned.pdf.
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assessment inputs and models: Draft
Residual Risk Assessment for the
Secondary Lead Smelting Source
Category.
1. Establishing the Nature and
Magnitude of Actual Emissions and
Identifying the Emissions Release
Characteristics
For each facility in the Secondary
Lead Smelting source category, we
compiled an emissions profile
(including emissions estimates, stack
parameters, and location data) based on
the information provided by the
industry in the ICR, the emissions test
data, various calculations, and the NEI.
The site-specific emissions profiles
include annual estimates of process,
process fugitive, and fugitive dust
emissions for the 2008–2010 timeframe,
as well as emissions release
characteristics such as emissions release
height, temperature, velocity, and
location coordinates.
The primary risk assessment is based
on estimates of the actual emissions
(though we also analyzed allowable
emissions and the potential risks due to
allowable emissions). We received a
substantial amount of emissions test
data and other information that enabled
us to derive estimates of stack emissions
of certain HAP for all of the facilities.
However, we did not have test data for
all pollutants at all emissions points.
Therefore, we estimated emissions of
some pollutants from certain emissions
points (for which we had no emissions
data) using test data from similar source
types with similar controls.
With regard to fugitive emissions,
because they cannot be readily captured
or directly measured, fugitive emissions
are a more challenging emissions type to
estimate. In 2010, as part of an
information collection request (ICR),
EPA asked the Secondary Lead industry
to provide their best estimate of the
emissions from fugitive sources (e.g.,
building openings, raw material storage
piles, roadways, parking areas) at their
facilities and to provide a description of
the basis for the estimates (e.g., test data,
emissions factors, mass balance
calculations, engineering judgment). For
our analysis of fugitive emissions for the
source category, we first reviewed and
evaluated the estimates of fugitive lead
emissions that were submitted by each
of the facilities in response to the 2010
ICR to determine the reliability and
appropriateness of those estimates as an
input to our risk analyses and other
assessments. We concluded that there
were significant gaps and incomplete
documentation for a number of
facilities, a large amount of variability in
estimates between the facilities, and
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various significant uncertainties. For
example, five facilities did not provide
any estimates of fugitive emissions,
while a few other facilities provided
emissions estimates that were quite
incomplete. Thus, we developed
estimates of fugitive emissions for all
facilities in the source category based on
a methodology described in the
emissions development technical
document (Draft Development of the
RTR Emissions Dataset for the
Secondary Lead Smelting Source
Category) for this rulemaking, which is
available in the docket. In this
methodology, we began with estimates
provided by one facility in the ICR
which were well-documented and
covered all the various fugitive
emissions sources expected at these
facilities. Using the ICR responses, other
available information on fugitive
emissions (including scientific
literature), and various assumptions and
calculations, we scaled these estimates
to derive site-specific fugitive emissions
estimates at each of the other 13
facilities. The estimates calculated using
this methodology were used as inputs to
the risk assessment modeling.
The results of the risk assessment
modeling (which are described further
in section IV below) indicated that the
fugitive dust emissions were the largest
contributor to the risks due to lead
emissions. The impacts of fugitive
emissions were generally considerably
greater than the impacts due to stack
emissions. Because of these impacts,
and because of the difficulties and
uncertainties associated with estimating
fugitive emissions, we decided to do
further analyses and review of the
fugitive emissions estimates as a quality
assurance check on the initial fugitive
emissions estimates. Therefore, we
consulted further with industry
representatives, gathered additional
information from the EPA’s Toxics
Release Inventory, evaluated the ICR
responses further, and performed
various other analyses, which led to the
development of an alternative set of
fugitive emissions estimates based on a
slightly different methodology. The total
fugitive estimates of lead for the
industry calculated based on the
alternative approach are within
10 percent of our initial estimates. We
did not rerun the model with the
alternative estimates because we know
that the overall results would be quite
similar and would not change our
overall conclusions and decisions
(described later in this notice). Further
details on all the emissions data,
calculations, estimates, and
uncertainties, are in the emissions
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technical document (Draft Development
of the RTR Emissions Dataset for the
Secondary Lead Smelting Source
Category) which is available in the
docket for this action. We are seeking
comments on our emissions data and
estimates, and the fugitive emissions
estimation methodologies and any other
potential appropriate methods or data
that could be used to estimate fugitive
emissions from these facilities.
2. Establishing the Relationship
Between Actual Emissions and MACT–
Allowable Emissions Levels
The emissions data in our data set are
estimates of actual emissions on an
annual basis for stacks and fugitives for
the 2008–2010 timeframe. With most
source categories, we generally find that
‘‘actual’’ emissions levels are lower than
the emissions levels that a facility is
allowed to emit under the MACT
standards. The emissions levels allowed
to be emitted by the MACT standards
are referred to as the ‘‘MACT-allowable’’
emissions levels. This represents the
highest emissions level that could be
emitted by facilities without violating
the MACT standards.
As we have discussed in prior
residual risk and technology review
rules, assessing the risks at the MACTallowable level is inherently reasonable
since these risks reflect the maximum
level at which sources could emit while
still complying with the MACT
standards. However, we also explained
that it is reasonable to consider actual
emissions, where such data are
available, in both steps of the risk
analysis, in accordance with the
Benzene NESHAP (54 FR 38044,
September 14, 1989). It is reasonable to
consider actual emissions because
sources typically seek to perform better
than required by emissions standards to
provide an operational cushion to
accommodate the variability in
manufacturing processes and control
device performance. Facilities’ actual
emissions may also be significantly
lower than MACT-allowable emissions
for other reasons such as State
requirements, better performance of
control devices than required by the
MACT standards, or reduced
production.
For the Secondary Lead Smelting
source category, we evaluated actual
and allowable emissions for both stack
emissions and fugitive dust emissions.
As described earlier in this section, the
actual emissions data for this source
category were compiled based on the
ICR responses, available test data,
various calculations, and the NEI. We
estimated actual emissions for all HAP
that we identified in the dataset. The
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analysis of allowable emissions was
largely focused on lead compound
emissions, which we considered the
most important HAP emitted from this
source category based on our screening
level risk assessment and the HAP for
which we had the most data. However,
we also considered allowable emissions
for other HAP.
With regard to fugitive emissions,
because there are no numerical
emissions limits, and because all
facilities are required to implement
identical fugitive emissions control
work-practices, we assume that the
allowable fugitive emissions from this
source category are equal to the actual
emissions.
To estimate emissions at the MACTallowable level from stacks (e.g.,
process, process fugitive, and building
vents), we estimated the emissions that
would occur if facilities were
continuously emitting lead at the
maximum allowed by the existing
MACT standard (i.e., 2.0 mg/dscm) from
all vents. We then compared these
estimated allowable emissions to the
estimated emissions using the actual
stack test data for each facility. We
realize that these estimates of allowable
emissions are theoretical high-end
estimates as facilities must maintain
average emissions levels at some level
below the MACT limit to ensure
compliance with the standard at all
times because of the day-to-day
variability in emissions. Nevertheless,
these high-end estimates of allowable
emissions were adequate for us to
estimate the magnitude of allowable
emissions and the differences between
the estimates of actual emissions and
the MACT allowable emissions.
Based on this analysis, we conclude
that all facilities are emitting lead at
levels lower than allowable; however,
the range of differences between actual
and allowable is significant. For two
facilities, the estimated actual emissions
were only moderately lower than
allowable (about 2–3 times lower). The
majority of other facilities have
estimated actual emissions in the range
of 10 to 100 times lower than allowable.
Finally, one facility, which has highly
advanced controls, has estimated actual
emissions of about 1,500 times below
the MACT allowable emissions level.
We then developed a ratio of MACTallowable to actual emissions for each
facility in the source category. After
developing these ratios, we applied
them on a facility-by-facility basis to the
maximum modeled ambient lead
concentrations to estimate the
maximum ambient concentrations that
would occur if all stacks were emitting
at maximum allowable levels. The ratios
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were applied to stack emissions while
leaving fugitive dust emissions at actual
levels since, as described above, actual
fugitive dust emissions were assumed to
be equal to allowable fugitive dust
emissions. The estimates of MACTallowable emissions are described
further in the technical document: Draft
Development of the RTR Emissions
Dataset for the Secondary Lead
Smelting Source Category. The
estimates of risks due to allowable
emissions are summarized in Section
IV.B of this preamble and described
further in the draft risk report: Draft
Residual Risk Assessment for the
Secondary Lead Smelting Source
Category.
3. Conducting Dispersion Modeling,
Determining Inhalation Exposures, and
Estimating Individual and Population
Inhalation Risks
Both long-term and short-term
inhalation exposure concentrations and
health risks from the source category
addressed in this proposal were
estimated using the Human Exposure
Model (Community and Sector HEM–3
version 1.1.0). The HEM–3 performs
three of the primary risk assessment
activities listed above: (1) Conducting
dispersion modeling to estimate the
concentrations of HAP in ambient air,
(2) estimating long-term and short-term
inhalation exposures to individuals
residing within 50 km of the modeled
sources, and (3) estimating individual
and population-level inhalation risks
using the exposure estimates and
quantitative dose-response information.
The dispersion model used by HEM–
3 is AERMOD, which is one of EPA’s
preferred models for assessing pollutant
concentrations from industrial
facilities.5 To perform the dispersion
modeling and to develop the
preliminary risk estimates, HEM–3
draws on three data libraries. The first
is a library of meteorological data,
which is used for dispersion
calculations. This library includes 1
year of hourly surface and upper air
observations for 130 meteorological
stations, selected to provide coverage of
the United States and Puerto Rico. A
second library, of United States Census
Bureau census block 6 internal point
locations and populations, provides the
basis of human exposure calculations
based on the year 2000 U.S. Census. In
addition, for each census block, the
5 U.S. EPA. Revision to the Guideline on Air
Quality Models: Adoption of a Preferred General
Purpose (Flat and Complex Terrain) Dispersion
Model and Other Revisions (70 FR 68218,
November 9, 2005).
6 A census block is the smallest geographic area
for which census statistics are tabulated.
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census library includes the elevation
and controlling hill height, which are
also used in dispersion calculations. A
third library of pollutant unit risk
factors and other health benchmarks is
used to estimate health risks. These risk
factors and health benchmarks are the
latest values recommended by EPA for
HAP and other toxic air pollutants.
These values are available at https://
www.epa.gov/ttn/atw/toxsource/
summary.html and are discussed in
more detail later in this section.
In developing the risk assessment for
chronic exposures, we used the
estimated annual average ambient air
concentrations of each of the HAP
emitted by each source for which we
have emissions data in the source
category. The air concentrations at each
nearby census block centroid were used
as a surrogate for the chronic inhalation
exposure concentration for all the
people who reside in that census block.
We calculated the MIR for the facilities
as the cancer risk associated with a
lifetime (70-year period) of exposure to
the maximum concentration at the
centroid of inhabited census blocks.
Individual cancer risks were calculated
by multiplying the estimated lifetime
exposure to the ambient concentration
of each of the HAP (in micrograms per
cubic meter) by its unit risk estimate
(URE), which is an upper bound
estimate of an individual’s probability
of contracting cancer over a lifetime of
exposure to a concentration of 1
microgram of the pollutant per cubic
meter of air. In general, for residual risk
assessments, we use URE values from
EPA’s Integrated Risk Information
System (IRIS). For carcinogenic
pollutants without EPA IRIS values, we
look to other reputable sources of cancer
dose-response values, often using
California Environmental Protection
Agency (CalEPA) URE values, where
available. In cases where new,
scientifically credible dose response
values have been developed in a manner
consistent with EPA guidelines and
have undergone a peer review process
similar to that used by EPA, we may use
such dose-response values in place of,
or in addition to, other values, if
appropriate. For this review, URE values
and their sources (e.g., IRIS, CalEPA)
can be found in Table 2.6–1(a) in the
risk assessment document entitled,
Draft Residual Risk Assessment for the
Secondary Lead Smelting Source
Category, which is available in the
docket for this proposed rulemaking.
Incremental individual lifetime
cancer risks associated with emissions
from the 14 facilities in the source
category were estimated as the sum of
the risks for each of the carcinogenic
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HAP (including those classified as
carcinogenic to humans, likely to be
carcinogenic to humans, and suggestive
evidence of carcinogenic potential 7)
emitted by the modeled source. Cancer
incidence and the distribution of
individual cancer risks for the
population within 50 km of the sources
were also estimated for the source
category as part of these assessments by
summing individual risks. A distance of
50 km is consistent with both the
analysis supporting the 1989 Benzene
NESHAP (54 FR 38044) and the
limitations of Gaussian dispersion
models, including AERMOD.
To assess the risk of non-cancer
health effects from chronic exposures,
we summed the HQ for each of the HAP
that affects a common target organ
system to obtain the HI for that target
organ system (or target organ-specific
HI, TOSHI). The HQ is the estimated
exposure divided by the chronic
reference value, which is either the EPA
RfC, defined as ‘‘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,’’ or, in cases where an
RfC is not available, the Agency for
Toxic Substances and Disease Registry
(ATSDR) chronic Minimal Risk Level
(MRL) or the CalEPA Chronic Reference
Exposure Level (REL). Notably, the REL
is defined as ‘‘the concentration level at
or below which no adverse health
effects are anticipated for a specified
exposure duration.’’
Worst-case screening estimates of
acute exposures and risks were also
evaluated for each of the HAP at the
point of highest off-site exposure for
each facility (i.e., not just the census
block centroids) assuming that a person
was located at this spot at a time when
both the peak (hourly) emissions rate
and worst-case hourly dispersion
conditions occurred. In general, acute
HQ values were calculated using best
available, short-term dose-response
values. These acute dose-response
7 These classifications also coincide with the
terms ‘‘known carcinogen, probable carcinogen, and
possible carcinogen,’’ respectively, which are the
terms advocated in the EPA’s previous Guidelines
for Carcinogen Risk Assessment, published in 1986
(51 FR 33992, September 24, 1986). Summing the
risks of these individual compounds to obtain the
cumulative cancer risks is an approach that was
recommended by the EPA’s Science Advisory Board
(SAB) in their 2002 peer review of EPA’s NATA
entitled, NATA—Evaluating the National-scale Air
Toxics Assessment 1996 Data—an SAB Advisory,
available at: https://yosemite.epa.gov/sab/
sabproduct.nsf/
214C6E915BB04E14852570CA007A682C/$File/
ecadv02001.pdf.
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values include REL, Acute Exposure
Guideline Levels (AEGL), and
Emergency Response Planning
Guidelines (ERPG) for 1-hour exposure
durations. Notably, for HAP emitted
from this source category, REL values
were the only such dose-response
values available. As discussed below,
we used conservative assumptions for
emissions rates, meteorology, and
exposure location for our acute analysis.
As described in the CalEPA’s Air
Toxics Hot Spots Program Risk
Assessment Guidelines, Part I, The
Determination of Acute Reference
Exposure Levels for Airborne Toxicants,
an acute REL value (https://
www.oehha.ca.gov/air/pdf/acuterel.pdf)
is defined as ‘‘the concentration level at
or below which no adverse health
effects are anticipated for a specified
exposure duration.’’ REL values are
based on the most sensitive, relevant,
adverse health effect reported in the
medical and toxicological literature.
REL values are designed to protect the
most sensitive individuals in the
population by the inclusion of margins
of safety. Since margins of safety are
incorporated to address data gaps and
uncertainties, exceeding the REL does
not automatically indicate an adverse
health impact.
To develop screening estimates of
acute exposures, we first developed
estimates of maximum hourly emissions
rates by multiplying the average actual
annual hourly emissions rates by a
factor to cover routinely variable
emissions. We chose the factor to use
based on process knowledge and
engineering judgment and with
awareness of a Texas study of short-term
emissions variability, which showed
that most peak emissions events, in a
heavily-industrialized 4-county area
(Harris, Galveston, Chambers, and
Brazoria Counties, Texas) were less than
twice the annual average hourly
emissions rate. The highest peak
emissions event was 74 times the
annual average hourly emissions rate,
and the 99th percentile ratio of peak
hourly emissions rate to the annual
average hourly emissions rate was 9.8
This analysis is provided in Appendix
4 of the Draft Residual Risk Assessment
for Secondary Lead Smelting that is
available in the docket for this action.
Considering this analysis, unless
specific process knowledge or data are
available to provide an alternate value,
to account for more than 99 percent of
the peak hourly emissions, we generally
apply the assumption to most source
8 See https://www.tceq.state.tx.us/compliance/
field_ops/eer/ or docket to access the
source of these data.
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categories that the maximum one-hour
emissions rate from any source other
than those resulting in fugitive dust
emissions are 10 times the average
annual hourly emissions rate for that
source. We use a factor other than 10 in
some cases if we have information that
indicates that a different factor is
appropriate for a particular source
category. Moreover, the factor of 10 is
not applied to fugitive dust sources
because these emissions are minimized
during the meteorological conditions
associated with the worst-case shortterm impacts (i.e., during low-wind,
stable atmospheric conditions) in these
acute exposure screening assessments.
In cases where all worst-case acute
HQ values from the screening step were
less than or equal to 1, acute impacts
were deemed negligible and no further
analysis was performed. In the cases
where any worst-case acute HQ from the
screening step was greater than 1,
additional site-specific data were
considered to develop a more refined
estimate of the potential for acute
impacts of concern. Ideally, we would
prefer to have continuous measurements
over time to see how the emissions vary
by each hour over an entire year. Having
a frequency distribution of hourly
emissions rates over a year would allow
us to perform a probabilistic analysis to
estimate potential threshold
exceedances and their frequency of
occurrence. Such an evaluation could
include a more complete statistical
treatment of the key parameters and
elements adopted in this screening
analysis. However, we recognize that
having this level of data is rare, hence
our use of the multiplier (i.e., factor of
10) approach in our screening analysis.
In the case of this source category, we
had no further information on peak-tomean emissions which could be used to
refine the estimates. The only
refinement that was made to the acute
screening assessments was to ensure
that the estimated worst-case HQ was
not calculated at a location within the
facility boundaries.
4. Conducting Multipathway Exposure
and Risk Modeling
EPA evaluated the potential for
significant human health risks due to
exposures via routes other than
inhalation (i.e., multipathway
exposures) and the potential for adverse
environmental impacts in a three-step
process. In the first step, we determined
whether any facilities emitted any HAP
known to be persistent and bioaccumulative in the environment
(PB–HAP). There are 14 PB–HAP
compounds or compound classes
identified for this screening in EPA’s Air
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Toxics Risk Assessment Library
(available at https://www.epa.gov/ttn/
fera/risk_atra_vol1.html).
Emissions of five PB–HAP were
identified in the emissions dataset for
the Secondary Lead Smelting source
category, as follows: Lead compounds,
cadmium compounds, POM, dioxin and
furans, and mercury.9 The dataset is
described in the emissions technical
document (Draft Development of the
RTR Emissions Dataset for the
Secondary Lead Smelting Source
Category) which is available in the
docket for this action. As described in
that document, lead emissions estimates
are based on multiple emission stack
tests conducted over multiple years,
cadmium and dioxin and furans are
based on emissions tests conducted in
2010. Mercury emissions estimates are
based on test results in 2010 which
included a large number of non-detects
and conservative assumptions about
non-detects, and the estimates for POM
are based on reported estimates from the
NEI or estimates provided by the
companies in the ICR responses in 2010.
Emissions of cadmium compounds,
POM, dioxin and furans and mercury
were evaluated for potential noninhalation risks and adverse
environmental impacts using our
recently developed screening scenario
that was developed for use with the
Total Risk Integrated Methodology
(TRIM.FaTE) model. This screening
scenario uses environmental media
outputs from the peer-reviewed
TRIM.FaTE to estimate the maximum
potential ingestion risks for any
specified emissions scenario by using a
generic farming/fishing exposure
scenario that simulates a subsistence
environment. The screening scenario
retains many of the ingestion and
scenario inputs developed for EPA’s
Human Health Risk Assessment
Protocols (HHRAP) for hazardous waste
combustion facilities. In the
development of the screening scenario,
a sensitivity analysis was conducted to
ensure that its key design parameters
were established such that
environmental media concentrations
were not underestimated, and to also
minimize the occurrence of false
positives for human health endpoints.
See Appendix 3 of the risk assessment
9 Most of the emissions test results for mercury
emissions for this industry were below detection
limit. The emissions estimates used in the risk
assessment are based on the assumption that all the
non-detect test values were at the level of the
detection limit. Therefore, these estimated
emissions for mercury are clear overestimates. We
conclude that the true amounts of emissions of
mercury from this source category are much lower
than shown in this assessment, but we are not able
to quantify precisely how much lower.
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document for a complete discussion of
the development and testing of the
screening scenario, as well as for the
values of facility-level de minimis
emissions rates developed for screening
potentially significant multipathway
impacts. For the purpose of developing
de minimis emissions rates for our
multipathway screening, we derived
emissions levels at which the maximum
human health risk could be 1-in-1
million for lifetime cancer risk, or
exposures could potentially be above
the reference dose for non-cancer
effects, based on a conservative model
plant analysis described in Appendix 3
of the risk assessment document.
For the secondary lead smelting
source category, there were exceedances
of de minimis emissions rates at
multiple facilities for multiple PB–HAP,
and thus a multipathway analysis was
performed. Two facilities were chosen
as case study analyses to assess
potential multipathway risks for
mercury, cadmium, POM, and dioxins
and furans. The selection criteria for
modeling these two facilities included
emissions rates of PB–HAPs, proximity
to water bodies, proximity to farmland,
average rainfall, average wind speed and
direction, smelting furnace type, local
change in elevation, and geographic
representativeness of sites throughout
the U.S. As a result of our selection
process, we believe the multipathway
risks associated with these two facilities
are in the upper end of the potential for
multipathway risks from the source
category. Since the modeling used in
these case study assessments utilize site
specific parameters to describe naturally
occurring physical, chemical and
biological processes, we believe that the
multimedia concentrations of PB–HAPs
generated in this analysis are unbiased
estimates of the true impacts.
In general, results of this assessment
were designed to characterize
multipathway risks associated with high
end consumption of PB–HAP
predominantly from contaminated food
sources. Thus, multipathway exposure
and risk estimates were calculated for
two basic scenarios, both of which are
expected to give rise to high-end
exposures and risks. The farmer
scenario involves an individual living
on a farm homestead in the vicinity of
a PB–HAP source who consumes
contaminated produce grown on the
farm, as well as contaminated meat and
animal products raised on the farm. The
farming scenario also accounts for
incidental ingestion of contaminated
surface soil at the location of the farm
homestead. The recreational fisher
scenario involves an individual who
regularly consumes fish caught in
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freshwater lakes in the vicinity of a PB–
HAP source. In the fishing scenario, in
addition to the characterization of
exposure and risks across the broad
population of recreational anglers,
exposures were also calculated for three
subpopulations of recreational anglers
(Hispanic, Laotian, and Vietnamese
descent) who have higher rates of fish
consumption.10 Furthermore, in order to
more fully characterize the modeled
potential multipathway risks that may
be associated with high-end
consumption of PB–HAP contaminated
food, we present results based on two
ingestion exposure scenarios: (1) A
reasonable maximum exposure (RME)
scenario that, for example, utilizes 90th
percentile ingestion rates for farmers,
recreational anglers, and the three
subpopulations of recreational anglers
(e.g., ingestion rates specific to Laotian
recreational anglers); and (2) a central
tendency exposure (CTE) scenario that,
for example, utilizes mean ingestion
rates for the groups just described. We
provide results from both scenarios to
illustrate the range of potential modeled
exposures and risks that may exist in
the high-end of the complete
distribution of potential multipathway
risks for this source category.
In evaluating the potential air-related
multipathway risks from the emissions
of lead compounds, rather than
developing a de minimis emissions rate,
we compared its maximum modeled
3-month average atmospheric lead
concentration at any off-site location
with the current primary National
Ambient Air Quality Standard (NAAQS)
for lead (promulgated in 2008), which is
set at a level of 0.15 micrograms per
cubic meter (μg/m3) based on rolling
3-month periods with a not-to-beexceeded level for any 3-month rolling
average, and which will require
attainment by 2016 (73 FR 66964).
Notably, in making these comparisons,
we estimated maximum rolling 3-month
ambient lead concentrations taking into
account all of the elements of the
NAAQS for lead. That is, our estimated
3-month lead concentrations are
10 In both scenarios, exposure via drinking water
was not considered because it is unlikely that
humans would use surface waters as a drinking
water source. Groundwater, which is a likely source
of drinking water, also was not included in the
exposure scenarios because contamination of
groundwater aquifers by air deposition sources was
not expected to be significant. For dioxin, exposure
via breast milk was considered in the farming
scenario as well as the recreational fishing scenario,
but not for the three recreational fishing
subpopulations (Hispanic, Laotian, and Vietnamese
descent) since subpopulation ingestion rates were
only applicable to adult males. The breast milk
pathway was not considered with respect to
mercury exposure due to a current lack of data
regarding this pathway.
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calculated in a manner that is consistent
with the indicator, averaging time, and
form of the lead NAAQS, and those
estimates are compared to the level of
the lead NAAQS (0.15 μg/m3).
The NAAQS value, a public health
policy judgment, incorporated the
Agency’s most recent health evaluation
of air effects of lead exposure for the
purposes of setting a national standard.
In setting this value, the Administrator
promulgated a standard that was
requisite to protect public health with
an adequate margin of safety. That
standard applies everywhere, under all
circumstances, regardless of an
individual’s location, exposure patterns,
or health circumstances. We consider
values below the level of the primary
NAAQS to protect against multipathway
risks because, as mentioned above, the
primary NAAQS is set so as to protect
public health with an adequate margin
of safety. However, ambient air lead
concentrations above the NAAQS are
considered to pose the potential for
increased risk to public health. We
consider this assessment—comparing
modeled concentrations to the level of
the NAAQS—to be a refined analysis
given: (1) The numerous health studies,
detailed risk and exposure analyses, and
level of external peer and public review
that went into the development of the
primary NAAQS for lead, combined
with: (2) the site-specific dispersion
modeling performed in the risk
assessment to develop ambient
concentration estimates from the 14
secondary lead smelter facilities
addressed in this proposed rule. It
should be noted, however, that this
comparison to the NAAQS for lead does
not account for possible population
exposures to lead from sources other
than the one being modeled; for
example, via consumption of water from
contaminated local sources or ingestion
of contaminated locally grown food.
Nevertheless, the Administrator judged
that the primary NAAQS would protect,
with an adequate margin of safety, the
health of children and other at-risk
populations against an array of adverse
health effects, most notably including
neurological effects, particularly
neurobehavioral and neurocognitive
effects, in children (73 FR 67007). The
Administrator, in setting the standard,
also recognized that no evidence of a
risk-based bright line indicated a single
appropriate level. Instead, a collection
of scientific evidence and other
information was used to select the
standard from a range of reasonable
values (73 FR 67006).
We further note that comparing
ambient lead concentrations to the
NAAQS for lead, considering the level,
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averaging time, form and indicator of
the lead NAAQS, also informs whether
there is the potential for adverse
environmental effects. This is because
the secondary lead NAAQS, which has
the same averaging time, form, and level
as the primary standard, was set to
protect the public welfare which
includes among other things soils,
water, crops, vegetation and wildlife
(CAA section 302(h)). Thus, ambient
lead concentrations above the NAAQS
for lead also indicate the potential for
adverse environmental effects (73 FR
67007 to 67012). For additional
information on the multipathway
analysis approach, see the residual risk
documentation as referenced in Section
III.A of this preamble. EPA solicits
comment generally on the modeling
approach used herein to assess airrelated lead risks, and specifically on
the use of the lead NAAQS in this
analytical construct.
5. Assessing Risks Considering
Emissions Control Options
In addition to assessing baseline
inhalation risks and screening for
potential multipathway risks, we also
estimated risks considering the potential
emissions reductions that would be
achieved by the main control options
under consideration. The expected
emissions reductions were applied to
the specific HAP and emissions points
in the source category dataset to develop
corresponding estimates of risk
reductions. More information regarding
the risks after control can be found in
the risk assessment document: Draft
Residual Risk Assessment for the
Secondary Lead Smelting Source
Category, which is available in the
docket for this action.
6. Conducting Other Risk-Related
Analyses, Including Facility-Wide
Assessments and Demographic Analyses
a. Facility-Wide Risk
To put the source category risks in
context, for our residual risk review, we
also examine the risks from the entire
‘‘facility,’’ where the facility includes all
HAP-emitting operations within a
contiguous area and under common
control. In other words, we examine the
HAP emissions not only from the source
category of interest, but also emissions
of HAP from all other emissions sources
at the facility. In this rulemaking, for the
Secondary Lead Smelting source
category, there are no other significant
HAP emissions sources present. Thus,
there was no need to perform a separate
facility wide risk assessment.
b. Demographic Analysis
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To identify specific groups that may
be affected by this rulemaking, EPA
conducted demographic analyses. These
analyses provide information about the
percentages of different social,
demographic, and economic groups
within the populations subjected to
potential HAP-related cancer and noncancer risks from the facilities in this
source category.
For the demographic analyses, we
focus on the populations within 50 km
of any facility with emissions sources
subject to the MACT standard (identical
to the risk assessment). Based on the
emissions for the source category or the
facility, we then identified the
populations that are estimated to have
exposures to HAP which result in: (1)
Cancer risks of 1-in-1 million or greater;
(2) non-cancer HI of 1 or greater; and/
or (3) ambient lead concentrations above
the level of the NAAQS for lead. We
compare the percentages of particular
demographic groups within the focused
populations to the total percentages of
those demographic groups nationwide.
The results, including other risk
metrics, such as average risks for the
exposed populations, are documented
in a technical report in the docket for
the source category covered in this
proposal.11
The basis for the risk estimates used
in the demographic analyses for this
source category was the modeling
results based on actual emissions levels
obtained from the HEM–3 model
described above. The risk estimates for
each census block were linked to a
database of information from the 2000
decennial census that includes data on
race and ethnicity, age distributions,
poverty status, household incomes, and
education level. The Census Department
Landview® database was the source of
the data on race and ethnicity, and the
data on age distributions, poverty status,
household incomes, and education level
were obtained from the 2000 Census of
Population and Housing Summary File
3 (SF3) Long Form. While race and
ethnicity census data are available at the
census block level, the age and income
census data are only available at the
census block group level (which
includes an average of 26 blocks or an
average of 1,350 people). Where census
data are available at the block group
level but not the block level, we
assumed that all census blocks within
the block group have the same
distribution of ages and incomes as the
block group.
11 Risk and Technology Review—Analysis of
Socio-Economic Factors for Populations Living
Near Primary Lead Smelting Operations.
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As noted above, we focused the
analysis on those census blocks where
source category risk results show: (1)
Estimated lifetime inhalation cancer
risks above 1-in-1 million; (2) chronic
non-cancer indices above 1; and/or (3)
census blocks where estimated ambient
lead concentrations were above the level
of the lead NAAQS. For each of these
cases, we determined the relative
percentage of different racial and ethnic
groups, different age groups, adults with
and without a high school diploma,
people living in households below the
national median income, and people
living below the poverty line within
those census blocks.
The specific census population
categories included:
• Total population
• White
• African American (or Black)
• Native Americans
• Other races and multiracial
• Hispanic or Latino
• People living below the poverty line
• Children 18 years of age and under
• Adults 19 to 64 years of age
• Adults 65 years of age and over
• Adults without a high school
diploma.
It should be noted that these
categories overlap in some instances,
resulting in some populations being
counted in more than one category (e.g.,
other races and multiracial and
Hispanic). In addition, while not a
specific census population category, we
also examined risks to ‘‘Minorities,’’ a
classification that is defined for these
purposes as all race population
categories except white.
The methodology and the results of
the demographic analyses for this
source category are included in the
technical report available in the docket
for this action (Risk and Technology
Review—Analysis of Socio-Economic
Factors for Populations Living near
Secondary Lead Smelting Operations).
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7. Considering Uncertainties in Risk
Assessment
Uncertainty and the potential for bias
are inherent in all risk assessments,
including those performed for the
source category addressed in this
proposal. Although uncertainty exists,
we believe the approach that we took,
which used conservative tools and
assumptions to bridge data gaps,
ensures that our decisions are healthprotective. A brief discussion of the
uncertainties in the emissions dataset,
dispersion modeling, inhalation
exposure estimates, dose-response
relationships, multipathway and
environmental impacts analyses, and
demographics analysis follows below. A
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more thorough discussion of these
uncertainties is included in the risk
assessment documentation (Draft
Residual Risk Assessment for the
Secondary Lead Smelting Category)
available in the docket for this action.
a. Uncertainties in the Emissions
Dataset
Although the development of the RTR
dataset involved quality assurance/
quality control processes, the accuracy
of emissions values will vary depending
on the source of the data, the degree to
which data are incomplete or missing,
the degree to which assumptions made
to complete the datasets are accurate,
whether and to what extent errors were
made in estimating emissions values,
and other factors. The estimates of stack
emissions are largely based on actual
emissions test data, and, therefore, we
have a relatively high degree of
confidence in those estimates. With
regard to fugitive emissions, those
estimates are largely based on
engineering calculations and
application of various assumptions, and
are therefore considered less certain
relative to the stack emissions estimates.
Nevertheless, we believe the fugitive
estimates we derived for these facilities
and used in our analyses are reasonable
estimates of the actual fugitive
emissions from these facilities partly
due to the findings that the available
ambient monitoring data (which are
described in the document Draft
Summary of the Ambient Lead
Monitoring Data near Secondary Lead
Smelting Facilities, available in the
docket) indicate that measured levels of
lead in ambient air near these facilities
are generally similar in magnitude (e.g.,
generally within a factor of 2) to the
modeled estimates (which are shown in
the Draft Residual Risk Assessment for
the Secondary Lead Smelting Source
Category, which is available in the
docket).
The emissions estimates for stacks
considered in this analysis are hourly
emissions rates primarily extracted from
test reports and extrapolated to an
annual total based on the hours of
operation of each facility and may not
reflect short-term fluctuations during
the course of a year or variations from
year to year. The estimates of peak
hourly emissions rates from stacks for
the acute effects screening assessment
were based on multiplication factors
applied to the hourly emissions rates
(the default factor of 10 was used for
Secondary Lead Smelting for sources
other than fugitive dust) which are
intended to account for emissions
fluctuations due to normal facility
operations.
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There is an unquantified level of
uncertainty regarding the emissions
estimates for acute impacts of fugitive
dusts. The current set of assumptions
used in deriving the worst-case acute
impact estimate for fugitive dusts
assumes the average hourly emission
level (annual emissions divided by 8760
hours per year) to occur at the default
worst-case meteorological conditions
(low winds with a stable atmosphere). It
is acknowledged that the combination of
average emissions during low winds
would be an overestimate of the fugitive
dust emission rate during those low
wind periods. Therefore, for fugitive
dusts, the worst case meteorology may
not be the same as for other process
emissions, and the level of hourly
fugitive dust emissions during this
alternate worst-case condition is
unknown.
We further note that there is
additional uncertainty with respect to
emissions of mercury. As previously
noted, most of the mercury emissions
test results for this industry were below
detection limit. The emissions estimates
utilized in the risk assessment are based
on the health-protective assumption that
all the non-detect test values were at the
level of the detection limit. Therefore,
these estimated emissions for mercury
are clear overestimates. We conclude
that the true amounts of emissions of
mercury from this source category are
much lower than those provided in the
technical documents supporting today’s
proposed rule, but we are not able to
quantify precisely how much lower.
b. Uncertainties in Dispersion Modeling
Although the analysis employed
EPA’s recommended regulatory
dispersion model, AERMOD, we
recognize that there is uncertainty in
ambient concentration estimates
associated with any model, including
AERMOD. In circumstances where we
had to choose between various model
options, where possible, we selected
model options (e.g., rural/urban, plume
depletion, chemistry) that provided an
overestimate of ambient concentrations
of the HAP rather than an
underestimate. However, because of
practicality and data limitation reasons,
some factors (e.g., building downwash)
have the potential in some situations to
overestimate or underestimate ambient
impacts. Despite these uncertainties, we
believe that at off-site locations and
census block centroids, the approach
considered in the dispersion modeling
analysis should generally yield
overestimates of ambient HAP
concentrations.
Furthermore, as noted previously,
there is a level of uncertainty in the
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conditions leading to worst-case
emissions for fugitive dusts. However,
in the absence of better information
regarding actual short-term impacts
from fugitive dust sources, the
combination of average hourly emission
level and worst-case meteorology was
assumed to be useful for deriving
protective acute impact estimates.
c. Uncertainties in Inhalation Exposure
The effects of human mobility on
exposures were not included in the
assessment. Specifically, short-term
mobility and long-term mobility
between census blocks in the modeling
domain were not considered.12 As a
result, this simplification will likely
bias the assessment toward
overestimating the highest exposures. In
addition, the assessment predicted the
chronic exposures at the centroid of
each populated census block as
surrogates for the exposure
concentrations for all people living in
that block. Using the census block
centroid to predict chronic exposures
tends to over-predict exposures for
people in the census block who live
farther from the facility and underpredict exposures for people in the
census block who live closer to the
facility. Thus, using the census block
centroid to predict chronic exposures
may lead to a potential understatement
or overstatement of the true maximum
impact for any one individual, but is an
unbiased estimate of average risk and
incidence.
The assessments evaluate the
projected cancer inhalation risks
associated with pollutant exposures
over a 70-year period, which is the
assumed lifetime of an individual. In
reality, both the length of time that
modeled emissions sources at facilities
actually operate (i.e., more or less than
70 years), and the domestic growth or
decline of the modeled industry (i.e., the
increase or decrease in the number or
size of United States facilities), will
influence the future risks posed by a
given source or source category.
Depending on the characteristics of the
industry, these factors will, in most
cases, result in an overestimate both in
individual risk levels and in the total
estimated number of cancer cases.
However, in rare cases, where a facility
maintains or increases its emissions
levels beyond 70 years, residents live
beyond 70 years at the same location,
and the residents spend most of their
days at that location, then the risks
12 Short-term mobility is movement from one
microenvironment to another over the course of
hours or days. Long-term mobility is movement
from one residence to another over the course of a
lifetime.
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could potentially be underestimated.
Annual cancer incidence estimates from
exposures to emissions from these
sources would not be affected by
uncertainty in the length of time
emissions sources operate.
The exposure estimates used in these
analyses assume chronic exposures to
ambient levels of pollutants. Because
most people spend the majority of their
time indoors, actual exposures may not
be as high, depending on the
characteristics of the pollutants
modeled. For many of the HAP, indoor
levels are roughly equivalent to ambient
levels, but for very reactive pollutants or
larger particles, these levels are
typically lower. This factor has the
potential to result in an overstatement of
25 to 30 percent of exposures for some
HAP.13
In addition to the uncertainties
highlighted above, there are several
factors specific to the acute exposure
assessment that should be highlighted.
The accuracy of an acute inhalation
exposure assessment depends on the
simultaneous occurrence of
independent factors that may vary
greatly, such as hourly emissions rates,
meteorology, and human activity
patterns. In this assessment, we assume
that individuals remain for 1 hour at the
point of maximum ambient
concentration as determined by the cooccurrence of peak emissions and worstcase meteorological conditions. These
assumptions would tend to be worstcase actual exposures since it is unlikely
that a person would be located at the
point of maximum exposure during the
time of worst-case impact.
d. Uncertainties in Dose-Response
Relationships
There are uncertainties inherent in
the development of the dose-response
values used in our risk assessments for
cancer effects from chronic exposures
and non-cancer effects from both
chronic and acute exposures. Some
uncertainties may be considered
quantitatively, and others generally are
expressed in qualitative terms. We note
as a preface to this discussion a point on
dose-response uncertainty that is
brought out in EPA’s 2005 Cancer
Guidelines; namely, that ‘‘the primary
goal of EPA actions is protection of
human health; accordingly, as an
Agency policy, risk assessment
procedures, including default options
that are used in the absence of scientific
data to the contrary, should be health
protective’’ (EPA 2005 Cancer
13 U.S. EPA. National-Scale Air Toxics
Assessment for 1996. (EPA 453/R–01–003; January
2001; page 85.)
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Guidelines, pages 1–7). This is the
approach followed here as summarized
in the next several paragraphs. A
complete detailed discussion of
uncertainties and variability in doseresponse relationships is given in the
residual risk documentation which is
available in the docket for this action.
Cancer URE values used in our risk
assessments are those that have been
developed to generally provide an upper
bound estimate of risk. That is, they
represent a ‘‘plausible upper limit to the
true value of a quantity’’ (although this
is usually not a true statistical
confidence limit).14 In some
circumstances, the true risk could be as
low as zero; however, in other
circumstances the risk could be
greater.15 When developing an upper
bound estimate of risk and to provide
risk values that do not underestimate
risk, health-protective default
approaches are generally used. To err on
the side of ensuring adequate health
protection, EPA typically uses the upper
bound estimates rather than lower
bound or central tendency estimates in
our risk assessments, an approach that
may have limitations for other uses (e.g.,
priority-setting or expected benefits
analysis).
Chronic non-cancer reference (RfC
and RfD) values represent chronic
exposure levels that are intended to be
health-protective levels. Specifically,
these values provide an estimate (with
uncertainty spanning perhaps an order
of magnitude) of a continuous
inhalation exposure (RfC) or a daily oral
exposure (RfD) to the human population
(including sensitive subgroups) that is
likely to be without an appreciable risk
of deleterious effects during a lifetime.
To derive values that are intended to be
‘‘without appreciable risk,’’ the
methodology relies upon an uncertainty
factor (UF) approach (U.S. EPA, 1993,
1994) which considers uncertainty,
variability and gaps in the available
data. The UF are applied to derive
reference values that are intended to
protect against appreciable risk of
deleterious effects. The UF are
commonly default values,16 e.g., factors
14 IRIS glossary (https://www.epa.gov/NCEA/iris/
help_gloss.htm).
15 An exception to this is the URE for benzene,
which is considered to cover a range of values, each
end of which is considered to be equally plausible,
and which is based on maximum likelihood
estimates.
16 According to the NRC report, Science and
Judgment in Risk Assessment (NRC, 1994) ‘‘[Default]
options are generic approaches, based on general
scientific knowledge and policy judgment, that are
applied to various elements of the risk assessment
process when the correct scientific model is
unknown or uncertain.’’ The 1983 NRC report, Risk
Assessment in the Federal Government: Managing
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of 10 or 3, used in the absence of
compound-specific data; where data are
available, UF may also be developed
using compound-specific information.
When data are limited, more
assumptions are needed and more UF
are used. Thus, there may be a greater
tendency to overestimate risk in the
sense that further study might support
development of reference values that are
higher (i.e., less potent) because fewer
default assumptions are needed.
However, for some pollutants, it is
possible that risks may be
underestimated.
While collectively termed ‘‘UF,’’ these
factors account for a number of different
quantitative considerations when using
observed animal (usually rodent) or
human toxicity data in the development
of the RfC. The UF are intended to
account for: (1) Variation in
susceptibility among the members of the
human population (i.e., inter-individual
variability); (2) uncertainty in
extrapolating from experimental animal
data to humans (i.e., interspecies
differences); (3) uncertainty in
extrapolating from data obtained in a
study with less-than-lifetime exposure
(i.e., extrapolating from sub-chronic to
chronic exposure); (4) uncertainty in
extrapolating the observed data to
obtain an estimate of the exposure
associated with no adverse effects; and
(5) uncertainty when the database is
incomplete or there are problems with
the applicability of available studies.
Many of the UF used to account for
variability and uncertainty in the
development of acute reference values
are quite similar to those developed for
chronic durations, but they more often
use individual UF values that may be
less than 10. UF are applied based on
chemical-specific or health effectspecific information (e.g., simple
irritation effects do not vary appreciably
between human individuals, hence a
value of 3 is typically used), or based on
the purpose for the reference value (see
the following paragraph). The UF
applied in acute reference value
derivation include: (1) Heterogeneity
among humans; (2) uncertainty in
the Process, defined default option as ‘‘the option
chosen on the basis of risk assessment policy that
appears to be the best choice in the absence of data
to the contrary’’ (NRC, 1983a, p. 63). Therefore,
default options are not rules that bind the Agency;
rather, the Agency may depart from them in
evaluating the risks posed by a specific substance
when it believes this to be appropriate. In keeping
with EPA’s goal of protecting public health and the
environment, default assumptions are used to
ensure that risk to chemicals is not underestimated
(although defaults are not intended to overtly
overestimate risk). See EPA, 2004, An Examination
of EPA Risk Assessment Principles and Practices,
EPA/100/B–04/001 available at: https://
www.epa.gov/osa/pdfs/ratf-final.pdf.
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extrapolating from animals to humans;
(3) uncertainty in lowest observed
adverse effect (exposure) level to no
observed adverse effect (exposure) level
adjustments; and (4) uncertainty in
accounting for an incomplete database
on toxic effects of potential concern.
Additional adjustments are often
applied to account for uncertainty in
extrapolation from observations at one
exposure duration (e.g., 4 hours) to
derive an acute reference value at
another exposure duration (e.g., 1 hour).
As further discussed below, there is
no RfD or other comparable chronic
health benchmark value for lead
compounds. Thus, to address
multipathway human health and
environmental risks associated with
emissions of lead from this facility,
ambient lead concentrations were
compared to the NAAQS for lead. In
developing the NAAQS for lead, EPA
considered human health evidence
reporting adverse health effects
associated with lead exposure, as well
as an EPA-conducted multipathway risk
assessment that applied models to
estimate human exposures to air-related
lead and the associated risk (73 FR
66979). EPA also explicitly considered
the uncertainties associated with both
the human health evidence and the
exposure and risk analyses when
developing the NAAQS for lead. For
example, EPA considered uncertainties
in the relationship between ambient air
lead and blood lead levels (73 FR
66974), as well as uncertainties between
blood lead levels and loss of IQ points
in children (73 FR 66981).
In considering the evidence and risk
analyses and their associated
uncertainties, EPA found that there is
no evidence- or risk-based bright line
that indicates a single appropriate level.
EPA noted there is a collection of
scientific evidence and judgments and
other information, including
information about the uncertainties
inherent in many relevant factors,
which needs to be considered together
in making the public health policy
judgment and in selecting a standard
level from a range of reasonable values
(73 FR 66998). In so doing, EPA decided
that a level for the primary lead
standard of 0.15 μg/m3, in combination
with the specified choice of indicator,
averaging time, and form, is requisite to
protect public health, including the
health of sensitive groups, with an
adequate margin of safety (73 FR 67006).
A thorough discussion of the health
evidence, risk and exposure analyses,
and their associated uncertainties can be
found in EPA’s final rule revising the
lead NAAQS (73 FR 66970–66981,
November 12, 2008).
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We also note the uncertainties
associated with the health-based (i.e.,
primary) NAAQS are likely less than the
uncertainties associated with doseresponse values developed for many of
the other HAP, particularly those HAP
for which no human health data exist.
We also note that because of the
multipathway, multi-media impacts of
lead, the risk assessment supporting the
NAAQS considered direct inhalation
exposures and indirect air-related
multipathway exposures from industrial
sources like primary and secondary lead
smelting operations. It also considered
background lead exposures from other
sources (like contaminated drinking
water and exposure to lead-based
paints). In revising the NAAQS for lead,
EPA placed more weight on the
evidence-based framework and less
weight on the results from the risk
assessment, although the risk estimates
were found to be roughly consistent
with and generally supportive of the
evidence-based framework applied in
the NAAQS determination (73 FR
67004). Thus, when revising the
NAAQS for lead to protect public health
with an adequate margin of safety, EPA
considered both the health evidence and
the risk assessment, albeit to different
extents.
In addition to the uncertainties
discussed above with respect to chronic,
cancer, and the lead NAAQS reference
values, there are also uncertainties
associated with acute reference values.
Not all acute reference values are
developed for the same purpose, and
care must be taken when interpreting
the results of an acute assessment of
human health effects relative to the
reference value or values being
exceeded. Where relevant to the
estimated exposures, the lack of shortterm dose-response values at different
levels of severity should be factored into
the risk characterization as potential
uncertainties.
Although every effort is made to
identify peer-reviewed reference values
for cancer and non-cancer effects for all
pollutants emitted by the sources
included in this assessment, some
hazardous air pollutants continue to
have no peer-reviewed reference values
for cancer or chronic non-cancer or
acute effects. Since exposures to these
pollutants cannot be included in a
quantitative risk estimate, an
understatement of risk for these
pollutants at environmental exposure
levels is possible.
Additionally, chronic reference values
for several of the compounds included
in this assessment are currently under
EPA IRIS review (e.g., cadmium and
nickel), and revised assessments may
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determine that these pollutants are more
or less potent than the current value. We
may re-evaluate residual risks for the
final rulemaking if, as a result of these
reviews, a dose-response metric changes
enough to indicate that the risk
assessment supporting this notice may
significantly understate or overstate
human health risk.
e. Uncertainties in the Multipathway
and Environmental Impacts Assessment
For the secondary lead smelting
source category, two facilities were
chosen as case study analyses to assess
potential multipathway risks for
mercury, cadmium, POM, and dioxins
and furans. The selection criteria for
modeling these two facilities included
emissions rates of PB–HAPs, proximity
to water bodies, proximity to farmland,
average rainfall, average wind speed and
direction, smelting furnace type, local
change in elevation, and geographic
representativeness of sites throughout
the U.S. However, there is uncertainty
as to whether these two facilities
represent the highest potential for
multipathway human health risks from
the source category.
Since the modeling used in these case
study assessments utilize site specific
parameters to describe naturally
occurring physical, chemical and
biological processes, we believe that the
multimedia concentrations of PB–HAPs
generated in this analysis are unbiased
estimates of the true impacts.
With respect to the risk estimates
generated from this analysis, we present
results based on two ingestion exposure
scenarios: the RME and CTE scenarios.
As noted above, we believe that these
scenarios illustrate the range of
potential modeled exposures and risks
that may exist in the high-end of the
complete distribution of potential
multipathway risks for this source
category.
We further note that high-end fisher
populations could display considerable
variability both in terms of the degree to
which they frequent specific water
bodies or watersheds and the degree to
which they target specific types of fish
(or at least sizes of fish). Both of these
factors can impact estimates of
exposure. If a fisher population
distributes their activity across a range
of water bodies and harvests a variety of
fish species (and sizes) than the
distribution of exposure and risk across
that population will be smaller
compared with a population that
focuses activity at individual water
bodies and tends to focus on larger fish.
To estimate potential high-end
multipathway exposures and risks, in
addition to utilizing fish consumption
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rate data for the general U.S. population
of recreational anglers,17 we used fish
consumption information for distinct
fisher subpopulations that are known to
have higher fish consumption rates. The
data were obtained from Shilling, et al.
(2010).18 In this publication, the authors
provide fish consumption information
for different ethnic groups including
Hispanics, Laotians, and Vietnamese
surveyed in California’s Central Valley
Delta based on sample sizes of 45, 33,
and 30, respectively. We note that there
is uncertainty based on the limited
sample sizes and in the extrapolation of
these fish consumption rates to other
parts of the United States. Further
discussion of these values is provided in
the risk assessment supporting
documents. We request comment on the
use of these data to support the RME
analysis.
A more detailed discussion of the
multipathway analysis and its
associated uncertainties is presented in
section 5.3 of the document Human
Health Multipathway Residual Risk
Assessment for the Secondary Lead
Smelting Source Category, which can be
found in the docket for the proposed
rule.
f. Uncertainties in the Demographic
Analysis
Our analysis of the distribution of
risks across various demographic groups
is subject to uncertainty associated with
the extrapolation of census-block group
data (e.g., income level and education
level) down to the census block level.
C. How did we consider the risk results
in making decisions for this proposal?
In evaluating and developing
standards under section 112(f)(2), as
discussed in Section I.A of this
preamble, we apply a two-step process
to address residual risk. In the first step,
EPA determines whether risks are
acceptable. This determination
‘‘considers all health information,
including risk estimation uncertainty,
and includes a presumptive limit on
maximum individual lifetime [cancer]
risk (MIR) 19 of approximately 1-in-10
thousand [i.e., 100-in-1 million]’’ (54 FR
38045). In the second step of the
17 Data for the general U.S. population of
recreational anglers was obtained from: EPA 2002,
‘‘Estimated Per Capita Fish Consumption in the
United States, Office of Water, Office of Science and
Technology, Washington, DC, EPA–821–C–02–003.
August 2002.
18 Shilling, et al. 2010 is available in the docket
for this rulemaking.
19 Although defined as ‘‘maximum individual
risk,’’ MIR refers only to cancer risk. MIR, one
metric for assessing cancer risk, is the estimated
risk were an individual exposed to the maximum
level of a pollutant for a lifetime.
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process, EPA sets the standard at a level
that provides an ample margin of safety
‘‘in consideration of all health
information, including the number of
persons at risk levels higher than
approximately 1-in-1 million, as well as
other relevant factors, including costs
and economic impacts, technological
feasibility, and other factors relevant to
each particular decision’’ (Id.)
In past residual risk actions, EPA has
presented and considered a number of
human health risk metrics associated
with emissions from the category under
review, including: The MIR; the
numbers of persons in various risk
ranges; cancer incidence; the maximum
non-cancer hazard index (HI); and the
maximum acute non-cancer hazard (72
FR 25138, May 3, 2007; 71 FR 42724,
July 27, 2006). In our most recent
proposals (75 FR 65068, October 21,
2010 and 75 FR 80220, December 21,
2010), EPA also presented and
considered additional measures of
health information, such as estimates of
the risks associated with the maximum
level of emissions which might be
allowed by the current MACT standards
(see, e.g., 75 FR 65068, October 21, 2010
and 75 FR 80220, December 21, 2010).
EPA also discussed and considered risk
estimation uncertainties. EPA is
providing this same type of information
in support of the proposed actions
described in this Federal Register
notice.
The Agency is considering all
available health information to inform
our determinations of risk acceptability
and ample margin of safety under CAA
section 112(f). Specifically, as explained
in the Benzene NESHAP, ‘‘the first step
judgment on acceptability cannot be
reduced to any single factor’’ and thus
‘‘[t]he Administrator believes that the
acceptability of risk under [previous]
section 112 is best judged on the basis
of a broad set of health risk measures
and information’’ (54 FR 38046).
Similarly, with regard to making the
ample margin of safety determination,
as stated in the Benzene NESHAP ‘‘[in
the ample margin decision, the Agency
again considers all of the health risk and
other health information considered in
the first step. Beyond that information,
additional factors relating to the
appropriate level of control will also be
considered, including cost and
economic impacts of controls,
technological feasibility, uncertainties,
and any other relevant factors.’’ Id.
The Agency acknowledges that the
Benzene NESHAP provides flexibility
regarding what factors EPA might
consider in making determinations and
how these factors might be weighed for
each source category. In responding to
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comment on our policy under the
Benzene NESHAP, EPA explained that:
‘‘The policy chosen by the
Administrator permits consideration of
multiple measures of health risk. Not
only can the MIR figure be considered,
but also incidence, the presence of noncancer health effects, and the
uncertainties of the risk estimates. In
this way, the effect on the most exposed
individuals can be reviewed as well as
the impact on the general public. These
factors can then be weighed in each
individual case. This approach complies
with the Vinyl Chloride mandate that
the Administrator ascertain an
acceptable level of risk to the public by
employing [her] expertise to assess
available data. It also complies with the
Congressional intent behind the CAA,
which did not exclude the use of any
particular measure of public health risk
from the EPA’s consideration with
respect to CAA section 112 regulations,
and, thereby, implicitly permits
consideration of any and all measures of
health risk which the Administrator, in
[her] judgment, believes are appropriate
to determining what will ‘protect the
public health’ ’’ (54 FR at 38057).
Thus, the level of the MIR is only one
factor to be weighed in determining
acceptability of risks. The Benzene
NESHAP explained that ‘‘an MIR of
approximately 1-in-10 thousand should
ordinarily be the upper end of the range
of acceptability. As risks increase above
this benchmark, they become
presumptively less acceptable under
CAA section 112, and would be
weighed with the other health risk
measures and information in making an
overall judgment on acceptability. Or,
the Agency may find, in a particular
case, that a risk that includes MIR less
than the presumptively acceptable level
is unacceptable in the light of other
health risk factors’’ (Id. at 38045).
Similarly, with regard to the ample
margin of safety analysis, EPA stated in
the Benzene NESHAP that: ‘‘* * * EPA
believes the relative weight of the many
factors that can be considered in
selecting an ample margin of safety can
only be determined for each specific
source category. This occurs mainly
because technological and economic
factors (along with the health-related
factors) vary from source category to
source category’’ (Id. at 38061).
EPA wishes to point out that certain
health information has not been
considered to date in making residual
risk determinations. In assessing risks to
populations in the vicinity of the
facilities in each category, we present
estimates of risk associated with HAP
emissions from the source category
alone (source category risk estimates),
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and generally we have also assessed
risks due to HAP emissions from the
entire facility at which the covered
source category is located (facility-wide
risk estimates). We have not attempted
to characterize the risks associated with
all HAP emissions impacting the
populations living near the sources in
these categories. That is, at this time, we
do not attempt to quantify those HAP
risks that may be associated with
emissions from other facilities that do
not include the source categories in
question, mobile source emissions,
natural source emissions, persistent
environmental pollution, or
atmospheric transformation in the
vicinity of the sources in these
categories.
The Agency understands the potential
importance of considering an
individual’s total exposure to HAP in
addition to considering exposure to
HAP emissions from the source category
and facility. This is particularly
important when assessing non-cancer
risks, where pollutant-specific exposure
health reference levels (e.g., Reference
Concentrations (RfCs)) are based on the
assumption that thresholds exist for
adverse health effects. For example, the
Agency recognizes that, although
exposures attributable to emissions from
a source category or facility alone may
not indicate the potential for increased
risk of adverse non-cancer health effects
in a population, the exposures resulting
from emissions from the facility in
combination with emissions from all of
the other sources (e.g., other facilities) to
which an individual is exposed may be
sufficient to result in increased risk of
adverse non-cancer health effects. In
May 2010, the EPA SAB advised us
‘‘* * * that RTR assessments will be
most useful to decision makers and
communities if results are presented in
the broader context of aggregate and
cumulative risks, including background
concentrations and contributions from
other sources in the area.’’ 20
Although we are interested in placing
source category and facility-wide HAP
risks in the context of total HAP risks
from all sources combined in the
vicinity of each source, we are
concerned about the uncertainties of
doing so. At this point, we believe that
such estimates of total HAP risks will
have significantly greater associated
20 EPA’s responses to this and all other key
recommendations of the SAB’s advisory on RTR
risk assessment methodologies (which is available
at: https://yosemite.epa.gov/sab/sabproduct.nsf/
4AB3966E263D943A8525771F00668381/$File/EPASAB-10-007-unsigned.pdf) are outlined in a memo
to this rulemaking docket from David Guinnup
entitled, EPA’s Actions in Response to the Key
Recommendations of the SAB Review of RTR Risk
Assessment Methodologies.
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uncertainties than for the source
category or facility-wide estimates, and
hence would compound the uncertainty
in any such comparison. This is because
we have not conducted a detailed
technical review of HAP emissions data
for source categories and facilities that
have not previously undergone an RTR
review or are not currently undergoing
such review. We are requesting
comment on whether and how best to
estimate and evaluate total HAP
exposure in our assessments, and, in
particular, on whether and how it might
be appropriate to use information from
EPA’s National Air Toxics Assessment
(NATA) to support such estimates. We
are also seeking comment on how best
to consider various types and scales of
risk estimates when making our
acceptability and ample margin of safety
determinations under CAA section
112(f). Additionally, we are seeking
comments and recommendations for
any other comparative measures that
may be useful in the assessment of the
distribution of HAP risks across
potentially affected demographic
groups.
D. How did we perform the technology
review?
Our technology review focused on the
identification and evaluation of
developments in practices, processes,
and control technologies that have
occurred since the 1997 NESHAP was
promulgated. In cases where the
technology review identified such
developments, we conducted an
analysis of the technical feasibility of
applying these developments, along
with the estimated impacts (costs,
emissions reductions, risk reductions,
etc.) of applying these developments.
We then made decisions on whether it
is necessary to propose amendments to
the regulation to require any of the
identified developments.
Based on our analyses of the data and
information collected by the ICR and
our general understanding of the
industry and other available information
on potential controls for this industry,
we identified several potential
developments in practices, processes,
and control technologies. For the
purpose of this exercise, we considered
any of the following to be a
‘‘development’’:
• Any add-on control technology or
other equipment that was not identified
and considered during development of
the 1997 NESHAP.
• Any improvements in add-on
control technology or other equipment
(that were identified and considered
during development of the 1997
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NESHAP) that could result in significant
additional emissions reduction.
• Any work practice or operational
procedure that was not identified or
considered during development of the
1997 NESHAP.
• Any process change or pollution
prevention alternative that could be
broadly applied to the industry and that
was not identified or considered during
development of the 1997 NESHAP.
In addition to reviewing the practices,
processes, or control technologies that
were not considered at the time we
developed the 1997 NESHAP, we
reviewed a variety of data sources in our
evaluation of whether there were
additional practices, processes, or
controls to consider for the secondary
lead smelting industry. Among the data
sources we reviewed were the NESHAP
for various industries that were
promulgated after the 1997 NESHAP.
We reviewed the regulatory
requirements and/or technical analyses
associated with these regulatory actions
to identify any practices, processes, and
control technologies considered in these
efforts that could possibly be applied to
emissions sources in the Secondary
Lead Smelting source category, as well
as the costs, non-air impacts, and energy
implications associated with the use of
these technologies.
We also consulted EPA’s RACT/
BACT/LAER Clearinghouse (RBLC) to
identify potential technology advances.
Control technologies, classified as RACT
(Reasonably Available Control
Technology), BACT (Best Available
Control Technology), or LAER (Lowest
Achievable Emissions Rate) apply to
stationary sources depending on
whether the sources are existing or new,
and on the size, age, and location of the
facility. BACT and LAER (and
sometimes RACT) are determined on a
case-by-case basis, usually by State or
local permitting agencies. EPA
established the RBLC to provide a
central database of air pollution
technology information (including
technologies required in source-specific
permits) to promote the sharing of
information among permitting agencies
and to aid in identifying future possible
control technology options that might
apply broadly to numerous sources
within a category or apply only on a
source-by-source basis. The RBLC
contains over 5,000 air pollution control
permit determinations that can help
identify appropriate technologies to
mitigate many air pollutant emissions
streams. We searched this database to
determine whether it contained any
practices, processes, or control
technologies for the types of processes
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covered by the Secondary Lead
Smelting MACT.
Additionally, we requested
information from facilities regarding
developments in practices, processes, or
control technology. Finally, we
reviewed other information sources,
such as State or local permitting agency
databases and industry-supported
databases.
E. What other issues are we addressing
in this proposal?
In addition to the analyses described
above, we also reviewed other aspects of
the MACT standards for possible
revision as appropriate and necessary.
Based on this review we have identified
aspects of the MACT standards that we
believe need revision.
This includes proposing revisions to
the startup, shutdown, and malfunction
(SSM) provisions of the MACT rule in
order to ensure that they are consistent
with a recent court decision in Sierra
Club v. EPA, 551 F.3d 1019 (DC Cir.
2008). In addition, we are proposing
other various minor changes with
regards to editorial errors and other
revisions to promote the use of plain
language. The analyses and proposed
decisions for these actions are presented
in Section IV.E of this preamble.
IV. Analyses Results and Proposed
Decisions
This section of the preamble provides
the results of our RTR for the Secondary
Lead Smelting source category and our
proposed decisions concerning changes
to the 1997 NESHAP.
A. What are the results of our analyses
and proposed decisions regarding
unregulated emissions sources?
1. Organic HAP
As discussed in Section III.A of this
preamble, we evaluated emissions limits
for organic HAP for reverberatory
furnaces not collocated with blast
furnaces, rotary furnaces, and electric
furnaces. Section 112(d)(3)(B) of the
CAA requires that the MACT standards
for existing sources be at least as
stringent as the average emissions
limitation achieved by the best
performing five sources (for which the
Administrator has or could reasonably
obtain emissions information) in a
category with fewer than 30 sources.
The Secondary Lead Smelting source
category consists of fewer than 30
sources. Where, as here, there are less
than 30 sources, we base the MACT
floor limit on the average emissions
limitation achieved by those sources for
which we have data.
EPA must exercise its judgment,
based on an evaluation of the relevant
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factors and available data, to determine
the level of emissions control that has
been achieved by the best performing
sources under variable conditions. It is
recognized in the case law that EPA may
consider variability in estimating the
degree of emissions reduction achieved
by best-performing sources and in
setting MACT floors. See Mossville
Envt’l Action Now v. EPA, 370 F.3d
1232, 1241–42 (DC Cir 2004) (holding
EPA may consider emissions variability
in estimating performance achieved by
best-performing sources and may set the
floor at a level that a best-performing
source can expect to meet ‘‘every day
and under all operating conditions’’).
More details on how we calculate
MACT floors and how we account for
variability are described in the Draft
MACT Floor Analysis for the Secondary
Lead Smelting Source Category which is
available in the docket for this proposed
action.
With regard to the evaluation of
potential MACT limits for organic HAP
from this source category, consistent
with the explanation presented in the
proposal of the 1997 NESHAP (NESHAP
for Secondary Lead Smelting, Proposed
Rule, June 9, 1994, 59 FR 63941) for this
source category describing the
appropriateness of THC as a surrogate
for organic HAP, we continue to
consider THC as an appropriate
surrogate for non-dioxin organic HAP in
the proposed amendments to the
NESHAP in today’s action. Based on our
data, there are currently only two
reverberatory furnaces not collocated
with a blast furnace, one rotary furnace,
and two reverberatory furnaces mixed
with electric furnaces (i.e., two
reverberatory furnaces whose exhaust
are mixed with the exhaust of an
electric furnace prior to atmospheric
release) operating in this source
category. Based on analysis of emissions
data and furnace operating
characteristics (as discussed further
below), we believe it is appropriate to
set one THC limit that will apply to
reverberatory furnaces not collocated
with a blast furnace and reverberatory
furnaces mixed with electric furnaces,
because of generally similar (and low)
potential for organic HAP emissions
from both furnace types. We are
proposing a separate THC emissions
limit for rotary furnaces.
We received THC emissions data for
one reverberatory furnace not collocated
with a blast furnace and one
reverberatory furnace mixed with an
electric furnace, and one rotary furnace.
Therefore, for each of these furnace
configurations, we have emissions data
from at least half the units. We are
soliciting emissions data for the
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operating affected sources for which we
don’t have data. Based on the data that
we have, we conducted a MACT Floor
analysis.
As discussed above, the MACT floor
limit is calculated based on the average
performance of the units plus an
amount to account for these units’
variability. To account for variability in
the operation and emissions, the stack
test data were used to calculate the 99
percent upper predictive limit (UPL) for
reverberatory furnaces not collocated
with a blast furnace and reverberatory
furnaces mixed with electric furnaces.
For rotary furnaces, because we have
only one test with two successful test
runs, we considered both the 99 percent
UPL and the 99 percent upper limit (UL)
to account for variability in the
emissions data. Our consideration of
variability is explained in more detail in
the technical document for this action:
Draft MACT Floor Analysis for the
Secondary Lead Smelting Source
Category, which is available in the
docket for this action.
The 99 percent UPL for exhaust THC
concentrations from existing
reverberatory furnaces not collocated
with a blast furnace and reverberatory
furnaces mixed with electric furnaces is
12 ppmv (expressed as propane)
corrected to 4 percent CO2 to account
for dilution. Consistent with CAA
section 112(d)(3), the MACT floor for
new sources cannot be less stringent
than the emissions control that is
achieved in practice by the bestcontrolled similar source. The 99
percent UPL for exhaust THC
concentrations from the best-performing
affected source was calculated as 12
ppmv (expressed as propane) corrected
to 4 percent CO2.
We are also proposing a THC MACT
limit for rotary furnaces. As mentioned
previously, there is only one operating
rotary furnace in the U.S. We received
test data for this unit; however, it
included only two successful test runs.
The average of the two emissions test
runs was 257 ppmv (expressed as
propane and adjusted to 4 percent CO2),
and the highest of the two test runs was
292 ppmv (expressed as propane and
adjusted to 4 percent CO2). Using the 99
percent UPL approach, we calculated a
MACT floor of 1700 ppmv, which is 6.6
times higher than the average. By using
the 99 percent UL approach, we
calculated a MACT floor of 610 ppmv
(expressed as propane and adjusted to 4
percent CO2) applicable to new and
existing affected sources, which is 2.4
times higher than the average. Because
of very limited emissions data, our
statistical analysis does not clearly
indicate whether the UPL or UL is a
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better measure of the typical variability
in performance of the unit. However,
because the 99 percent UL approach
resulted in a MACT floor that is more
within the range of typical variability
we expect when calculating MACT
floors for various source categories and
emissions points, the emissions limit
calculated using the 99 percent UL was
chosen as the proposed THC MACT
floor for rotary furnaces in this action.
However, we seek comments on this
issue.
We considered beyond-the-floor
options for THC standards for all of
these furnace configurations, as required
by section 112(d)(2) of the Act.
However, we decided not to propose
any limits based on the beyond the floor
analyses for THC because of the costs,
potential disadvantages of these
additional controls (including increases
in CO2 and NOX emissions), and non-air
environmental impacts and adverse
energy implications associated with use
of these additional controls. The
beyond-the-floor analysis is presented
in the technical documentation for this
action (Draft MACT Floor Analysis for
the Secondary Lead Smelting Source
Category). In summary, we are
proposing that new and existing
reverberatory furnaces not collocated
with a blast furnace and reverberatory
furnaces mixed with electric furnaces be
subject to a THC concentration limit of
12 ppmv (expressed as propane)
corrected to 4 percent CO2.
Additionally, we are proposing that
both new and existing rotary furnaces be
subject to a THC concentration limit of
610 ppmv (expressed as propane)
corrected to 4 percent CO2.
We propose that compliance with all
the proposed THC limits will be
demonstrated by annual performance
tests, and that continuous monitoring of
temperatures of control devices (e.g.,
afterburners) and/or furnaces (e.g.,
reverberatory furnaces) will be required
as parametric monitoring to ensure
continuous compliance with the THC
limits.
No changes are being considered in
this action for the THC limits for blast
and collocated blast and reverberatory
furnaces established in the 1997
NESHAP.
2. Dioxin and Furans
As mentioned previously, the 1997
NESHAP does not include emissions
limits for dioxins and furans. Therefore,
pursuant to CAA section 112(d)(3), we
are proposing to revise the 1997
NESHAP to include emission limits for
dioxins and furans. The form of these
proposed standards are in the form of
toxic equivalency quotient (TEQ)
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29049
concentration limits (i.e., prorating the
amount of total dioxins and furans
allowed to the most toxic species of
dioxin). For more information on the
TEQ approach to calculating dioxin and
furan emissions see the dioxin
emissions guidance available at: https://
www.epa.gov/raf/hhtefguidance/.
Because the formation of dioxins and
furans is highly temperature dependent,
and because the potential for dioxin and
furan emissions varies considerably
among different furnace types and
configurations, EPA is proposing
separate limits for each of the following
furnace configurations: (1)
Reverberatory furnaces not collocated
with blast furnaces and reverberatory
furnaces where the exhaust gases are
mixed with the exhaust from electric
furnaces; (2) blast furnaces; (3)
collocated blast and reverberatory
furnaces; and (4) rotary furnaces. A
detailed analysis and documentation of
the MACT floor calculations can be
found in the technical document for this
action: Draft MACT Floor Analysis for
the Secondary Lead Smelting Source
Category.
Based on the emissions data and
furnace operating temperatures reported
in ICR surveys, EPA is proposing a
single TEQ emissions limit that will
apply to reverberatory furnaces not
collocated with a blast furnace and to
reverberatory furnaces where the
exhaust gases are mixed with electric
furnaces. There are seven sources of this
type in the industry. We received
emissions data for two such affected
sources. We are soliciting data for the
affected sources of this type for which
we don’t have emissions data. The
MACT floor emissions limit for this
affected source was calculated based on
the average of the two emissions tests
plus variability (based on the 99 percent
UPL). The 99 percent UPL for exhaust
TEQ concentrations from the affected
sources is 0.20 nanograms per dry
standard cubic meter (ng/dscm) of TEQ
corrected to 7 percent oxygen (O2) to
account for dilution. The 99 percent
UPL calculated for new affected sources
is 0.10 ng/dscm corrected to 7 percent
O2.
With regard to blast furnaces, there
are nine sources of this type in the
industry. We received dioxin and furan
emissions data for two affected sources.
Using the data from these two sources,
we calculated that the 99 percent UPL
for exhaust TEQ concentrations from
blast furnaces is 170 ng/dscm at 7
percent O2. For new blast furnaces, the
99 percent UPL is 10 ng/dscm at 7
percent O2. We acknowledge the large
difference between the performance of
the two affected sources for which we
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have data but have not identified a
technical basis for the difference. We are
soliciting information that may explain
these differences and other comments
on this topic, including comments
regarding the calculation of MACT floor
limits for these sources. Additionally,
we are soliciting data for the seven
affected sources of this type for which
we don’t have emissions test data.
There are five collocated blast and
reverberatory furnaces in the industry.
We received emissions test data for one
of the affected sources. The calculated
99 percent UPL is 0.5 ng/dscm at 7
percent O2 and would apply to both
new and existing collocated blast and
reverberatory furnaces. We are soliciting
data for the remaining four affected
sources for which we don’t have
emissions data.
As previously noted, there is only one
rotary furnace currently in operation
and we received emissions data for this
source. Similar to THC emissions, we
have only two emissions test runs for
this unit. For the same reasons
explained above for THC, we developed
a MACT floor limit of 1.0 ng/dscm of
TEQ corrected to 7 percent O2 based on
the 99 percent UL, as opposed to the
UPL. Thus, an emissions limit based on
the MACT floor for existing and new
rotary furnaces would be 1.0 ng/dscm of
TEQ corrected to 7 percent O2.
We then considered beyond-the-floor
options to further reduce emissions of
dioxins and furans, especially from blast
furnaces since blast furnaces have
higher emissions compared to the other
furnace types. The options considered,
included an option based on setting a
MACT limit for existing sources based
on the performance of the best
performing source (i.e., based upon the
test data used to calculate the MACT
floor for new sources) such that the
MACT limit for existing sources would
be the same as the MACT limit for new
sources (i.e., 10 ng/dscm). However,
since we are uncertain about the
performance of the other blast furnaces
and whether it would be feasible for
them to meet a limit of 10 ng/dscm and
what the costs would be, we are not
proposing MACT limits for existing
blast furnaces based on this one set of
data in today’s action. We do have data
for two other blast furnaces that are not
controlled with reverberatory furnaces,
but because of the configuration of the
stacks (blast furnace off-gas is mixed
with reverberatory furnace off-gas), we
were unable to determine the amount of
dioxin that originated from the blast
furnace alone compared to the dioxin
that was due to the reverberatory
furnace. Therefore, these data were not
used in the calculation of the blast
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furnace MACT limits. However, we note
that the dioxin concentrations emitted
from these sources was in the range of
the better performing of the two blast
furnaces that were used in the
calculations of the MACT Floor.
Nevertheless, we are seeking comments
as to whether it would be appropriate to
establish a MACT limit based upon the
data from the one better performing
blast furnace or if it would be
appropriate to use the data from the
mixed sources to determine a MACT
limit for Blast furnaces. A MACT limit
based upon the data from the one better
performing blast furnace (using the 3
test results and applying the 99 percent
UPL) would be 10 ng/dscm. We are
seeking comments on whether this
limit, or some other limit, would be
appropriate for Blast Furnaces.
The key conditions typically
associated with determining the extent
of dioxin and furan formation are
combustion efficiency, complex organic
fuels, particulate concentration in the
flue gas, time in a critical temperature
window of approximately 250 to 450
degrees C, and the amount of chlorine
present. Increased chlorine
concentrations in the furnace feed can
increase the dioxin formation. The blast
furnaces tested have higher emissions of
dioxins and furans than other furnace
types. We believe this is because these
furnaces are designed to operate at
lower temperatures, and these operating
temperatures can lead to dioxin
formation. Controls for dioxins and
furans once they have formed include a
high temperature oxidation with quick
quenching of the off-gases, or activated
carbon injection followed by fabric
filtration. Fabric filtration alone has also
been demonstrated to provide
significant control of dioxins and
furans, and because improvements are
expected in the performance of fabric
filters as a result of standards being
proposed for lead in today’s action, it is
anticipated that some additional
reduction in dioxin emissions may
occur as a co-benefit of the proposed
lower limits for lead. Nevertheless, we
are seeking data and information on
dioxin emissions from blast furnaces,
possible control options, factors that
affect dioxin formation and other related
information to inform the development
of appropriate standards for dioxin and
furan emissions from these sources.
As described below, we are also
proposing a work practice standard to
prevent plastics (which are complex
organics and may contain chlorine) from
entering furnaces as a beyond-the-floor
option. We also considered an option
that involves installation of additional
afterburner capacity at the facilities
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operating blast furnaces. This option
would include operating the currently
installed afterburners at high
temperatures and with sufficient
residence time to destroy dioxins, or
installation of new or additional
afterburner capacity with this
capability. Based on the current level of
performance identified in the ICR
surveys, we believe that this option
would require four facilities to install
afterburner capacity at their facility in
order to operate the units at these
conditions. The estimated total capital
cost for the additional controls is
$5.9 million, with a total annualized
cost of $2.9 million. We estimate that
TEQ emissions would be reduced by
roughly 28 grams per year (and organic
HAP emissions by 200 tons per year)
resulting in a total estimated cost
effectiveness of $103,600 per gram of
dioxin TEQ and $14,500 per ton organic
HAP (see: Draft MACT Floor Analysis
for the Secondary Lead Smelting Source
Category for more details).
In light of the costs of these additional
controls and since these controls would
have some disadvantages, including
causing increases in CO2 and NOX
(oxides of nitrogen) emissions and
increased fuel use, and given the
uncertainties regarding how effective
these controls would be, we are not
proposing more stringent numerical
emissions limits based on this beyondthe-floor analysis. Nevertheless, we are
seeking data and information on dioxin
and furan emissions from blast furnaces
and the costs and feasibility of
additional controls and emissions
reductions, including the beyond-thefloor options described above.
Based on all the analyses described
above, under CAA section 112(d)(3), we
are proposing to revise the 1997
NESHAP for this source category to
include the following emissions limits
for dioxins and furans:
• For reverberatory furnaces not collocated
with blast furnaces and reverberatory
furnaces where the exhaust gases are mixed
with electric furnaces, we are proposing
emissions limits of 0.20 ng/dscm at 7 percent
O2 and 0.1 ng/dscm at 7 percent O2 for
existing and new affected sources,
respectively.
• For blast furnaces, we are proposing
emissions limits of 170 ng/dscm at 7 percent
O2 and 10 ng/dscm at 7 percent O2 for
existing and new sources, respectively.
• For collocated blast and reverberatory
furnaces, we are proposing an emissions
limit of 0.5 ng/dscm at 7 percent O2 for both
new and existing sources.
• For rotary furnaces, we are proposing an
emissions limit of 1.0 ng/dscm at 7 percent
O2 for both new and existing sources.
Compliance with the TEQ limits will
be demonstrated through an initial
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compliance test followed by a
compliance test at least once every
5 years. The TEQ emissions will be
calculated using the toxic equivalency
factors (TEF) outlined by the World
Health Organization (WHO) in 2005
(available at Web site: https://
www.epa.gov/raf/hhtefguidance/).
Additionally, we are proposing that
facilities must establish limits for the
furnace exhaust temperature or
afterburner operating temperature
during the initial performance test.
These temperatures must be maintained
and monitored continuously between
compliance tests to ensure that the
controls are working properly to limit
dioxin and furan emissions.
In addition to the emissions limits
described above, we are proposing that
each facility must operate a process to
separate plastic battery casing material
prior to introducing feed into a blast
furnace. Separation of plastic materials
prior to the furnace will limit the
organic component in the feed material,
minimizing the formation of organic
HAP, including dioxins and furans. It is
our understanding that all facilities
currently have a plastics separation
process (that they implement on a
voluntary basis) so this proposed
requirement results in very minimal
additional costs to the industry, if any.
We are proposing this as a requirement
(i.e., propose to convert this from a
voluntary activity to a regulatory
requirement) to ensure that facilities
continue to implement the separation
process to help minimize formation of
dioxins and furans. Moreover, we
considered proposing a minimum
percent of plastics separation
requirement (such as ensuring that a
minimum of 95 percent of total plastics
are separated from the scrap materials
before being fed to furnaces). However,
we did not have sufficient data to
determine an appropriate specific
percent. Nevertheless, we are seeking
data and comments regarding the
percent separation that can be achieved
by the available processes and the
potential to establish such a minimum
percent separation requirement.
Moreover, we are seeking information
and comments on the various types of
plastics separation processes and
equipment used, and the relative
feasibility and effectiveness of those
processes and equipment. We are also
seeking comments and information on
potential methods to improve overall
plastics separation, or methods to
improve separation of certain types of
plastics that may have higher potential
for dioxin formation (e.g., chlorinated
plastics). Finally, we are seeking
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information on appropriate
recordkeeping and reporting
requirements for these proposed work
practices.
3. Mercury Emissions
Based on the emissions test data
received under the ICR, we considered
proposing an emissions limit for
mercury under CAA section 112(d)(3).
However, after careful review of the data
from the ICR, we have decided not to
propose a numerical limit for mercury.
We found that the measured stack
concentrations of mercury were
consistently below the detection levels
of the EPA test methods (52 out of 76
total test runs for mercury contained
data below the detection limit, or
68 percent of the entire data set).
Consequently, EPA considers it
impracticable to reliably measure
mercury emissions from these units.
We instead considered work practice
standards under 112(h) for mercury
emissions from this category. The
difficulties with accurate measurements
at the levels encountered from
secondary lead smelters makes a
measured standard technologically
impracticable, and possibly
economically impracticable as well
(there appears to be no reliable way to
measure compliance at such low levels
even with the most carefully conducted
tests). Given the factors described above,
we conclude it is appropriate to
consider work practice standards under
112(h) for mercury rather than
numerical emissions limits under
Section 112(d)(3).
Therefore, we considered establishing
work practice standards under CAA
section 112(h) to minimize the potential
for mercury emissions. Based on
information submitted under the ICR,
all facilities have baghouses to control
lead and other particulate matter (PM)
emissions. These control devices are
very effective at controlling non-volatile
HAP metals (e.g., a well performing
baghouse captures more than 99 percent
of lead emissions). These devices do not
capture mercury as efficiently as the
non-volatile metals. However, available
data from other industries (such as coalfired power plants) indicate that
baghouses do provide some level of
mercury control. For example,
emissions data from coal-fired power
plants suggest that baghouses can
capture approximately 50 to 90 percent
of mercury emissions depending on the
speciation of the mercury compounds
and other factors. (Reference: ‘‘Control of
Mercury Emissions from Coal Fired
Electric Utility Boilers: An Update.’’
National Risk Management Research
Laboratory, Office of Research and
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Development, U.S. EPA. February 18,
2005, available at: https://www.epa.gov/
ttn/atw/utility/utiltoxpg.html).
Therefore, we are proposing that
facilities must have continuous
operation of a BLDS with a detection
level of 1.0 mg/dscm for PM to ensure
their baghouses are working properly as
a work practice to limit mercury
emissions. This is the same requirement
proposed for lead emissions monitoring
in this rulemaking under CAA sections
112(f)(2) and 112(d)(6), and will
therefore pose no additional burden to
the industry. Further, the proposed
stack standards for lead will also
adequately control mercury such that no
further standard is necessary. The
standard would be implemented
continuously for all metals by the BLDS
measurement.
Nevertheless, we also investigated the
feasibility of additional work practices
to determine if there were other costeffective pollution prevention measures
that could be applied to this industry to
further minimize mercury emissions
such as source separation approaches.
Based on available information,
analyses, and discussion with industry,
we understand that the vast majority of
input materials have very low mercury
content (e.g., lead acid batteries).
However, we also understand that other
types of scrap such as industrial
batteries, various construction materials,
and other scrap materials are
occasionally processed in these furnaces
materials. To ensure that mercurybearing materials are not included in
such scrap, we considered proposing
that facilities inspect their input scrap
materials daily to ensure that mercurybearing materials are not fed to the
furnaces. However, we are not aware of
any identifiable or recoverable sources
of mercury in the scrap fed to secondary
lead smelters and we are also concerned
that such work practices could be
infeasible. Therefore, we are not
proposing such a standard in today’s
action. However, we are soliciting
comments on the appropriateness and
feasibility of implementing such a work
practice standard for mercury. We are
also interested in information regarding
any other pollution prevention practices
for mercury that may be feasible or
appropriate for this source category.
B. What are the results of the risk
assessments and analyses?
As described above, for the Secondary
Lead Smelting source category, we
conducted an inhalation risk assessment
for all HAP emitted. We also conducted
multipathway analyses for cadmium,
dioxins and furans, mercury, and POM,
as well as air-related multipathway
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analyses for lead. With respect to lead,
we used the recently promulgated lead
NAAQS to evaluate the potential for airrelated multipathway and
environmental effects. Furthermore, we
conducted a demographic analysis of
population risks. Details of the risk
assessments and additional analyses can
be found in the residual risk
documentation referenced in Section
III.B of this preamble, which is available
in the docket for this action. The
Agency considered the available health
information—the MIR; the numbers of
persons in various risk ranges; cancer
incidence; the maximum non-cancer
hazard index (HI); the maximum acute
non-cancer hazard; the extent of noncancer risks; the potential for adverse
environmental effects; and distribution
of risks in the exposed population
(54 FR 38044, September 14, 1989)—in
developing the proposed CAA section
112(f)(2) standards for the Secondary
Lead source category.
1. Inhalation Risk Assessment Results
Table 3 of this preamble provides an
overall summary of the results of the
inhalation risk assessment.
TABLE 3—SECONDARY LEAD SMELTING INHALATION RISK ASSESSMENT RESULTS
Maximum individual cancer risk
(in 1 million) 1
Based on actual emissions level
Based on
allowable
emissions
level
Estimated
population
at increased
risk of
cancer ≥1in-1 million
50 .....................................................................................
200
128,000
Maximum chronic
non-cancer TOSHI 2
Estimated
annual
cancer
incidence
(cases per
year)
Based on
actual
emissions
level
Based on
allowable
emissions
level
0.02
0.6
3
Maximum
screening
acute
non-cancer
HQ 3
30
1 Estimated
maximum individual excess lifetime cancer risk due to HAP emissions from the source category.
TOSHI. The target organ with the highest TOSHI for the Secondary Lead Smelting source category is the kidney.
maximum HQ acute value of 30, driven by emissions of arsenic, is based on the only available acute dose-response value available for
arsenic, which is the REL. See Section III.B of this preamble for explanation of acute dose-response values.
2 Maximum
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3 The
The results of the chronic inhalation
cancer risk assessment indicate that,
based on estimates of current actual
emissions, the maximum individual
lifetime cancer risk (MIR) could be up
to 50-in-1 million, with fugitive dust
emissions of arsenic, and to a lesser
extent fugitive dust emissions of
cadmium (see below), driving these
risks. The total estimated cancer
incidence from this source category
based on actual emission levels is 0.02
excess cancer cases per year or one case
in every 50 years, with emissions of
arsenic and cadmium contributing
73 percent and 15 percent respectively,
to this cancer incidence. In addition, we
note that approximately 1,500 people
are estimated to have cancer risks
greater than 10-in-1 million, and
approximately 128,000 people are
estimated to have risks greater than
1-in-1 million. When considering the
risks associated with MACT-allowable
emissions, the MIR could be up to
200-in-1 million.
The maximum modeled chronic noncancer TOSHI value is 0.6 based on
actual emissions, driven primarily by
fugitive dust emissions of arsenic. When
considering MACT allowable emissions,
the maximum chronic non-cancer
TOSHI value could be up to 3.
Based on using the acute REL to
assess possible acute non-cancer effects
due to emissions of arsenic, our
screening analysis estimates that the
maximum acute HQ value for a facility
in this source category could be up to
30. Moreover, this analysis estimates
that acute HQ values could exceed a
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value of 1 at nine facilities.21 These
exceedances are mainly due to fugitive
emissions at most of these nine
facilities. However, stack emissions,
while generally not the principle driver
of maximum acute HQ values greater
than 1, contribute about 90 percent of
the risk at the facility which has the
maximum acute HQ screening value of
30. We note that the California REL is
the only acute value available, and we
request comments on the use of this
value as well as comments on the
existence of other peer reviewed values
that may be used to inform acute risks.
In summary, the analysis indicates
that arsenic and cadmium emissions
pose risks to public health due to
inhalation exposures resulting from
both fugitive and stack emissions (see
above). Lead and dioxin and furan
emissions also pose risks to public
health, but these HAP are assessed
separately as part of multipathway
assessments described below. Based on
our risk assessment, no other HAP were
identified as contributing significant
risks.
With respect to the potential for
adverse environmental effects from non
PB–HAP, we note that that there is a
lack of information about specific
adverse environmental effects occurring
at a given concentration of HAP for this
source category. However, given that all
chronic non-cancer HQ values
considering actual emissions are less
21 Individual facility acute HQ values for all
facilities can be found in Appendix 5, Table 3, of
the risk assessment document that is included in
the docket for this proposed rulemaking. Acute HQ
values exceeding a value of 1 were as follows: 2,
2, 2, 3, 4, 5, 6, 20 and 30.
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than 1 using human health reference
values, we believe that it is unlikely that
adverse environmental effects would
occur at the actual HAP concentrations
estimated in our human health risk
assessment.
2. Multipathway Risk Assessments and
Results
As noted above, in evaluating the
potential for multipathway effects from
emissions of lead, we compared
modeled maximum 3-month rolling
average lead concentrations (based on
estimates of actual emissions) with the
lead NAAQS. Results of this analysis
indicate that, if current emission levels
continue, the lead NAAQS could be
exceeded at 12 of the 14 facilities and
that nine facilities could have ambient
levels that are at least 2–3 times above
the NAAQS, largely due to actual
fugitive dust emissions. Moreover,
available ambient monitoring data for
lead confirms that ambient air
concentrations of lead are well above
the lead NAAQS near seven of these
facilities. As described in the technical
document Draft Summary of Ambient
Lead Monitoring Data near Secondary
Lead Smelting Facilities, which is
available the docket, the measured
ambient levels (for 3-month maximum
rolling concentrations) for year 2010
range from 1.00 to 0.26 μg/m3 for the
seven facilities, and for year 2008, the
measured values were up to 2.49 μg/m3.
When considering actual stack
emissions only (i.e., in the theoretical
absence of fugitive dust emissions), we
estimate that one facility would be
about 3 times above the NAAQS.
Moreover, we estimate that the risks
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associated with MACT-allowable stack
emissions would be significantly higher.
For example, we estimate that based on
MACT-allowable emissions from stacks
alone (not including fugitive dust
emissions), the ambient lead
concentrations could be about 10 times
above the NAAQS at two facilities.
Considering the results presented
above, fugitive dust emissions, and to a
lesser extent emissions from stacks,
resulted in modeled lead concentrations
above the NAAQS. We also note when
considering all emissions (i.e., stack and
fugitive dust emissions), our analysis
indicates that maximum off-site
3-month rolling average lead
concentrations could be up to 20 times
the lead NAAQS near one facility’s
fenceline.22
To evaluate the potential for adverse
environmental effects from lead, we
compared modeled maximum 3-month
rolling average lead ambient air
concentrations with the current
secondary lead NAAQS, which is
identical to the primary, public healthbased standard (see Section III.B.3 of
this preamble). Thus, our analyses
discussed above also indicate the
potential for adverse environmental
effects from emissions of lead.
As noted above (section III.B.4), based
on a multipathway screening analysis
for emissions of non-lead PB–HAP from
this source category, emissions of
cadmium, dioxins and furans, and POM
were all above the de minimis emissions
rates that suggest the potential for nonnegligible (i.e., greater than 1-in-1
million cancer risk or greater than a
noncancer hazard quotient of 1) risk of
adverse health effects from
multipathway exposures.23 With regard
to mercury, emissions are quite low for
this category. In fact, most emissions
tests for mercury for this source category
were below MDL. Nevertheless, using
conservative worst-case assumptions
(e.g., assuming all non-detects for
mercury were equal to the detection
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22 Secondary
lead smelting modeled ambient lead
concentrations for all facilities can be found in
Table 3.2–3 of the risk assessment document that
is included in the docket for this proposed
rulemaking. Facilities with modeled ambient lead
concentrations exceeding the NAAQS did so by 23,
19, 10, 6, 5, 4, 4, 3, 3, 1.5, 1.4 and 1.3 fold.
23 For facilities in this source category: Cadmium,
BaP, dioxins and furans, and mercury estimated
emission rates were up to about 8, 24, 23,000, and
4 times above their respective de minimis emissions
rates.
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limit, as described in Sections IV.A and
IV.B of this preamble), we estimated
that mercury emissions could be above
the de minimis emissions rates
described above (see Section III.B of this
preamble).
As a result of this conservative
screening analysis, we performed two
detailed case study multipathway
analyses for these four PB–HAP in areas
near the Frisco Recycling (Frisco, TX)
and Revere Smelting & Refining
(Middletown, NY) facilities.24
Moreover, as previously mentioned
above (section III.B.4), in order to more
fully characterize the potential
multipathway risks associated with high
end consumption of PB–HAP
contaminated food, we present results
based on RME and CTE scenarios. The
RME scenario utilizes 90th percentile
ingestion rates for farmers, recreational
anglers, and for three subpopulations of
recreational anglers) who have higher
rates of fish consumption (Hispanic,
Laotian, and Vietnamese descent), while
the CTE scenario utilizes mean
ingestion rates for each of these groups.
We provide results from both scenarios
to illustrate the range of potential
modeled exposures and risks that may
exist in the high-end of the complete
distribution of potential multipathway
risks for this source category.
Considering the RME scenario, results
of this analysis estimate the MIR for
dioxin to be 30 in a million (based on
Laotian anglers near the Frisco, TX
facility). Using the CTE scenario, the
maximum individual cancer risk from
dioxins is estimated to be 6 in a million
(also for Laotian anglers near the Frisco,
TX facility). We note that, for the entire
distribution of recreational anglers, the
individual risk estimates for the CTE
and RME scenarios ranged from 3 to 7
in a million. Considering both exposure
scenarios, the MIR for POM was less
than 1 in a million. With respect to
chronic noncancer risk, in both case
24 24 As previously noted above, the reasons that
EPA selected these two facilities for analysis are
described in detail in section 2.5.1 of the document
Human Health Multipathway Residual Risk
Assessment for the Secondary Lead Smelting
Source Category, which can be found in the docket
for the proposed rule. The selection criteria for
modeling these two facilities included emissions
rates of PB–HAPs, proximity to water bodies,
proximity to farmland, average rainfall, average
wind speed and direction, smelting furnace type,
local change in elevation, and geographic
representativeness of sites throughout the U.S.
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29053
studies, using both exposure scenarios,
we did not estimate chronic HQ values
greater than 1 for dioxin, mercury (even
using the conservative emission
assumptions just mentioned above) or
cadmium. Detailed methods and results
of the multipathway analysis are
presented in the document Human
Health Multipathway Residual Risk
Assessment for the Secondary Lead
Smelting Source Category, which can be
found in the docket for the proposed
rule.
With respect to the potential for
adverse environmental effects from the
non-lead PB–HAP included in the case
study multipathway assessments
described above (i.e., multipathway
assessment for cadmium, dioxins and
furans, POM, and mercury), similar to
non PB–HAP, there is a lack of
information about specific adverse
environmental effects occurring at a
given concentration for these pollutants.
However, given that the multipathway
assessments for these pollutants
estimated that all chronic non-cancer
HQ values are less than 1 using human
health reference values, we believe that
it is unlikely that adverse environmental
effects would occur at the PB–HAP
concentrations estimated in the
multipathway assessment.
3. Facility-Wide Risk Assessment
Results
For this source category, there are no
other significant HAP emissions sources
present. All significant HAP sources
have been included in the source
category risk analysis. Therefore, we
conclude that the facility-wide risk is
essentially the same as the source
category risk and that no separate
facility-wide analysis is necessary.
4. Demographic Risk Analysis Results
To identify specific groups that may
be affected by this rulemaking, EPA
conducted demographic analyses. These
analyses provide information about the
demographic makeup of populations
with: (1) Estimated cancer risks at or
above 1-in-1 million; and (2) estimated
ambient air lead concentrations above
the NAAQS for lead. Results are
summarized in Table 4 of this preamble
and are based on modeling using
estimated actual emissions levels for the
populations living within 50 km of any
secondary lead smelting facility.
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TABLE 4—SECONDARY LEAD SMELTING DEMOGRAPHIC RISK ANALYSIS RESULTS
Population
Nationwide
Total population ...............................................................................................................
Population
with ambient
air lead
concentrations
exceeding
the NAAQS
Population
with cancer
risk greater
than 1-in-1
million
285,000,000
128,000
500
75
25
58
42
94
6
75
12
0.9
12
58
7
0.8
34
94
2
0.6
3
14
86
56
44
5
95
13
87
22
78
10
90
27
32
26
Race by percent
White ................................................................................................................................
All Other Races ...............................................................................................................
Race by percent
White ................................................................................................................................
African American .............................................................................................................
Native American ..............................................................................................................
Other and Multiracial .......................................................................................................
Ethnicity by percent
Hispanic ...........................................................................................................................
Non-Hispanic ...................................................................................................................
Income by percent
Below poverty level ..........................................................................................................
Above poverty level .........................................................................................................
Children
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Children, Ages 0–18 ........................................................................................................
Results of the cancer risk assessment
indicate that there are approximately
128,000 people exposed to a cancer risk
greater than 1-in-1 million. For
informational purposes, it can further be
determined that about 42 percent of this
population can be classified as a
minority (listed as ‘‘all Other Races’’ in
the table), which is above the national
percentage of 25 percent. More
specifically, this analysis estimates a
greater percentage of this population is
‘‘Hispanic’’ (56 percent) and ‘‘Other and
Multiracial’’ (34 percent) when
compared to the corresponding national
percentages (14 percent and 12 percent,
respectively). We also note that in the
cancer demographics analysis there is a
larger percentage of individuals ‘‘Below
Poverty Level’’ (22 percent) when
compared to the national percentage (13
percent). In contrast, this analysis
estimates the percentage of those
classified as ‘‘African American’’ (7
percent) and ‘‘Native American’’ (0.8
percent) to be below corresponding
national percentages (12 and 0.9
percent, respectively).
With respect to lead, the risk analysis
estimates that 500 people are living in
areas around this source category with
modeled ambient air lead
concentrations above the NAAQS for
lead. The lead demographics analysis
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estimates that about 6 percent of this
population can be classified as a
minority (listed as ‘‘all Other Races’’ in
the table). Moreover, all minority or
below the poverty level populations
considered in the demographics
analysis for lead are below the
corresponding national percentages for
these groups.
Moreover, given the extent to which
lead may impact children’s health, we
further note that our demographic
analysis doesn’t indicate the presence of
a higher percentage of children than one
would normally expect around facilities
in this source category. The national
percentage of people who are children
18 years and younger is 27 percent; the
percentage of people who are children
18 years or younger living near
secondary lead smelting facilities who
are estimated to be exposed to lead
concentrations above the lead NAAQS
is 26 percent (see Risk and Technology
Review—Analysis of Socio-Economic
Factors for Populations Living Near
Secondary Lead Smelting Facilities in
the docket for this proposed
rulemaking).
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C. What are our proposed decisions
based on risk acceptability and ample
margin of safety?
1. Risk Acceptability
As noted in Section III.C of this
preamble, we weigh all health risk
factors in our risk acceptability
determination, including cancer risks to
the individual most exposed, risk
estimation uncertainty, and other health
information, including population risks
and risks for non-cancer health effects.
The following sections discuss our
decisions on risk acceptability based on
three analyses: (1) Comparison of
modeled ambient lead concentrations
with the lead NAAQS, (2) the inhalation
risk assessment, and (3) the
multipathway risk assessment.
a. Comparison of Modeled Ambient
Lead Concentrations With the Lead
NAAQS
With regard to lead emissions,
because ambient air lead concentrations
resulting from current emissions from
nine facilities were estimated to be well
above the lead NAAQS, the risks
associated with lead emissions from this
source category are judged to be
unacceptable. Based on our modeling
analysis, we estimate that ambient air
lead concentrations near the facility
boundary resulting from actual
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emissions from one of these facilities
could be as high as 20 times above the
lead NAAQS, due primarily to fugitive
dust emissions. Additionally,
approximately 500 individuals could be
exposed to three-month-rolling average
lead concentrations in excess of the
NAAQS due to emissions from this
source category. Moreover, we estimate
that the risks would be significantly
higher based on MACT-allowable
emissions of lead from this source
category. Exposure to levels this much
in excess of a primary NAAQS raises
obvious issues of adequacy of protection
afforded by the current MACT standard.
Among other things, the lead NAAQS
was set to ‘‘provide increased protection
for children and other at-risk
populations against an array of adverse
health effects, most notably including
neurological effects in children,
including neurocognitive and
neurobehavioral effects’’ (73 FR 67007).
EPA is thus proposing that these
ambient lead levels need to be reduced
to provide protection to public health
with an ample margin of safety.
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b. Inhalation Risk Assessment
Based on the inhalation risk
assessment, we estimate that the cancer
risks to the individual most exposed
could be as high as 50-in-1 million due
to actual emissions and as high as 200in-1 million due to MACT-allowable
emissions, mainly due to arsenic stack
emissions and, to a lesser extent,
cadmium emissions. We estimate that
the incidence of cancer based on actual
emissions is 0.02 excess cancer cases
per year, or one case every 50 years.
Based on these results, we conclude that
the cancer risks due to MACT-allowable
emissions from this source category are
unacceptable. The cancer risks due to
actual emissions are below 100-in-1
million and population risks are
relatively low. Therefore, cancer risks
due to actual emissions are considered
acceptable.
With respect to potential acute noncancer health risks, we estimate that,
based on our screening analysis, the
worst-case HQ value could be up to 30
(based on the REL) at one facility, due
primarily to arsenic emissions.
Additionally, we estimated that nine
facilities had potential worst-case HQs
greater than 1 in our screening analysis,
also due primarily to arsenic emissions.
These results suggest that arsenic
emissions have the potential to cause
acute non-cancer health effects.
However, the worst-case nature of our
acute screening assessment suggests that
the potential for these effects carries a
relatively low probability of occurrence.
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Nevertheless, we seek comments
regarding this conclusion.
c. Multipathway Risk Assessment
Based on our multipathway risk
assessment, we estimate that the MIR for
cancer using a reasonable maximum or
a central tendency exposure scenario
(see above) could be up to 30-in-1
million and 6-in-1 million respectively,
due to actual emissions of dioxins and
furans. Because the MIR is less than the
100-in-1 million threshold, we conclude
that the risks due to actual dioxin and
furan emissions are acceptable. Because
emissions of other HAP (i.e., cadmium
and POM) analyzed in the
multipathway risk assessments did not
result in MIRs above 1-in-1 million, we
also conclude that the risks due to
emissions of these HAP are acceptable.
d. Summary of Conclusions
In summary, we conclude that, based
on our lead NAAQS analysis, the risks
due to lead emissions under the MACT
standard for this source category are
unacceptable. Based on the inhalation
risk assessment, we conclude that
cancer risks associated with MACTallowable emissions from this source
category are unacceptable, primarily
due to arsenic emissions from stacks,
and to a lesser extent cadmium
emissions. The cancer risks associated
with actual emissions from this source
category were determined to be
acceptable, but will be investigated
further in the ample margin of safety
analysis because the risks are greater
than 1-in-1 million, primarily due to
fugitive emissions of arsenic and
cadmium.
We will also evaluate the arsenic
emissions further under the ample
margin of safety because of the potential
for acute non-cancer risks. Lastly, the
risks from emissions of all HAP
considered in the multipathway
assessment are acceptable. Nevertheless,
as described in section 2 below, we
evaluate the HAP further under the
ample margin of safety analysis.
2. Proposed Controls and Analysis of
the Resulting Risk
a. Allowable Stack Emissions
In order to ensure that the risks
associated with MACT-allowable stack
emissions from this source category are
acceptable, the MIR, resulting primarily
from allowable stack emissions of
arsenic, would need to be reduced by at
least a factor of 2 (i.e., from 200-in-1
million to 100-in-1 million or lower).
Also, based on our analyses, MACT
allowable emissions of lead from stacks
alone (not including fugitive dust
emissions) could result in ambient lead
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29055
concentrations about 10 times above the
NAAQS for two facilities. Because the
controls for stack emissions of arsenic
are the same as those for lead, and
because the relationship between
emissions and the MIR and ambient air
lead concentrations is predominantly
linear, we estimated that the current
stack lead concentration limit would
need to be reduced by approximately an
order of magnitude to ensure acceptable
risk from MACT-allowable emissions of
lead and arsenic from this source
category. Therefore, we considered
lowering the existing lead concentration
limit by an order of magnitude (i.e.,
from 2.0 mg/dscm to 0.2 mg/dscm) for
all stacks. We also considered different
forms of a revised lead emissions limit
that would achieve similar reductions in
MACT-allowable emissions. However,
based on a combination of data analysis,
evaluation of each facility’s processes,
and communication with the industry,
we have determined that a
concentration-based limit continues to
be the most appropriate form for this
source category.
We also evaluated an approach that
would implement a facility-wide, flowweighted average lead concentration
limit of 0.20 mg/dscm with a maximum
concentration limit of 1.0 mg/dscm for
any individual stack. For the 0.2 mg/
dscm flow-weighted average limit,
facilities would assign a weighting
factor to the measured lead
concentrations of each stack based on
the exhaust flow rates of each control
device. The sum of all the flowweighted concentrations at each stack
within a facility would then be
calculated and compared to the
proposed limit to demonstrate
compliance. A limit in this form would
ensure that the risks associated with
MACT-allowable stack emissions of lead
and arsenic from this source category
are acceptable, and that the rule
provides an ample margin of safety,
while providing flexibility to the
facilities in determining the most
efficient approach to achieve the
necessary reductions. Proposing a
maximum concentration limit of 1.0 mg/
dscm for any individual stack will also
ensure that stack emissions of lead from
any one stack in this source category
will not result in exceedances of the
lead NAAQS. Furthermore, our analysis
of available control technologies,
presented in Section IV.D of this
preamble, confirms that this is a
technologically feasible standard.
For these reasons, under the authority
of CAA section 112(f)(2), we are
proposing a facility-wide, flow-weighted
average lead concentration limit of 0.20
mg/dscm to cover all stacks in this
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source category. We are also proposing
a maximum lead concentration limit of
1.0 mg/dscm to apply to any individual
stack at existing facilities. For new
sources, we are proposing that a limit of
0.20 mg/dscm applies to all individual
stacks at the facility. As in the existing
MACT standard, compliance for existing
sources will be demonstrated by annual
stack testing and installation and
operation of BLDSs for both new and
existing sources.
We are also proposing that new
affected sources would be required to
demonstrate compliance using a lead
continuous emissions monitoring
systems (CEMS).25 However, since the
Agency has not finalized the
performance specification for the use of
these instruments, we are deferring the
effective date of the requirement to
install, calibrate, maintain and operate
lead CEMS until these actions can be
completed. The lead CEMS installation
deadline will be established through
future rulemaking, along with other
pertinent requirements. In the event
operations commence at a new affected
source prior to promulgation of the
performance specification, compliance
would be demonstrated through annual
stack testing and installation of a BLDS
until promulgation of the lead CEMS
performance specification. With regard
to existing sources, we considered the
possibility of proposing CEMs as the
method to demonstrate compliance with
the MACT limits. However, since the
Agency has not yet finalized the
performance specification for this
method and since the costs could be
high for applying this technology to
multiple stacks, we are not proposing a
requirement for CEMs for existing
sources. However, we are allowing the
option of a CEMS in lieu of annual stack
tests for lead for existing sources in this
industry when the technology is
available and the EPA has established
performance specifications. We are
seeking comments and information on
the feasibility of applying this
technology for monitoring lead
emissions from these sources and the
potential to require CEMs on existing
sources in this source category.
Nevertheless, depending on comments
received and other factors we may
25 We do not believe that use of a lead CEM to
meet the flow-weighted average of 0.2 mg/dscm
poses issues of feasibility, even though our present
data for the source data comes from stack tests
rather than continuous measurements. This is
because so many sources are achieving levels
considerably less than 0.2 mg/dscm in their
performance tests. (See ‘‘Summary of the
Technology Review for Secondary Lead Smelters’’,
which is available in the docket.)
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consider requiring CEMs for existing
sources in the future, if appropriate.
b. Fugitive Dust Emissions
As described in Section IV.C.1 of this
preamble, we have determined that
fugitive dust emissions must be reduced
such that ambient lead concentrations
near the facility boundaries are below
the lead NAAQS (i.e., 0.15 mg/dscm).
Based on our review of information
submitted in the ICR, we have identified
a combination of specific fugitive
control measures that are generally able
to achieve lead concentrations near the
boundaries of facilities that are below
the lead NAAQS (see Draft Technology
Review for the Secondary Lead Smelting
Source Category). These controls
include total enclosure of process
fugitive emissions sources and material
storage and handling areas and
implementation of a list of prescribed
work practices to further limit the
formation of fugitive dust in other areas
of the facilities. Examples of these
prescribed work practices include:
Pavement of all grounds on the facility
or sufficient groundcover to prevent
wind-blown dust, monthly cleaning of
building rooftops, timely cleaning of
any accidental releases, inspection of
battery storage areas outside of
enclosures for broken batteries, and
performance of maintenance on
equipment that may be contaminated
with lead inside total enclosures. Our
analysis indicates that these controls are
necessary to ensure that three-month
rolling average lead concentrations near
the boundaries at all facilities in this
source category do not exceed the lead
NAAQS. Furthermore, our analysis of
available control technologies in Section
IV.D of this preamble confirms that this
is a technologically feasible standard for
this source category.
For the reasons described above, we
are proposing under CAA section
112(f)(2) that each facility must totally
enclose the following emissions sources
and operate the total enclosure under
negative pressure:
(1) Smelting furnaces;
(2) Smelting furnace charging areas;
(3) Lead taps, slag taps, and molds
during tapping;
(4) Battery breakers;
(5) Refining kettles, casting areas;
(6) Dryers;
(7) Agglomerating furnaces and
agglomerating furnace product taps;
(8) Material handling areas for any
lead bearing materials (drosses, slag,
other raw materials), excluding areas
where unbroken lead acid batteries and
finished lead products are stored; and
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(9) Areas where dust from fabric
filters, sweepings or used fabric filters
are handled or processed.
The ventilation air from the total
enclosures must be conveyed to a
control device. We are also proposing
that the emissions from the enclosure
control devices will be subject to the
proposed stack lead emissions limits
described in this section.
In addition, we are proposing that
facilities must implement the following
fugitive control work practices:
Pavement cleaning and vehicle washing;
cleaning of building rooftops on a
regular schedule (e.g., at least once per
month); cleaning of all affected areas
after accidental releases; inspection of
the battery storage areas for broken
batteries; performance of maintenance
activities inside enclosures; and
transport of lead bearing material in
closed systems. Additionally, each
facility will be required to prepare, and
at all times operate according to, a SOP
manual that describes in detail how the
additional work practices will be
implemented.
We acknowledge that there may be
other control measures and alternative
approaches that we have not identified
that are effective in reducing fugitive
dust emissions at other facilities.
Therefore, as an alternative to the
requirement for full enclosure, we are
proposing under CAA section 112(f)(2)
that facilities may choose to implement
the work practices, maintain partial
enclosures and enclosure hoods as the
1997 NESHAP requires, prepare an SOP
as described above and establish an
ambient air monitoring network to
ensure that lead concentrations in air
near the facility boundaries remain at or
below 0.15 μg/m3 based on 3-month
rolling averages (the level and averaging
time of the lead NAAQS). The
monitoring plan must include a
minimum of two monitoring sites that
are placed in locations that are most
likely to capture measurements of the
maximum concentrations at or near the
facility boundaries. For example, at least
one monitor must be placed in the
predominant downwind direction from
main emissions sources based on
historical weather patterns in the area.
This alternative regulatory requirement
based on partial enclosures, work
practices plus monitoring lead
concentrations in air would provide
flexibility to facilities in determining
the within-facility sources that should
be enclosed and vented to a control
device that are most effective for
reducing fugitive emissions at their
facilities. These proposed requirements
will ensure that the risks associated
with fugitive lead emissions from this
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source category are acceptable.
Nevertheless, we are seeking comments
on this proposed alternative
requirement, including whether two
monitors would be sufficient or if more
monitors may be warranted.
If this alternative approach is chosen
by the facility, the work practices and
SOP along with the lead concentration
in air monitoring would be established
as the enforceable requirements to
address fugitive emissions under the
NESHAP. For both new and existing
facilities, compliance with the lead
concentration in air monitoring
component would be demonstrated
based on rolling 3-month average
concentrations as measured by the lead
compliance monitoring devices,
consistent with the averaging time of the
lead NAAQS (see documentation for
EPA’s Lead NAAQS, available at:
https://www.epa.gov/ttnnaaqs/
standards/pb). We are proposing that
approval by EPA is required for each
source electing to comply by means of
this alternative approach that includes a
monitoring network plus work practices
rather than compliance based on full
enclosure plus work practices. Thus, the
proposed alternative requires
development of a monitoring plan for
approval by the Administrator that
includes the minimum sampling and
analysis methods and compliance
demonstration criteria. Under this
alternative, facilities would also be
required to provide a work practice SOP
manual to the Administrator.26
As part of this alternative, we are also
proposing a provision that would allow
for reduced monitoring if the facility
demonstrates ambient lead
concentrations less than 50 percent of
the ambient lead concentration limit for
three consecutive years at each monitor.
We propose that a revised monitoring
plan may be submitted (for review and
possible approval by the Administrator)
to reduce the sampling and analysis
frequency if all of the 3-month rolling
average concentrations at each monitor
are less than 50 percent of the limit of
0.15 μg/m3 over a 3-year period. The
monitoring requirements discussed
above were designed to allow for
flexibility, prevention of redundant
requirements, and also to provide
consistency with current monitoring
26 The proposed lead concentration in air
alternative appears to be an ‘‘emissions standard’’,
as required by section 112 (f)(2), since it ‘‘limits the
quantity, rate, or concentration’’ of lead—to the
level of the NAAQS at a location of maximum
exposure—albeit compliance with the standard is
measured by means of ambient monitoring. CAA
section 302 (k). Nonetheless, EPA solicits comment
on this issue.
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programs that may be required at some
of the facilities in this source category.
c. Risks Considering Proposed Control
Options
We conducted an assessment to
estimate the risks based on a postcontrol scenario reflecting the proposed
requirements for stack and fugitive
emissions described above. (Details are
provided in the Draft Risk Assessment
report which is available in the docket
for this action). Based on that modeling
assessment, we estimated that the
ambient lead concentrations would be at
or below the lead NAAQS for all
facilities once this rule is fully
implemented, except for possibly one
facility in California. Our modeling
analysis indicated that this one facility
in California may still be above the lead
NAAQS after controls. Therefore, we
gathered additional information and did
further evaluation of this facility. Based
on communications with the company,
it is our understanding that the facility
is currently constructing an additional
enclosure of certain equipment (e.g.,
baghouse row, abatement equipment,
and slurry tanks) that we had not
included in our post-control scenario.
Moreover, it is our understanding that
the company has recently implemented,
or is currently implementing, other
measures (e.g., repaired asphalt and
additional cleaning of road surfaces)
that will significantly reduce their
fugitive emissions further as part of
their efforts to comply with a California
State regulation (reference: based on
verbal communications during meeting
with Exide Corporation on February 23,
2011, in RTP, NC; and a phone
conversation on April 25, 2011). The
California regulation has a compliance
deadline of late 2011 and requires that
ambient concentrations of lead near this
facility remain at or below 0.15 μg/m3
per 3-month rolling averages. Therefore,
we conclude that this facility will
achieve levels at or below the NAAQS.
In summary, we are proposing that
the MACT standard, with the changes
we are proposing under the CAA section
112(f)(2) residual risk review, will
reduce risks from fugitive lead
emissions to an acceptable level.
Our analysis indicates that the MIR
for cancer due to inhalation exposure
associated with actual emissions from
this source category would be reduced
from 50-in-1 million to 10-in-1 million
as a result of the actions proposed under
112(f)(2), while the MIR from MACTallowable emissions would be reduced
from 200-in-1 million to 10-in-1 million.
The cancer incidence rate will be
reduced from 0.02 to 0.01. Furthermore,
the maximum worst-case screening
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acute HQ value will be reduced from
potentially as high as 30 to less than or
equal to 5. Based on these metrics, the
actions proposed above under CAA
section 112(f)(2) ensure acceptable risks
from actual and MACT-allowable stack
emissions of all HAP for this source
category.
3. Ample Margin of Safety
Under the ample margin of safety
analysis, we evaluate the cost and
feasibility of available control
technologies and other measures
(including the controls, measures and
costs reviewed under the technology
review) that could be applied in this
source category to further reduce the
risks due to emissions of HAP identified
in our risk assessment. We estimate that
the actions proposed under CAA section
112(f)(2), as described above, will
reduce the MIR associated with arsenic
and cadmium from 200-in-1 to 10-in-1
million for MACT-allowable emissions
and from 50-in-1 to 10-in-1 million for
actual emissions. The cancer incidence
will be reduced from 0.02 to 0.01 and
the maximum acute HQ value will be
reduced from potentially up to 30 to less
than or equal to 5. Although these risks
are considered acceptable based on the
100-in-1 million threshold established
in the Benzene NESHAP, the MIR
remains greater than 1-in-1 million, due
primarily to fugitive emissions of
arsenic and cadmium. Also, the
maximum acute non-cancer HQ could
be up to 5. Our ample margin of safety
analysis is provided below. We have
performed these analyses for emissions
sources of the following five groups of
HAP for which standards were proposed
in today’s action: (1) Arsenic and
cadmium, (2) lead compounds, (3)
dioxins and furans, (4) organic HAP,
and (5) mercury compounds. The results
of these analyses are presented in the
following sections.
a. Arsenic and Cadmium Emissions
Because the estimated MIR of 10-in-1
million remaining after implementation
of our proposed revisions to the MACT
standard is driven primarily by fugitive
emissions of arsenic and cadmium, we
performed an ample margin of safety
analysis on these emissions. Based on
our research and analyses, we have not
identified any feasible control options
beyond what we are requiring in our
proposed standards for fugitive
emissions sources described above, and
are therefore not proposing additional
fugitive controls based on our ample
margin of safety analysis. Nevertheless,
we are soliciting comments and
information regarding additional
fugitive control measures, work
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practices that may be available and their
feasibility in further reducing fugitive
emissions of metal HAP, or additional
monitoring that may be warranted to
ensure adequate control of fugitive
emissions.
We also conducted additional
analyses to determine whether
reductions in stack emissions of arsenic
and cadmium emissions beyond those
required by our proposed standards are
appropriate and necessary to provide an
ample margin of safety. We identified
one control technology that could
achieve reductions beyond those that
will occur due to the actions we are
proposing under CAA section 112(f)(2),
which are described above. The device
is a wet electrostatic precipitator
(WESP) that provides an estimated lead
control efficiency of greater than 99
percent on the outlet of the baghouse.
The combination of the baghouses with
the WESP achieves greater than 99.99
percent control efficiency (see: Wet
Electrostatic Precipitator (WESP)
Control for Meeting Metals Emissions
Standards). This technology is currently
used at one facility in California.
However, this control configuration is
quite expensive. We estimated that
installing a WESP at the other 13
facilities would result in total capital
costs to the industry of $400 million and
a total annualized cost of $55 million.
We estimate that the cost-effectiveness
would be about $4.0 million per ton of
reductions in metal HAP emissions
(mainly lead compounds). A detailed
analysis of the costs associated with the
WESP unit can be found in the technical
document for this action available in the
docket (see Draft Cost Impacts of the
Revised NESHAP for the Secondary
Lead Smelting Source Category). Stack
emissions of arsenic and cadmium do
not appreciably contribute to the 10-in1 million cancer risks remaining after
implementation of the proposed
revisions. Moreover, we conclude that
the likelihood of significant noncancer
effects due to arsenic emissions (after
the proposed controls described above
are in place) is very low because the
maximum acute noncancer HQ (which
could be as high as 5) is based on a very
conservative analysis using some worst
case assumptions. Furthermore, the
costs for these additional controls are
high. Therefore, we are not proposing a
requirement for the installation of a
WESP under this ample margin of safety
analysis.
b. Lead Emissions
With regard to emissions of lead, by
lowering the facility-wide emissions
limit to a flow-weighted average of 0.20
mg/dscm, limiting the emissions from
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any one stack to no more than 1.0 mg/
dscm, and requiring facilities to either
fully enclose their facility and
implement comprehensive fugitive work
practices or implement comprehensive
fugitive work practices and lead air
monitoring, we conclude that the actual
and MACT-allowable lead emissions
from this source category would be
reduced to the point that they would not
result in off-site concentrations above
the NAAQS. Moreover, we have not
identified any further feasible and costeffective controls. See Section IV.C.2.a
of this preamble explaining that adding
a wet electrostatic precipitator as
supplementary HAP metal control
would be excessively costly and not
cost-effective. Moreover, as described
above, we have not identified other
measures (beyond those proposed
above) to further reduce fugitive
emissions. Thus, we are proposing that
revisions to the MACT standard that we
are proposing under CAA section
112(f)(2), as described above, will
provide an ample margin of safety with
regard to emissions of lead from this
source category.
c. Dioxin and Furan Emissions
With regard to dioxin and furan
emissions, as outlined in Section IV.A
of this preamble, we are proposing
various emissions limits under CAA
section 112(d)(3). Results of the
multipathway risk assessment indicate
that the cancer MIR associated with
dioxin and furan emissions is 30-in-1
million, less than the acceptability
threshold of 100-in-1 million. However,
because the MIR is greater than 1-in-1
million, we are required to investigate
whether reductions in emissions of
dioxins and furans beyond that required
in the limits we are proposing under
CAA section 112(d)(3) are needed to
provide an ample margin of safety to the
public.
We identified one option to reduce
emissions of dioxins and furans beyond
that required by the limits proposed in
today’s action. This option is the
installation of additional afterburner
capacity at the facilities operating blast
furnaces. We evaluated this option
because of the higher potential of
formation of dioxins and furans in the
blast furnace exhaust due to its
relatively cooler exit temperature. This
option would include operating the
currently installed afterburners at a
temperature of 1600 °F with a residence
time of 2.5 seconds, or installation of
new or additional afterburner capacity
with this capability. Based on the
current level of performance identified
in the ICR surveys, we believe that this
option would require four facilities to
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install additional afterburner capacity or
install new afterburners at their facility
in order to operate the units at these
conditions. The estimated total capital
cost for the additional controls is $5.9
million, with a total annualized cost of
$2.9 million. Based on an estimated
control efficiency of 98 percent, TEQ
emissions would be reduced by an
estimated 28 grams per year and organic
HAP emissions by 200 tons per year (see
Draft Cost Impacts of the Revised
NESHAP for the Secondary Lead
Smelting Source Category for a detailed
analysis). However, this option would
result in increases of NOX and CO2
emissions. Considering the costs
associated with this option, the
potential for increased emissions of
NOX and CO2, and the fact that risks
associated with emissions of dioxins
and furans are clearly less than 100-in1 million, we are not proposing this
option as part of our ample margin of
safety analysis. We also considered
various beyond the floor options for
establishing MACT limits for dioxins
and furans under the Section 112(d)(3)
review (as described in section IV.A.2),
but we are not proposing any of those
options in this action for the reasons
described in that section.
d. Organic HAP Emissions
With regard to organic HAP (other
than dioxins and furans), we estimate
that actual emissions do not result in a
cancer risk above 1-in-1 million at any
facilities in this source category. Given
that actual emissions from blast
furnaces do not result in a cancer risk
above 1-in-1 million in this source
category, and that the actual THC
emissions modeled from blast furnaces
were at levels close to the allowable
emissions, we conclude that the cancer
risk associated with actual and
allowable emissions of organic HAP
from all other furnace types are not
likely to be greater than 1-in-1 million
since the THC limit for blast furnaces is
considerably higher than for other
furnace types. The one exception is for
rotary furnaces, for which we are
proposing a THC limit (i.e., 610 ppmv)
in today’s action that is higher than the
limit in the 1997 NESHAP for blast
furnaces (i.e., 360 ppmv). Based on our
risk assessment, we estimate that the
highest possible MIR due to allowable
organic HAP emissions from the one
rotary furnace in operation today would
be 2-in-1 million (given the proposed
emissions limits in today’s action). This
is based on the conservative assumption
that this rotary furnace will
continuously emit THC at exactly 610
ppmv, which is a highly unlikely
scenario. Additionally, emissions of
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organic HAP from this source category
do not appreciably contribute to any
chronic-non cancer risk. For these
reasons, we are proposing that the
MACT standards for organic HAP, as
proposed in today’s action, provide an
ample margin of safety.
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e. Mercury Emissions
Lastly, with regard to mercury
emissions from this source category, our
risk assessment indicates that, even
based on our highly conservative
estimates of mercury emissions (see
Section III.B.7 of this preamble for
further discussion on the conservative
nature of our mercury emissions
estimates), emissions of mercury did not
appreciably contribute to risk based on
both the inhalation and multipathway
risk analyses. Given that the work
practice standard proposed in today’s
action for mercury is based on actual
performance of the industry, we are
proposing that these standards provide
an ample margin of safety with regards
to risk from mercury emissions from
this source category.
D. What are the results and proposed
decisions based on our technology
review?
Based on our technology review, we
determined that there have been
advances in emissions control measures
since the Secondary Lead Smelting
NESHAP was originally promulgated in
1997. Since promulgation, we estimate
that industry-wide metal HAP emissions
(including lead) from process and
process fugitive sources have been
reduced by approximately 80 percent.
As a result, and due to other factors,
actual lead emissions from process and
process fugitive sources at most
secondary lead smelting facilities are
significantly lower than are allowed
under the 1997 NESHAP.
Based on our technology review, we
believe that the reductions in metal
HAP emissions since promulgation of
the 1997 NESHAP are mainly directly
related to improvements in two areas:
(1) Improvements in fabric filter control
technology (e.g., improved bag
materials, replacement of older
baghouses) and (2) total enclosure of
process fugitive emissions sources and
raw material storage and handling areas
and improvements in emissions controls
and work practices for fugitive dust
emissions sources. Additional
reductions have been achieved due to
the use of a WESP at one facility and
also HEPA filters in some cases. The
results of our analyses and our proposed
decisions for these areas under CAA
section 112(d)(6) are presented in the
following sections. Additional details
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regarding these analyses can be found in
the following technical document for
this action which is available in the
docket: Draft Technology Review for the
Secondary Lead Smelting Source
Category.
1. Fabric Filter Improvements
The improvements in fabric filter
control technology are reflected in the
emissions test data collected under the
ICR. The emissions limit for lead under
the 1997 NESHAP is a concentrationbased limit of 2.0 mg/dscm applicable to
all stacks whether they are classified as
process, process fugitives, or building or
enclosure ventilation systems. Based on
our analysis of survey responses and
test data collected under the ICR, this
industry primarily uses fabric filters to
control emissions of lead and other
metal HAP, and the vast majority of
sources affected by the current lead
limit are achieving lead concentrations
at control device outlets that are far
below the current limit (see: Draft
Technology Review for the Secondary
Lead Smelting Source Category). Several
facilities have also installed HEPA
filters downstream of their fabric filters
that have an estimated 99.97 percent
add-on control efficiency for particles
with an aerodynamic diameter of 0.3
microns. More than 95 percent of all
sources reported lead concentrations
(coming out of the stacks after the
control devices) that are less than half
of the current limit, with several sources
achieving lead concentrations that are
two to three orders of magnitude lower
than the current limit. Based on the
available data, the average lead outlet
concentration of all affected sources in
this source category is 0.16 mg/dscm,
with a median of 0.04 mg/dscm. Based
on these data, we believe that
developments in practices, processes,
and control technologies warrant
revisions to the 1997 NESHAP to reflect
emissions levels achieved in practice.
Our analysis of emissions data provided
in the ICR indicates that stacks
equipped with a well-performing fabric
filter can achieve exhaust lead
concentrations of less than 0.20 mg/
dscm (see: Draft Technology Review for
the Secondary Lead Smelting Source
Category). In fact, of the 93 stacks
identified in the ICR that are controlled
using a baghouse, 74 reported average
lead concentrations of less than 0.20
mg/dscm. Based on these data, we
considered the costs and feasibility of
revising the emissions limit down to
0.20 mg/dscm as a facility-wide, flowweighted average, identical to the limit
proposed under CAA section 112(f)(2)
in today’s action. We estimate that if we
proposed such a limit, two of the 14
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facilities would be required to replace
one of their large old baghouses with a
newer, more efficient baghouse in order
to comply. We estimate that this would
result in about 5.9 tons of reductions of
metal HAP emissions. We estimate that
the total capital costs would be about
$7.6 million with annualized costs of
$1.7 million and cost-effectiveness of
$0.3 million per ton of metal HAP (or
$150 per pound of metal HAP). As a cobenefit to implementation of this
revised standard, we estimate
reductions of 56 tons of PM at a costeffectiveness of $30,000 per ton of PM.
We do not anticipate additional energy
use associated with this revised limit, as
only replacement baghouses, as opposed
to new units, are anticipated.
Furthermore, we do not anticipate any
adverse non-air environmental impacts
associated with the implementation of
this revised limit.27
For the reasons described above,
under the authority of CAA section
112(d)(6), we are proposing a facilitywide, flow-weighted average lead
concentration limit of 0.20 mg/dscm to
cover all stacks. Additionally, because
89 of the 93 stacks identified in the ICR
that are controlled using a baghouse are
achieving lead concentrations below 1.0
mg/dscm, we conclude that this level of
emissions is technologically feasible
and demonstrated, therefore we are also
proposing a maximum lead
concentration limit of 1.0 mg/dscm to
apply to any individual stack at existing
facilities. For new sources, we are
proposing that the 0.20 mg/dscm limit
applies to all individual stacks at the
facility. Consistent with the standards
proposed under CAA section 112(f)(2)
in today’s action, compliance for
existing sources will be demonstrated
either by annual stack testing and
installation and operation of BLDS or by
use of a lead CEMS once performance
specifications have been promulgated.
New affected sources would be required
to demonstrate compliance using a lead
CEMS, pending promulgation of the
lead CEMS performance specifications.
Any new affected sources commencing
operations prior to promulgation of the
performance specifications may
demonstrate compliance through annual
stack testing and operation of a BLDS
until the CEMS performance
specifications are promulgated.
We believe that these proposed
revisions, identical to those proposed
under CAA section 112(f)(2), are costeffective revisions that reflect the level
27 As explained in section C above, we conclude
that requiring an additional wet electrostatic
precipitator as a form of supplementary metal
control at all facilities would be excessively costly
and not cost effective.
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of control achievable in practice by a
well performing fabric filter.
2. Total Enclosure of Process Fugitive
Sources and Raw Material Storage and
Handling Areas and Work Practices for
Fugitive Dust Sources
Facilities have achieved some of their
reductions since 1997 through total
enclosure of process fugitive emissions
sources and material storage and
handling areas. Based on responses to
the ICR survey, the process fugitive
emissions sources regulated under the
1997 NESHAP are totally enclosed and
vented to a control device at seven of
the 14 existing facilities. Additionally,
an eighth facility has a current project
to install total enclosures and associated
control devices for their process fugitive
emissions sources. This level of
enclosure is well beyond the
requirements of the 1997 NESHAP that
provides facilities the option of using
negative pressure hoods to capture
process fugitive emissions and route
them to a control device. The other six
facilities have some degree of enclosure,
but the extent of enclosure among these
six facilities varies considerably. With
regard to material storage and handling
areas, the ICR surveys indicate that all
of the facilities with process fugitive
emissions sources in total enclosures
have enclosed the storage areas for all
lead-bearing materials such as processed
raw materials and slag.
The information and data collected
under the ICR also indicate that at least
four facilities conduct work practices
beyond those required in the 1997
NESHAP to further limit the formation
of fugitive dust from material handling
operations and re-entrainment of lead
dust deposited within the facility fence
line. Examples of these work practices
include: pavement of all grounds on the
facility, monthly cleaning of building
rooftops, timely cleaning of any
accidental releases, inspection of battery
storage areas outside of enclosures for
broken batteries, and performance of
maintenance on equipment that may be
contaminated with lead inside total
enclosures.
We estimate that for the six facilities
to implement total enclosures with
negative pressure ventilation to their
process fugitive emissions sources, the
total capital cost would be about $40
million (about $6.7 million per facility)
with total annualized costs of about $6.4
million (or about $1.1 million per
facility). These controls would achieve
an estimated 5.3 tons reduction of metal
HAP (mainly lead compounds, but also
arsenic, and cadmium). Additionally, as
a co-benefit, these controls would
achieve an estimated 58 tons reduction
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of PM at a cost effectiveness of $100,000
per ton of PM. We do anticipate
approximately 23 million kilowatt hours
(KWH) of additional energy use
associated with the operation of
additional baghouses controlling the
building ventilation systems. However,
we do not anticipate any adverse nonair environmental impacts associated
with the implementation of these
potential controls. Additionally, for ten
facilities to implement the additional
fugitive control work practices
mentioned above, we estimate no
capital cost and a total annualized cost
of about $3.0 million (about $0.2 million
per facility). These work practices
would achieve an estimated 4.2 tons
reduction of metal HAP (mainly lead,
arsenic, and cadmium). Additionally, as
a co-benefit, these work practices would
achieve an estimated 46 tons reduction
of PM at a cost-effectiveness of $100,000
per ton of PM. The total cost
effectiveness of implementing total
enclosures with negative pressure
ventilation as well as additional fugitive
emissions control work practices is
estimated at $1.0 million per ton of
metal HAP (or $500 per pound of metal
HAP). Because the primary HAP
reduced are lead compounds, arsenic,
and cadmium, and given the co-benefit
PM reductions, we believe that these
costs and cost-effectiveness values are
reasonable.
Therefore, for the reasons described
above, we are proposing under CAA
section 112(d)(6) that each facility must
totally enclose the following emissions
sources and operate the total enclosure
under negative pressure:
(1) Smelting furnaces.
(2) Smelting furnace charging areas.
(3) Lead taps, slag taps, and molds
during tapping.
(4) Battery breakers.
(5) Refining kettles, casting areas.
(6) Dryers.
(7) Agglomerating furnaces and
agglomerating furnace product taps.
(8) Material handling areas for any
lead bearing materials (drosses, slag,
other raw materials), excluding areas
where unbroken lead acid batteries and
finished lead products are stored.
(9) Areas where dust from fabric
filters, sweepings or used fabric filters
are handled or processed.
The ventilation air from the total
enclosures must be conveyed to a
control device. We are also proposing
that the emissions from the enclosure
control devices be subject to the
proposed stack lead emissions limits
proposed in Section IV.D.1 of this
preamble and also previously under
CAA section 112(f)(2).
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Additionally, we are proposing under
CAA section 112(d)(6) that each facility
must implement the following fugitive
control work practices: pavement
cleaning and vehicle washing; cleaning
of building rooftops on a regular (e.g., at
least once per month) schedule;
cleaning of all affected areas after
accidental releases; inspection of the
battery storage areas for broken
batteries; performance of maintenance
activities inside enclosures; and
transport of lead bearing material in
closed systems.
For both new and existing facilities,
compliance with the total enclosure and
work practice requirements described
above would require construction of
total enclosures (where they do not
already exist) capable of being operated
under negative pressure and venting of
the enclosure exhaust to a control
device. Additionally, each facility
would be required to prepare, and at all
times operate according to, a SOP
manual that describes in detail how the
additional work practices will be
implemented. We believe this standard,
identical to that proposed under CAA
section 112(f)(2), is a cost-effective
control option that reflects the level of
fugitive control achieved in practice by
several facilities in this source category.
3. Alternative Compliance Option for
Fugitive Dust Emissions Under CAA
Section 112(d)(6)
Similar to the previous discussion
regarding the fugitive emissions limits
proposed in under CAA section
112(f)(2), we acknowledge that there
may be other control measures that we
have not identified that are effective in
reducing fugitive dust emissions at
other facilities. Therefore, as an
alternative to the requirements for full
enclosure, we are proposing under CAA
section 112(d)(6) that facilities may
choose to implement comprehensive
fugitive control work practices,
maintain the partial enclosures and
enclosure hoods required in the 1997
NESHAP, plus establish an air
monitoring network, similar to that
required in the lead NAAQS, to ensure
that fugitive emissions are minimized
and that lead concentrations in air near
the facility boundaries remain at or
below 0.15 μg/m3 based on 3-month
rolling averages. This compliance
alternative is identical to that proposed
under CAA section 112(f)(2). The
implementation of this proposed
alternative is thus identical and is
presented in Section IV.C of this
preamble.
For facilities that choose the
alternative compliance option for
fugitive dust emissions and do not
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install total enclosures, we are
proposing to keep the requirements for
enclosure hoods and partial enclosures
specified in the 1997 NESHAP in order
to ensure a level of containment for
process fugitive emissions. We are
seeking comment on other control
measures that should be prescribed for
facilities that choose the alternative
compliance option.
E. What other actions are we proposing?
jlentini on DSK4TPTVN1PROD with PROPOSALS2
1. Startup, Shutdown, Malfunction
The United States Court of Appeals
for the District of Columbia Circuit
vacated portions of two provisions in
EPA’s CAA section 112 regulations
governing the emissions of HAP during
periods of startup, shutdown, and
malfunction (SSM). Sierra Club v. EPA,
551 F.3d 1019 (DC Cir. 2008), cert.
denied, 130 S. Ct. 1735 (U.S. 2010).
Specifically, the Court vacated the SSM
exemption contained in 40 CFR
63.6(f)(1) and 40 CFR 63.6(h)(1), that are
part of a regulation, commonly referred
to as the ‘‘General Provisions Rule,’’ that
EPA promulgated under CAA section
112. When incorporated into CAA
section 112(d) regulations for specific
source categories, these two provisions
exempt sources from the requirement to
comply with the otherwise applicable
CAA section 112(d) emissions standard
during periods of SSM.
We are proposing the elimination of
the SSM exemption in this rule.
Consistent with Sierra Club v. EPA, EPA
is proposing standards in this rule that
apply at all times. We are also proposing
several revisions to Table 1 to subpart
X of part 63 (the General Provisions
Applicability table). For example, we
are proposing to eliminate the
incorporation of the General Provisions’
requirement that the source develop an
SSM plan. We also are proposing to
eliminate or revise certain
recordkeeping and reporting that related
to the SSM exemption. EPA has
attempted to ensure that we have not
included in the proposed regulatory
language any provisions that are
inappropriate, unnecessary, or
redundant in the absence of the SSM
exemption. We are specifically seeking
comment on whether there are any such
provisions that we have inadvertently
incorporated or overlooked.
In proposing the standards in this
rule, EPA has taken into account startup
and shutdown periods and, for the
reasons explained below, has not
proposed different standards for those
periods.
Information on periods of startup and
shutdown received from the industry in
the ICR indicate that emissions during
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these periods do not increase. Control
devices such as afterburners for organics
and dioxin control and baghouses for
lead and metal HAP particulate control
are started up before the process units,
and are operational during the
shutdown phase of a process. Therefore,
no increase in emissions is expected
during these periods. Enclosures and
work practices for fugitive emissions
will be in place at all times. Therefore,
separate standards for periods of startup
and shutdown are not being proposed.
Periods of startup, normal operations,
and shutdown are all predictable and
routine aspects of a source’s operations.
However, by contrast, malfunction is
defined as a ‘‘sudden, infrequent, and
not reasonably preventable failure of air
pollution control and monitoring
equipment, process equipment or a
process to operate in a normal or usual
manner * * *’’ (40 CFR 63.2). EPA has
determined that CAA section 112 does
not require that emissions that occur
during periods of malfunction be
factored into development of CAA
section 112 standards. Under CAA
section 112, emissions standards for
new sources must be no less stringent
than the level ‘‘achieved’’ by the best
controlled similar source and for
existing sources generally must be no
less stringent than the average emissions
limitation ‘‘achieved’’ by the best
performing 12 percent of sources in the
category. There is nothing in CAA
section 112 that directs the Agency to
consider malfunctions in determining
the level ‘‘achieved’’ by the best
performing or best controlled sources
when setting emissions standards.
Moreover, while EPA accounts for
variability in setting emissions
standards consistent with the CAA
section 112 case law, nothing in that
case law requires the Agency to
consider malfunctions as part of that
analysis. Section 112 of the CAA uses
the concept of ‘‘best controlled’’ and
‘‘best performing’’ unit in defining the
level of stringency that CAA section 112
performance standards must meet.
Applying the concept of ‘‘best
controlled’’ or ‘‘best performing’’ to a
unit that is malfunctioning presents
significant difficulties, as malfunctions
are sudden and unexpected events.
Further, accounting for malfunctions
would be difficult, if not impossible,
given the myriad different types of
malfunctions that can occur across all
sources in the category and given the
difficulties associated with predicting or
accounting for the frequency, degree,
and duration of various malfunctions
that might occur. As such, the
performance of units that are
malfunctioning is not ‘‘reasonably’’
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foreseeable. See, e.g., Sierra Club v.
EPA, 167 F.3d 658, 662 (DC Cir. 1999)
(EPA typically has wide latitude in
determining the extent of data-gathering
necessary to solve a problem. We
generally defer to an agency’s decision
to proceed on the basis of imperfect
scientific information, rather than to
‘‘invest the resources to conduct the
perfect study.’’). See also, Weyerhaeuser
v. Costle, 590 F.2d 1011, 1058 (DC Cir.
1978) (‘‘In the nature of things, no
general limit, individual permit, or even
any upset provision can anticipate all
upset situations. After a certain point,
the transgression of regulatory limits
caused by ‘uncontrollable acts of third
parties,’ such as strikes, sabotage,
operator intoxication or insanity, and a
variety of other eventualities, must be a
matter for the administrative exercise of
case-by-case enforcement discretion, not
for specification in advance by
regulation’’). In addition, the goal of a
best controlled or best performing
source is to operate in such a way as to
avoid malfunctions of the source and
accounting for malfunctions could lead
to standards that are significantly less
stringent than levels that are achieved
by a well-performing nonmalfunctioning source. EPA’s approach
to malfunctions is consistent with CAA
section 112 and is a reasonable
interpretation of the statute.
In the event that a source fails to
comply with the applicable CAA section
112(d) standards as a result of a
malfunction event, EPA would
determine an appropriate response
based on, among other things, the good
faith efforts of the source to minimize
emissions during malfunction periods,
including preventative and corrective
actions, as well as root cause analyses
to ascertain and rectify excess
emissions. EPA would also consider
whether the source’s failure to comply
with the CAA section 112(d) standard
was, in fact, ‘‘sudden, infrequent, not
reasonably preventable’’ and was not
instead ‘‘caused in part by poor
maintenance or careless operation’’ 40
CFR 63.2 (definition of malfunction).
Finally, EPA recognizes that even
equipment that is properly designed and
maintained can sometimes fail and that
such failure can sometimes cause an
exceedance of the relevant emissions
standard. (See, e.g., State
Implementation Plans: Policy Regarding
Excessive Emissions During
Malfunctions, Startup, and Shutdown
(Sept. 20, 1999); Policy on Excess
Emissions During Startup, Shutdown,
Maintenance, and Malfunctions (Feb.
15, 1983)). EPA is therefore proposing to
add to the final rule an affirmative
defense to civil penalties for
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exceedances of emissions limits that are
caused by malfunctions. See 40 CFR
63.542 (defining ‘‘affirmative defense’’ to
mean, in the context of an enforcement
proceeding, a response or defense put
forward by a defendant, regarding
which the defendant has the burden of
proof, and the merits of which are
independently and objectively
evaluated in a judicial or administrative
proceeding). We also are proposing
other regulatory provisions to specify
the elements that are necessary to
establish this affirmative defense; the
source must prove by a preponderance
of the evidence that it has met all of the
elements set forth in 40 CFR 63.552 (40
CFR 22.24). The criteria ensure that the
affirmative defense is available only
where the event that causes an
exceedance of the emissions limit meets
the narrow definition of malfunction in
40 CFR 63.2 (sudden, infrequent, not
reasonable preventable and not caused
by poor maintenance and or careless
operation). For example, to successfully
assert the affirmative defense, the source
must prove by a preponderance of the
evidence that excess emissions ‘‘[w]ere
caused by a sudden, infrequent, and
unavoidable failure of air pollution
control and monitoring equipment,
process equipment, or a process to
operate in a normal or usual manner
* * *’’ The criteria also are designed to
ensure that steps are taken to correct the
malfunction, to minimize emissions in
accordance with 40 CFR 63.543(j) and to
prevent future malfunctions. For
example, the source must prove by a
preponderance of the evidence that
‘‘[r]epairs were made as expeditiously as
possible when the applicable emissions
limitations were being exceeded * * *’’
and that ‘‘[a]ll possible steps were taken
to minimize the impact of the excess
emissions on ambient air quality, the
environment and human health * * *.’’
In any judicial or administrative
proceeding, the Administrator may
challenge the assertion of the affirmative
defense and, if the respondent has not
met its burden of proving all of the
requirements in the affirmative defense,
appropriate penalties may be assessed
in accordance with CAA section 113
(see also 40 CFR 22.77).
Specifically, we are proposing the
following changes to the rule.
Added general duty requirements in
40 CFR 63.543(j) to replace General
Provision requirements that reference
vacated SSM provisions.
Added replacement language that
eliminates the reference to SSM
exemptions applicable to performance
tests in 40 CFR 63.543(i).
Added paragraphs in 40 CFR
63.550(d) requiring the reporting of
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malfunctions as part of the affirmative
defense provisions.
Added paragraphs in 40 CFR
63.550(c) requiring the keeping of
certain records during malfunctions as
part of the affirmative defense
provisions.
Revised Table 1 to subpart X of part
63 to reflect changes in the applicability
of the General Provisions to this subpart
resulting from a court vacatur of certain
SSM requirements in the General
Provisions.
2. Electronic Reporting
EPA must have performance test data
to conduct effective reviews of CAA
sections 112 and 129 standards, as well
as for many other purposes including
compliance determinations, emissions
factor development, and annual
emissions rate determinations. In
conducting these required reviews, EPA
has found it ineffective and time
consuming, not only for us, but also for
regulatory agencies and source owners
and operators, to locate, collect, and
submit performance test data because of
varied locations for data storage and
varied data storage methods. In recent
years, though, stack testing firms have
typically collected performance test data
in electronic format, making it possible
to move to an electronic data submittal
system that would increase the ease and
efficiency of data submittal and improve
data accessibility.
Through this proposal EPA is
presenting a step to increase the ease
and efficiency of data submittal and
improve data accessibility. Specifically,
EPA is proposing that owners and
operators of Secondary Lead Smelting
facilities submit electronic copies of
required performance test reports to
EPA’s WebFIRE database. The WebFIRE
database was constructed to store
performance test data for use in
developing emissions factors. A
description of the WebFIRE database is
available at https://cfpub.epa.gov/
oarweb/index.cfm?action=fire.main.
As proposed above, data entry would
be through an electronic emissions test
report structure called the Electronic
Reporting Tool. The ERT would be able
to transmit the electronic report through
EPA’s Central Data Exchange network
for storage in the WebFIRE database
making submittal of data very
straightforward and easy. A description
of the ERT can be found at https://
www.epa.gov/ttn/chief/ert/ert_tool.html.
The proposal to submit performance
test data electronically to EPA would
apply only to those performance tests
conducted using test methods that will
be supported by the ERT. The ERT
contains a specific electronic data entry
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form for most of the commonly used
EPA reference methods. A listing of the
pollutants and test methods supported
by the ERT is available at https://
www.epa.gov/ttn/chief/ert/ert_tool.html.
We believe that industry would benefit
from this proposed approach to
electronic data submittal. Having these
data, EPA would be able to develop
improved emissions factors, make fewer
information requests, and promulgate
better regulations.
One major advantage of the proposed
submittal of performance test data
through the ERT is a standardized
method to compile and store much of
the documentation required to be
reported by this rule. Another advantage
is that the ERT clearly states what
testing information would be required.
Another important proposed benefit of
submitting these data to EPA at the time
the source test is conducted is that it
should substantially reduce the effort
involved in data collection activities in
the future. When EPA has performance
test data in hand, there will likely be
fewer or less substantial data collection
requests in conjunction with
prospective required residual risk
assessments or technology reviews. This
would result in a reduced burden on
both affected facilities (in terms of
reduced manpower to respond to data
collection requests) and EPA (in terms
of preparing and distributing data
collection requests and assessing the
results).
State, local, and Tribal agencies could
also benefit from more streamlined and
accurate review of electronic data
submitted to them. The ERT would
allow for an electronic review process
rather than a manual data assessment
making review and evaluation of the
source provided data and calculations
easier and more efficient. Finally,
another benefit of the proposed data
submittal to WebFIRE electronically is
that these data would greatly improve
the overall quality of existing and new
emissions factors by supplementing the
pool of emissions test data for
establishing emissions factors and by
ensuring that the factors are more
representative of current industry
operational procedures. A common
complaint heard from industry and
regulators is that emissions factors are
outdated or not representative of a
particular source category. With timely
receipt and incorporation of data from
most performance tests, EPA would be
able to ensure that emissions factors,
when updated, represent the most
current range of operational practices. In
summary, in addition to supporting
regulation development, control strategy
development, and other air pollution
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control activities, having an electronic
database populated with performance
test data would save industry, state,
local, Tribal agencies, and EPA
significant time, money, and effort
while also improving the quality of
emissions inventories and, as a result,
air quality regulations.
Records must be maintained in a form
suitable and readily available for
expeditious review, according to
63.10(b)(1). Electronic recordkeeping
and reporting is available for many
records, and is the form considered
most suitable for expeditious review if
available. Electronic recordkeeping and
reporting is encouraged in this proposal
and some records and reports are
required to be kept in electronic format.
Records required to be maintained
electronically include the output of
continuous monitors and the output of
the bag leak detection systems.
Additionally, standard operating
procedures for the bag leak detection
system and fugitive emissions control
are required to be submitted to the
Administrator for approval in electronic
format.
jlentini on DSK4TPTVN1PROD with PROPOSALS2
3. Other Changes
The following lists additional minor
changes to the NESHAP we are
proposing. This list includes proposed
rule changes that address editorial
corrections and plain language
revisions:
• Revise the definition for collocated blast
and reverberatory furnaces to apply to
systems ‘‘where the vent streams of the
furnaces are mixed before cooling’’. This
proposed revision clarifies the intent of the
original definition which was to establish the
conditions under which a reverberatory
furnace stream would control the emissions
of a blast furnace stream.
• Add a definition for ‘‘maintenance
activity.’’ This definition is necessary for the
proposed work practice requirement
concerning fugitive emissions during
maintenance activities that could generate
lead dust.
• Delete definitions no longer referenced
in the proposed NESHAP.
• Eliminate the exemption for areas used
exclusively for the storage of blast furnace
slag from the raw materials storage area
definition.
• Change the title of 40 CFR 63.543
(‘‘Standards for process sources’’) to ‘‘What
are my standards for atmospheric vents?’’.
This change is being made to better reflect
the description of the proposed standards in
this section.
• Change the title of 40 CFR 63.544
(‘‘Standards for process fugitive sources’’) to
‘‘What are my process enclosure standards?’’
to better reflect the description of the
proposed requirements for enclosure of
sources of process fugitive emissions.
• Eliminate the provision in 40 CFR
63.544(f) allowing up to 24 months to
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conduct a compliance test for lead if the
previous test was less than 1.0 mg/dscm. We
do not believe a reduced testing frequency is
appropriate considering the proposed
changes to the existing standard, and the
proposed requirement to calculate a flowweighted average on an annual basis.
• Add a requirement to conduct a
performance test for THC on the same
schedule as the stack test for lead. The 1997
NESHAP requires an initial test for THC, but
does not require periodic testing. We are
proposing that a performance test for total
hydrocarbon be conducted on the same
schedule as the stack test for lead. This
proposed requirement will ensure any
changes in operation that could affect the
organic HAP content of the furnace vents are
monitored on a routine basis.
• Consolidate the requirements for
atmospheric vents to be conveyed to a
control device into one section of the rule
(40 CFR 63.543(f)).
• Clarify the requirements for plant
roadway cleaning in 40 CFR 63.545 to specify
equipment requirements for the mobile
vacuum sweeper.
• Clarify the requirement to wash vehicles
at the exit of a material storage area by
specifying that the wash must include
washing of tires, undercarriage and exterior
surface of the vehicle followed by an
inspection.
• Accompanying edits are being proposed
for the standard operating procedures for
baghouses in 40 CFR 63.548 and for control
of fugitive emissions in 40 CFR 63.545 to
reflect the proposed changes described for
baghouses, enclosures and work practices for
control of fugitive emissions.
• Update the monitoring requirements for
building differential pressure to reflect the
requirements for the pressure monitor to
have the capability of detecting 0.01 mm Hg
and to continuously record pressure
readings.
• Update the recordkeeping and reporting
sections to reflect the new monitoring
requirements and monitoring options
described above.
• Update the compliance dates to include
the anticipated dates the proposed
requirements will become effective.
• Added the requirement in 40 CFR
63.548(l) for new or modified sources to
install a CEMS for measuring lead emissions
when performance specifications for lead
CEMS are promulgated.
• Included provisions for existing sources
to use a CEMS instead of operating a BLDS
and performing annual stack tests.
F. What is the relationship of the
Secondary Lead Smelting standards
proposed in today’s action and
implementation of the lead NAAQS?
Although EPA’s obligation to conduct
technology reviews and risk analyses for
the secondary lead smelting source
category is independent of the process
of developing, revising, and
implementing the National Ambient Air
Quality Standard (NAAQS) for lead,
EPA is interested in harmonizing these
separate regulatory processes to the
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extent possible. EPA revised the
primary NAAQS for lead in 2008. See
73 FR 66,964 (Nov. 12, 2008); see also
Coalition of Battery Recyclers v. EPA,
604 F. 3d 613 (DC Cir. 2010) (upholding
those standards). EPA designated 16
areas as non-attainment for the lead
NAAQS, effective December 21, 2010,
75 FR 71,033 (November 22, 2010). EPA
intends to complete designations for
remaining areas of the country for the
lead NAAQS in October, 2011, effective
December 31, 2011. States have 18
months following a nonattainment
designation for lead to submit a State
Implementation Plan (SIP)
demonstrating how the area will timely
attain the NAAQS. See CAA section
191(a). Accordingly, attainment SIPs for
lead will be due by July 2012 for areas
designated in 2010 and July 2013 for
areas designated in 2011. States are
required to attain the standard as
expeditiously as practicable, but no later
than 5 years following a nonattainment
designation (i.e., Dec. 31, 2015 or 2016,
respectively). As part of the attainment
demonstration, SIPs may consider
regulatory controls which have been
adopted as of the date the SIP is
submitted and will achieve timely
reductions for attaining the standard.
The standards proposed in this rule
would likely harmonize with this
implementation schedule both
procedurally and substantively.
Pursuant to consent decree, EPA is
obligated to promulgate the final
NESHAP rule by December 31, 2011.
Assuming EPA adopts the proposed
standards and the rule is published in
the Federal Register in early 2012, the
standards would become effective in
early 2012, with a compliance date of
March 2014 (assuming a two year
compliance date is necessary to allow
sufficient time for the controls to be
adopted). This schedule should allow
for states to take any controls required
under the NESHAP rule into
consideration for attainment planning
purposes.
As described above, EPA is proposing
standards either predicated on
individual sources emitting lead at
levels that would result in ambient
concentrations less than the primary
lead NAAQS (the proposed stack
standards), or (in the case of the
alternative to enclosure standards for
lead) actually demonstrating that source
emissions do not exceed the primary
lead NAAQS at a point of maximum
projected concentration. EPA
anticipates that, at least in areas where
nonattainment is attributable to single
sources that are subject to this rule, if
the proposed controls are sufficient to
attain the NAAQS by the attainment
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jlentini on DSK4TPTVN1PROD with PROPOSALS2
deadline, then adoption of additional
controls in the SIP for the area would
not be necessary.
EPA solicits comments on the
interplay between implementation of
the primary lead NAAQS and the
proposed standards in today’s action
and steps EPA might permissibly take to
harmonize the two regulatory processes.
G. Compliance Dates
We are proposing that facilities must
comply with all the requirements in this
action (which are being proposed under
CAA sections 112(d)(2), 112(d)(3),
112(d)(6), 112(f)(2), and 112(h) for all
affected sources), no later than two
years after the effective date of this rule.
Under section 63.6(i)(4)(ii), ‘‘the owner
or operator of an existing source unable
to comply with a relevant standard
established * * * pursuant to section
112(f) * * * may request that the
Administrator grant an extension
allowing the source up to 2 years after
the standard’s effective date to comply
with the standard.’’ The rule further
specifies a written application for such
a request. Here, EPA is already fully
aware of the steps needed for each
source to comply with the proposed
standards and to reasonably estimate the
amount of time it will take each source
to do so. We believe that the two year
extension would be warranted in all
cases for sources needing to upgrade
current practice. This includes the time
needed to: Construct required
enclosures and install associated control
devices for fugitive sources; purchase,
install and test replacement bags, or if
the facility decides to replace an
existing baghouse or add a new
baghouse in series with an existing
baghouse, seek bids, select a vendor,
install and test the new equipment;
prepare and submit the required
monitoring plan to monitor lead
concentrations in air; and, purchase,
install and conduct quality assurance
and quality control measures on
compliance monitoring equipment (see
Estimated Time Needed to Achieve
Compliance with The Proposed
Revisions to the MACT standard for
Secondary Lead Smelters, which is
available in the docket for this proposed
action). EPA believes it reasonable to
interpret section 63.6(i)(4)(ii) to allow
this plenary finding, rather than
utilizing a facility-by-facility application
process, when the facts are already
known and a category-wide
adjudication is therefore possible. In
addition, utilizing this process allows
for public comment on the issue which
would not be possible if a case-by-case
application process with a 90-day
window for completion were used.
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V. Summary of Cost, Environmental,
and Economic Impacts
A. What are the affected sources?
We anticipate that the 14 secondary
lead smelting facilities currently
operating in the United States will be
affected by these proposed amendments.
No new facilities are expected to be
constructed in the foreseeable future;
however, one facility is currently
undergoing an expansion.
B. What are the air quality impacts?
EPA estimated the emissions
reductions that are expected to result
from the proposed amendments to the
1997 NESHAP compared to the 2009
baseline emissions estimates. A detailed
documentation of the analysis can be
found in:
Draft Cost Impacts of the Revised
NESHAP for the Secondary Lead
Smelting Source Category
Emissions of lead and arsenic from
secondary lead smelters have declined
over the last 15 years as a result of
Federal rules, state rules and on the
industry’s own initiative. The current
proposal would cut lead and arsenic
emissions by 63 percent from their
current levels, for a total reduction of
more than 95% over that last 15 years.
Under the proposed emissions limit for
lead, we estimated that the lead
emissions reductions would be 9,400 lb/
yr from process and process fugitive
sources and 17,200 lb/yr from fugitive
dust sources. The expected reduction in
total metal HAP is 11,800 lb/yr from
process and process fugitive sources and
19,000 lb/yr from fugitive dust sources.
We estimate that these controls will also
reduce emissions of PM by 319,000 lb/
yr.
Based on the emissions data available
to the EPA, we believe that all facilities
will be able to comply with the
proposed emissions limits for THC and
dioxins and furans without additional
controls. However, we expect that some
emissions reductions will occur due to
increased temperatures of afterburners
and from improved work practices.
Nevertheless, it is quite difficult to
estimate accurate reductions from these
actions, and therefore, we are not
providing estimates of reductions for
THC and dioxin and furans.
C. What are the cost impacts?
Under the proposed amendments,
secondary lead smelting facilities are
expected to incur capital costs for the
following types of control measures:
Replacement of existing baghouses with
new, higher-performing baghouses,
replacement of bags in existing
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baghouses with better-performing
materials, construction of new
enclosures for processes not currently
enclosed, modification of partiallyenclosed structures to meet the
requirements of total enclosure, and
installation of BLDS on baghouses that
are not currently equipped with these
systems.
The capital costs for each facility were
estimated based on the number and
types of upgrades required. Each facility
was evaluated for its ability to meet the
proposed limits for lead emissions, THC
emissions, dioxin and furan emissions,
and proposed fugitive dust emissions
requirements. The memorandum Cost
Impacts of the Revised NESHAP for the
Secondary Lead Smelting Source
Category includes a complete
description of the cost estimate methods
used for this analysis and is available in
the docket.
The majority of the capital costs
estimated for compliance with the
amendments proposed in this action are
for purchasing new enclosures and the
associated control devices that would be
required for these enclosures. Although
the proposed amendments would
provide the alternative option to install
monitors at or near the property
boundary to demonstrate compliance
with the enclosure requirements, we
assumed that each facility would need
to install enclosures for each of the
processes described in proposed 40 CFR
63.544 if the facility did not already
have the required enclosures. For each
facility, we estimated the square footage
of new enclosures required based on the
size of enclosures currently in place
compared to facilities that we
considered to be totally enclosed with a
similar production capacity. We further
assumed that the facilities that required
a substantial degree of new enclosure
would re-configure their facility,
particularly the storage areas, to reduce
their footprint.
Based on our analysis of the facility
configurations, seven facilities were
considered to be totally enclosed.
Another facility is currently installing
enclosure structures and equipment that
we anticipate will meet the proposed
requirements. Consequently, capital
costs were not estimated for these eight
facilities. The remaining six facilities
will require new building installations,
thereby incurring capital costs.
Typical enclosure costs were
estimated using information and
algorithms from the Permanent Total
Enclosures chapter in the EPA Air
Pollution Control Cost Manual. New
baghouse costs were estimated using a
model based primarily on the cost
information for recent baghouse
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installations submitted by facilities in
the ICR survey. The total capital cost
estimate for the enclosures, the
ductwork system, and control devices at
the six facilities is approximately $40
million, at an annualized cost of $6.6
million in 2009 dollars (an average of
about $1.1 million per facility).
We also estimated annual costs for the
work practices proposed in this action.
Based on the ICR survey information,
we estimated that additional costs
would be required to implement the
work practices at 10 of the 14 existing
facilities. The total annual costs to
implement the proposed fugitive
emissions work practices are
approximately $3 million per year.
For compliance with the stack lead
concentration limit, we compared each
stack emissions point’s lead
concentration (reported under the ICR)
to the proposed requirement of 1.0 mg/
dscm of lead for any one stack. If the
reported concentration was over 1.0 mg/
dscm, we assumed that the
corresponding facility would either
upgrade the baghouse with new bags
and additional maintenance or
completely replace the baghouse,
depending on the age of the unit. If the
baghouse was less than 10 years old and
the lead concentration in the outlet was
not appreciably over the proposed
standard, we assumed that the baghouse
could be upgraded for minimal capital.
If the baghouse was more than 10 years
old and the lead concentration was
appreciably over the proposed standard,
we assumed the baghouse would be
replaced. We then compared each
facility’s emissions with the proposed
flow-weighted, facility-wide
concentration limit of 0.20 mg/dscm
using the assumption that baghouses
needing replacement based on the 1.0
mg/dscm individual stack limit would
be replaced with units that performed at
least as well as the average baghouse
identified in our data set. We estimated
that three baghouses would need to be
replaced based on these analyses. To
estimate costs, we used a model based
primarily on the cost information
submitted in the ICR for recent
baghouse installations in this industry.
We assumed an increase in maintenance
cost based on more frequent bag changes
(from once every 5 years to once every
2 years). The total capital cost for three
new baghouses at two facilities is
estimated to be approximately $7.6
million, and total annual costs were
estimated to be approximately $1.7
million.
New limits for THC are being
proposed for reverberatory, electric, and
rotary furnaces. Dioxin and furan limits
are being proposed for all furnaces. We
anticipate all operating affected units
will be able to meet the proposed limits
without installing additional controls,
however, we have estimated additional
costs of $260,000 per year for facilities
to increase the temperature of their
existing afterburners to ensure
continuous compliance with the
proposed standards.
The estimated costs for the proposed
change to the monitoring requirements
for baghouses, including installation of
seven new BLDS for existing baghouses,
is $230,000 of capital cost and $84,000
total annualized cost. The capital cost
estimated for additional differential
pressure monitors for total enclosures is
$97,000. The cost for all additional
monitoring and recordkeeping
requirements, including the baghouse
monitoring proposed, is estimated at
$1,016,000.
The total annualized costs for the
proposed rule are estimated at $12.6
million (2009 dollars). Table 5 provides
a summary of the estimated costs and
emissions reductions associated with
the proposed amendments to the
Secondary Lead Smelting NESHAP
presented in today’s action.
TABLE 5—ESTIMATED COSTS AND REDUCTIONS FOR THE PROPOSED STANDARDS IN THIS ACTION
Estimated
capital cost
($MM)
Estimated
annual cost
($MM)
Revised stack lead emissions limit ................
7.6
1.7
5.9 (of metal HAP) .........................................
Total enclosure of fugitive emissions sources
40
6.6
5.5 (of metal HAP) .........................................
Fugitive control work practices .......................
0
3.0
4.0 (of metal HAP) .........................................
THC and D/F concentration limits ..................
Additional testing and monitoring ...................
0
0.3
0.3
1.0
1 30.0 ..............................................................
N/A .................................................................
Proposed amendment
1 Based
$0.3 MM per ton.
($150 per pound).
$1.2 MM per ton.
($600 per pound).
$0.8 MM per ton.
($400 per pound).
$0.01 MM per ton.
N/A.
on total organic HAP.
D. What are the economic impacts?
jlentini on DSK4TPTVN1PROD with PROPOSALS2
Total HAP emissions reductions
(tons per year)
Cost effectiveness
in $ per ton total
HAP
reduction
(and in $ per
pound)
We performed an economic impact
analysis for secondary lead consumers
and producers nationally using the
annual compliance costs estimated for
this proposed rule. The impacts to
producers affected by this proposed rule
are annualized costs of less than 0.9
percent of their revenues using the most
current year available for revenue data.
Prices and output for secondary lead
should increase by no more than the
impact on cost to revenues for
producers, thus secondary lead prices
should increase by less than 0.9 percent.
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Hence, the overall economic impact of
this proposed rule should be low on the
affected industry and its consumers. For
more information, please refer to the
Economic Impact Analysis for this
proposed rulemaking that is available in
the public docket.
E. What are the benefits?
The estimated reductions in lead
emissions to meet the 2008 NAAQS
standards that will be achieved by this
proposed rule would provide benefits to
public health, although we have not
made a detailed quantitative assessment
of them. For example, as described in
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the EPA’s 2008 Regulatory Impact
Analysis (RIA) that was completed for
the lead NAAQS (which is available in
the docket for this action and also on
the EPA’s Web site) populations aged
less than age 7 would receive significant
benefits from reductions in lead
exposure (in the form of averted IQ loss
among children less than 7 years of age).
As noted in that RIA, there were also
several other lead-related health effects
that EPA was unable to quantify—
particularly among adults. These
potential impacts included
hypertension, non-fatal strokes,
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reproductive effects and premature
mortality, among others.
When viewed in this context, the
reductions in concentrations of ambient
lead that would be achieved with this
proposed RTR for secondary lead
smelters are expected to provide
significant benefits to both children and
adult populations, but these benefits
cannot be quantified due to resource
and data limitations.
In addition to the benefits likely to be
achieved for lead reductions, we also
estimate that this proposed RTR rule
will achieve about 48 to 76 tons
reductions in PM 2.5 emissions as a cobenefit of the HAP reductions. These
PM 2.5 reductions would result in an
average of about $8.6 to $13.6 million in
benefits per year. Finally, the proposed
rule will provide human health benefits
through reductions in arsenic and
cadmium emissions. We estimate that
cancer cases from these emissions
would be reduced from 0.02 per year to
0.01 per year.
VI. Request for Comments
We are soliciting comments on all
aspects of this proposed action. In
addition to general comments on this
proposed action, we are also interested
in any additional data that may help to
reduce the uncertainties inherent in the
risk assessments and other analyses. We
are specifically interested in receiving
corrections to the site-specific emissions
profiles used for risk modeling. Such
data should include supporting
documentation in sufficient detail to
allow characterization of the quality and
representativeness of the data or
information. Section VII of this
preamble provides more information on
submitting data.
VII. Submitting Data Corrections
The site-specific emissions profiles
used in the source category risk and
demographic analyses are available for
download on the RTR Web page at:
https://www.epa.gov/ttn/atw/rrisk/
rtrpg.html. The data files include
detailed information for each HAP
emissions release point for the facility
included in the source category.
If you believe that the data are not
representative or are inaccurate, please
identify the data in question, provide
your reason for concern, and provide
any ‘‘improved’’ data that you have, if
available. When you submit data, we
request that you provide documentation
of the basis for the revised values to
support your suggested changes. To
submit comments on the data
downloaded from the RTR Web page,
complete the following steps:
1. Within this downloaded file, enter
suggested revisions to the data fields
appropriate for that information. The
data fields that may be revised include
the following:
Data element
Definition
Control Measure .................................................................
Control Measure Comment ................................................
Delete .................................................................................
Delete Comment ................................................................
Emissions Calculation Method Code for Revised Emissions.
Emissions Process Group ..................................................
Are control measures in place? (yes or no)
Select control measure from list provided, and briefly describe the control measure.
Indicate here if the facility or record should be deleted.
Describes the reason for deletion.
Code description of the method used to derive emissions. For example, CEM, material balance, stack test, etc.
Enter the general type of emissions process associated with the specified emissions
point.
Enter release angle (clockwise from true North); orientation of the y-dimension relative to true North, measured positive for clockwise starting at 0 degrees (maximum 89 degrees).
Enter dimension of the source in the east-west (x-) direction, commonly referred to
as length (ft).
Enter dimension of the source in the north-south (y-) direction, commonly referred to
as width (ft).
Enter total annual emissions due to malfunctions (tpy).
Enter maximum hourly malfunction emissions here (lb/hr).
Enter datum for latitude/longitude coordinates (NAD27 or NAD83); if left blank,
NAD83 is assumed.
Enter general comments about process sources of emissions.
Enter revised physical street address for MACT facility here.
Enter revised city name here.
Enter revised county name here.
Enter revised Emissions Release Point Type here.
Enter revised End Date here.
Enter revised Exit Gas Flowrate here (ft3/sec).
Enter revised Exit Gas Temperature here (F).
Enter revised Exit Gas Velocity here (ft/sec).
Enter revised Facility Category Code here, which indicates whether facility is a major
or area source.
Enter revised Facility Name here.
Enter revised Facility Registry Identifier here, which is an ID assigned by the EPA
Facility Registry System.
Enter revised HAP Emissions Performance Level here.
Enter revised Latitude here (decimal degrees).
Enter revised Longitude here (decimal degrees).
Enter revised MACT Code here.
Enter revised Pollutant Code here.
Enter revised routine emissions value here (tpy).
Enter revised SCC Code here.
Enter revised Stack Diameter here (ft).
Enter revised Stack Height here (ft).
Enter revised Start Date here.
Enter revised State here.
Enter revised Tribal Code here.
Enter revised Zip Code here.
Fugitive Angle ....................................................................
Fugitive Length ...................................................................
Fugitive Width ....................................................................
Malfunction Emissions .......................................................
Malfunction Emissions Max Hourly ....................................
North American Datum ......................................................
Process Comment ..............................................................
REVISED Address .............................................................
REVISED City ....................................................................
REVISED County Name ....................................................
REVISED Emissions Release Point Type .........................
REVISED End Date ...........................................................
REVISED Exit Gas Flow Rate ...........................................
REVISED Exit Gas Temperature .......................................
REVISED Exit Gas Velocity ...............................................
REVISED Facility Category Code ......................................
jlentini on DSK4TPTVN1PROD with PROPOSALS2
REVISED Facility Name ....................................................
REVISED Facility Registry Identifier ..................................
REVISED
REVISED
REVISED
REVISED
REVISED
REVISED
REVISED
REVISED
REVISED
REVISED
REVISED
REVISED
REVISED
HAP Emissions Performance Level Code ........
Latitude ..............................................................
Longitude ...........................................................
MACT Code ......................................................
Pollutant Code ...................................................
Routine Emissions ............................................
SCC Code .........................................................
Stack Diameter ..................................................
Stack Height ......................................................
Start Date ..........................................................
State ..................................................................
Tribal Code ........................................................
Zip Code ............................................................
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Data element
Definition
Shutdown Emissions ..........................................................
Shutdown Emissions Max Hourly ......................................
Stack Comment ..................................................................
Startup Emissions ..............................................................
Startup Emissions Max Hourly ...........................................
Year Closed .......................................................................
2. Fill in the commenter information
fields for each suggested revision
(i.e., commenter name, commenter
organization, commenter e-mail address,
commenter phone number, and revision
comments).
3. Gather documentation for any
suggested emissions revisions (e.g.,
performance test reports, material
balance calculations).
4. Send the entire downloaded file
with suggested revisions in Microsoft®
Access format and all accompanying
documentation to Docket ID Number
EPA–HQ–OAR–2011–0344 (through one
of the methods described in the
ADDRESSES section of this preamble). To
expedite review of the revisions, it
would also be helpful if you submitted
a copy of your revisions to the EPA
directly at RTR@epa.gov in addition to
submitting them to the docket.
5. If you are providing comments on
a facility, you need only submit one file
for that facility, which should contain
all suggested changes for all sources at
that facility. We request that all data
revision comments be submitted in the
form of updated Microsoft® Access files,
which are provided on the RTR Web
Page at: https://www.epa.gov/ttn/atw/
rrisk/rtrpg.html.
jlentini on DSK4TPTVN1PROD with PROPOSALS2
VIII. Statutory and Executive Order
Reviews
A. Executive Order 12866: Regulatory
Planning and Review and Executive
Order 13563: Improving Regulation and
Regulatory Review
Under Executive Order 12866 (58 FR
51735, October 4, 1993), this action is a
significant regulatory action because it
raises novel legal and policy issues.
Accordingly, EPA submitted this action
to the Office of Management and Budget
(OMB) for review under Executive
Orders 12866 and 13563 (76 FR 3821,
January 21, 2011) and any changes made
in response to OMB recommendations
have been documented in the docket for
this action.
B. Paperwork Reduction Act
The information collection
requirements in this rule have been
submitted for approval to the Office of
Management and Budget (OMB) under
the Paperwork Reduction Act, 44 U.S.C.
3501 et seq. The Information Collection
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Enter
Enter
Enter
Enter
Enter
Enter
total annual emissions due to shutdown events (tpy).
maximum hourly shutdown emissions here (lb/hr).
general comments about emissions release points.
total annual emissions due to startup events (tpy).
maximum hourly startup emissions here (lb/hr).
date facility stopped operations.
Request (ICR) document prepared by
EPA has been assigned EPA ICR number
1856.07. The information collection
requirements are not enforceable until
OMB approves them. The information
requirements are based on notification,
recordkeeping, and reporting
requirements in the NESHAP General
Provisions (40 CFR part 63, subpart A),
which are mandatory for all operators
subject to national emissions standards.
These recordkeeping and reporting
requirements are specifically authorized
by CAA section 114 (42 U.S.C. 7414).
All information submitted to EPA
pursuant to the recordkeeping and
reporting requirements for which a
claim of confidentiality is made is
safeguarded according to Agency
policies set forth in 40 CFR part 2,
subpart B.
We are proposing new paperwork
requirements to the Secondary Lead
Smelting source category in the form of
increased frequency for stack testing as
described in 40 CFR 63.540(f)–(h). More
specifically, we are proposing the
elimination of the provisions allowing
reduced stack testing for lead and the
addition of annual stack testing for THC
and stack testing every 5 years for
dioxins and furans. In conjunction with
setting THC limits for reverberatory,
electric, and rotary furnaces, additional
monitoring and recordkeeping is
required for furnace outlet temperature
on these units. We believe temperature
monitors currently exist in these
locations and that the facilities will not
incur a capital cost due to this
requirement. Additionally, increased
monitoring is required for
demonstrating negative pressure in all
total enclosures if this compliance
option is selected. If the lead
concentration in air limit is chosen,
additional monitoring and
recordkeeping will be required. Bag leak
detection monitors will be required for
HEPA filtration systems where no BLDS
are currently installed. We estimate a
total of seven new BLDS will be
required as a result of this proposed rule
at an estimated capital cost of $230,000.
For this proposed rule, EPA is adding
affirmative defense to the estimate of
burden in the ICR. To provide the
public with an estimate of the relative
magnitude of the burden associated
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with an assertion of the affirmative
defense position adopted by a source,
EPA has provided administrative
adjustments to this ICR to show what
the notification, recordkeeping and
reporting requirements associated with
the assertion of the affirmative defense
might entail. EPA’s estimate for the
required notification, reports and
records for any individual incident,
including the root cause analysis, totals
$3,141 and is based on the time and
effort required of a source to review
relevant data, interview plant
employees, and document the events
surrounding a malfunction that has
caused an exceedance of an emissions
limit. The estimate also includes time to
produce and retain the record and
reports for submission to EPA. EPA
provides this illustrative estimate of this
burden because these costs are only
incurred if there has been a violation
and a source chooses to take advantage
of the affirmative defense.
Given the variety of circumstances
under which malfunctions could occur,
as well as differences among sources’
operation and maintenance practices,
we cannot reliably predict the severity
and frequency of malfunction-related
excess emissions events for a particular
source. It is important to note that EPA
has no basis currently for estimating the
number of malfunctions that would
qualify for an affirmative defense.
Current historical records would be an
inappropriate basis, as source owners or
operators previously operated their
facilities in recognition that they were
exempt from the requirement to comply
with emissions standards during
malfunctions. Of the number of excess
emissions events reported by source
operators, only a small number would
be expected to result from a malfunction
(based on the definition above), and
only a subset of excess emissions caused
by malfunctions would result in the
source choosing to assert the affirmative
defense. Thus we believe the number of
instances in which source operators
might be expected to avail themselves of
the affirmative defense will be
extremely small. For this reason, we
estimate no more than 2 or 3 such
occurrences for all sources subject to
subpart X over the 3-year period
covered by this ICR. We expect to gather
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information on such events in the future
and will revise this estimate as better
information becomes available. We
estimate 14 regulated entities are
currently subject to subpart X and will
be subject to all proposed standards.
The annual monitoring, reporting, and
recordkeeping burden for this collection
(averaged over the first 3 years after the
effective date of the standards) for these
amendments to subpart X (Secondary
Lead Smelting) is estimated to be $1.01
million per year. This includes 4,200
labor hours per year at a total labor cost
of $330,000 per year, and total non-labor
capital and operation and maintenance
(O&M) costs of $690,000 per year. This
estimate includes performance tests,
notifications, reporting, and
recordkeeping associated with the new
requirements for front-end process vents
and back-end process operations. The
total burden for the Federal government
(averaged over the first 3 years after the
effective date of the standard) is
estimated to be 1,300 hours per year at
a total labor cost of $67,000 per year.
Burden is defined at 5 CFR 1320.3(b).
An agency may not conduct or
sponsor, and a person is not required to
respond to, a collection of information
unless it displays a currently valid OMB
control number. The OMB control
numbers for EPA’s regulations in 40
CFR are listed in 40 CFR part 9. When
these ICRs are approved by OMB, the
Agency will publish a technical
amendment to 40 CFR part 9 in the
Federal Register to display the OMB
control numbers for the approved
information collection requirements
contained in the final rules.
To comment on the Agency’s need for
this information, the accuracy of the
provided burden estimates, and any
suggested methods for minimizing
respondent burden, EPA has established
a public docket for this rule, which
includes this ICR, under Docket ID
number EPA–HQ–OAR–2011–0344.
Submit any comments related to the ICR
to EPA and OMB. See the ADDRESSES
section at the beginning of this notice
for where to submit comments to EPA.
Send comments to OMB at the Office of
Information and Regulatory Affairs,
Office of Management and Budget, 725
17th Street, NW., Washington, DC
20503, Attention: Desk Office for EPA.
Since OMB is required to make a
decision concerning the ICR between 30
and 60 days after May 19, 2011, a
comment to OMB is best assured of
having its full effect if OMB receives it
by June 20, 2011. The final rule will
respond to any OMB or public
comments on the information collection
requirements contained in this proposal.
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C. Regulatory Flexibility Act
The Regulatory Flexibility Act (RFA)
generally requires an agency to prepare
a regulatory flexibility analysis of any
rule subject to notice and comment
rulemaking requirements under the
Administrative Procedure Act or any
other statute unless the agency certifies
that the rule will not have a significant
economic impact on a substantial
number of small entities. Small entities
include small businesses, small
organizations, and small governmental
jurisdictions.
For purposes of assessing the impacts
of this proposed rule on small entities,
small entity is defined as: (1) A small
business as defined by the Small
Business Administration’s (SBA)
regulations at 13 CFR 121.201; (2) a
small governmental jurisdiction that is a
government of a city, county, town,
school district or special district with a
population of less than 50,000; and (3)
a small organization that is any not-forprofit enterprise that is independently
owned and operated and is not
dominant in its field. For this source
category, which has the NAICS code
331419 (i.e., Secondary Smelting and
Refining of Nonferrous Metal (except
copper and aluminum)), the SBA small
business size standard is 750 employees
according to the SBA small business
standards definitions. We have
estimated the cost impacts and have
determined that the impacts do not
constitute a significant economic impact
on a substantial number of small entities
(see: Small Business Analysis for the
Secondary Lead Smelting Source
Category, which is available in the
docket for this proposed rule). After
considering the economic impacts of
today’s proposed rule on small entities,
I certify that this action will not have a
significant economic impact on a
substantial number of small entities.
One of the six parent companies
affected is considered a small entity per
the definition provided in this section.
However, we estimate that this
proposed action will not have a
significant economic impact on that
company. The impact of this proposed
action on this company will be an
annualized compliance cost of less than
one percent of its revenues. (See: Small
Business Analysis for the Secondary
Lead Smelting Source Category). All
other affected parent companies are not
small businesses according to the SBA
small business size standard for the
affected NAICS code (NAICS 331419).
Although this proposed rule will not
have a significant economic impact on
a substantial number of small entities,
EPA nonetheless has tried to reduce the
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impact of this rule on small entities. To
reduce the impacts, we are proposing an
alternative option to enclosure
standards to address fugitive emissions
in order to allow companies flexibility
on how best to minimize fugitive
emissions at their facilities most
efficiently. Moreover, we are proposing
stack limits that are based on a weighted
average approach (as described in
Sections V.C and V.D of this preamble)
and have been established at the least
stringent levels that we estimate will
still result in acceptable risks to public
health. Thus, the proposed stack limits
are based on the least costly approach
that will still provide an ample margin
of safety for human health and the
environment. In addition, the proposed
compliance testing requirements were
established in a way that minimizes the
costs for testing and reporting while still
providing the Agency the necessary
information needed to ensure
continuous compliance with the
proposed standards. For more
information, please refer to the small
business analysis that is in the docket.
We continue to be interested in the
potential impacts of the proposed rule
on small entities and welcome
comments on issues related to such
impacts.
D. Unfunded Mandates Reform Act
This proposed rule does not contain
a Federal mandate under the provisions
of Title II of the Unfunded Mandates
Reform Act of 1995 (UMRA), 2 U.S.C.
1531–1538 for State, local, or Tribal
governments or the private sector. The
proposed rule would not result in
expenditures of $100 million or more
for State, local, and Tribal governments,
in aggregate, or the private sector in any
1 year. The proposed rule imposes no
enforceable duties on any State, local or
Tribal governments or the private sector.
Thus, this proposed rule is not subject
to the requirements of sections 202 or
205 of the UMRA.
This proposed rule is also not subject
to the requirements of section 203 of
UMRA because it contains no regulatory
requirements that might significantly or
uniquely affect small governments
because it contains no requirements that
apply to such governments nor does it
impose obligations upon them.
E. Executive Order 13132: Federalism
This proposed rule does not have
federalism implications. It will not have
substantial direct effects on the States,
on the relationship between the national
government and the States, or on the
distribution of power and
responsibilities among the various
levels of government, as specified in
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Executive Order 13132. None of the
facilities subject to this action are
owned or operated by State
governments, and, because no new
requirements are being promulgated,
nothing in this proposed rule will
supersede State regulations. Thus,
Executive Order 13132 does not apply
to this proposed rule.
In the spirit of Executive Order 13132,
and consistent with EPA policy to
promote communications between EPA
and State and local governments, EPA
specifically solicits comment on this
proposed rule from State and local
officials.
H. Executive Order 13211: Actions
Concerning Regulations That
Significantly Affect Energy Supply,
Distribution, or Use
F. Executive Order 13175: Consultation
and Coordination With Indian Tribal
Governments
I. National Technology Transfer and
Advancement Act
This proposed rule does not have
Tribal implications, as specified in
Executive Order 13175 (65 FR 67249,
November 9, 2000). Thus, Executive
Order 13175 does not apply to this
action.
EPA specifically solicits additional
comment on this proposed action from
Tribal officials.
jlentini on DSK4TPTVN1PROD with PROPOSALS2
G. Executive Order 13045: Protection of
Children From Environmental Health
Risks and Safety Risks
This proposed rule is not subject to
Executive Order 13045 (62 FR 19885,
April 23, 1997) because it is not
economically significant as defined in
Executive Order 12866. However, the
Agency does believe there is a
disproportionate risk to children due to
current emissions of lead from this
source category. Modeled ambient air
lead concentrations from about 10 of the
14 facilities in this source category are
in excess of the NAAQS for lead, which
was set to ‘‘provide increased protection
for children and other at-risk
populations against an array of adverse
health effects, most notably including
neurological effects in children,
including neurocognitive and
neurobehavioral effects’’ (73 FR 67007).
However, the control measures
proposed in this notice will result in
lead concentration levels at or below the
lead NAAQS at all facilities, thereby
mitigating the risk of adverse health
effects to children.
The public is invited to submit
comments or identify peer-reviewed
studies and data that assess effects of
early life exposure to lead, arsenic, or
cadmium.
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This action is not a ‘‘significant energy
action’’ as defined under Executive
Order 13211, ‘‘Actions Concerning
Regulations That Significantly Affect
Energy Supply, Distribution, or Use’’ (66
FR 28355, May 22, 2001), because it is
not likely to have significant adverse
effect on the supply, distribution, or use
of energy. This action will not create
any new requirements and therefore no
additional costs for sources in the
energy supply, distribution, or use
sectors.
Section 12(d) of the National
Technology Transfer and Advancement
Act of 1995 (‘‘NTTAA’’), Public Law
104–113 (15 U.S.C. 272 note), directs
EPA to use voluntary consensus
standards (VCS) in its regulatory
activities unless to do so would be
inconsistent with applicable law or
otherwise impractical. VCS are
technical standards (e.g., materials
specifications, test methods, sampling
procedures, business practices) that are
developed or adopted by voluntary
consensus standards bodies. NTTAA
directs EPA to provide Congress,
through OMB, explanations when the
Agency decides not to use available and
applicable VCS.
This proposed rulemaking involves
technical standards. EPA proposes to
use ASME PTC 19.10–1981, ‘‘Flue and
Exhaust Gas Analyses,’’ for its manual
methods of measuring the oxygen or
carbon dioxide content of the exhaust
gas. These parts of ASME PTC 19.10–
1981 are acceptable alternatives to EPA
Method 3B. This standard is available
from the American Society of
Mechanical Engineers (ASME), Three
Park Avenue, New York, NY 10016–
5990 and ASTM D6420–99 (2004) as an
acceptable alternative to EPA Method
18. EPA has also decided to use EPA
Methods 1, 2, 3, 3A, 3B, 4, 5D, 23, a
Procedure in Subpart X to measure
doorway in-draft, and a method for
measuring lead in ambient air (i.e., 40
CFR Part 50 Appendix G). Although the
Agency has identified 16 VCS as being
potentially applicable to these methods
cited in this rule, we have decided not
to use these standards in this proposed
rulemaking. The use of these VCS
would have been impractical because
they do not meet the objectives of the
standards cited in this rule. The search
and review results are in the docket for
this proposed rule.
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29069
EPA welcomes comments on this
aspect of this proposed rulemaking and,
specifically, invites the public to
identify potentially-applicable
voluntary consensus standards and to
explain why such standards should be
used in this regulation.
Under section 63.7(f) and section
63.8(f) of Subpart A of the General
Provisions, a source may apply to EPA
for permission to use alternative test
methods or alternative monitoring
requirements in place of any required
testing methods, performance
specifications, or procedures in the
proposed rule. J. Executive Order 12898:
Federal Actions to Address
Environmental Justice in Minority
Populations and Low-Income
Populations.
Executive Order 12898 (59 FR 7629,
February 16, 1994) establishes Federal
executive policy on environmental
justice. Its main provision directs
Federal agencies, to the greatest extent
practicable and permitted by law, to
make environmental justice part of their
mission by identifying and addressing,
as appropriate, disproportionately high
and adverse human health or
environmental effects of their programs,
policies, and activities on minority
populations and low-income
populations in the United States.
To examine the potential for any
environmental justice issues that might
be associated with each source category,
we evaluated the distributions of HAPrelated cancer and non-cancer risks
across different social, demographic,
and economic groups within the
populations living near the facilities
where these source categories are
located. The methods used to conduct
demographic analyses for this rule are
described in Section III.B of this
preamble. The development of
demographic analyses to inform the
consideration of environmental justice
issues in EPA rulemakings is an
evolving science. EPA offers the
demographic analyses in today’s
proposed rulemaking as examples of
how such analyses might be developed
to inform such consideration, and
invites public comment on the
approaches used and the interpretations
made from the results, with the hope
that this will support the refinement
and improve utility of such analyses.
In the case of Secondary Lead
Smelting, we focused on populations
within 50 km of the 14 facilities in this
source category with emissions sources
subject to the MACT standard. More
specifically, for these populations we
evaluated exposures to HAP that could
result in cancer risks of 1-in-1 million
or greater, or population exposures to
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ambient air lead concentrations above
the level of the NAAQS for lead. We
compared the percentages of particular
demographic groups within the focused
populations to the total percentages of
those demographic groups nationwide.
The results of this analysis are
documented in Section IV of this
preamble (see Table 4 of this preamble),
as well as in a technical report located
in the docket for this proposed
rulemaking.
As described in Section IV of this
preamble, with regard to cancer risks,
there are some potential
disproportionate impacts to some
minority populations due to emissions
of arsenic and cadmium from this
source category. However, with regard
to lead, the analysis does not indicate
significant disproportionate impacts.
Nevertheless, the proposed actions in
today’s notice will significantly
decrease the risks due to HAP emissions
from this source category and mitigate
any disproportionate risks due to those
emissions.
List of Subjects in 40 CFR Part 63
Environmental protection, Air
pollution control, Incorporation by
reference, Lead, Reporting and
recordkeeping requirements.
Dated: April 29, 2011.
Lisa P. Jackson,
Administrator.
PART 63—[AMENDED]
1. The authority citation for part 63
continues to read as follows:
Authority: 42 U.S.C. 7401, et seq.
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2. Part 63 is amended by revising
subpart X to read as follows:
Subpart X—National Emission Standards
for Hazardous Air Pollutants From
Secondary Lead Smelting
Sec.
63.541 Applicability.
63.542 Definitions.
63.543 What are my standards for process
vents?
63.544 What are my process enclosure
standards?
63.545 What are my standards for fugitive
dust sources?
63.546 Compliance dates.
63.547 Test methods.
63.548 Monitoring requirements.
63.549 Notification requirements.
63.550 Recordkeeping and reporting
requirements.
63.551 Implementation and enforcement.
63.552 Affirmative Defense for Exceedance
of Emissions Limit During Malfunction.
16:40 May 18, 2011
Subpart X—National Emission
Standards for Hazardous Air Pollutants
From Secondary Lead Smelting
§ 63.541
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Applicability.
(a) You are subject to this subpart if
you own or operate any of the following
equipment or processes at a secondary
lead smelter: Blast, reverberatory, rotary,
and electric furnaces; refining kettles;
agglomerating furnaces; dryers; process
fugitive emissions sources; and fugitive
dust sources. The provisions of this
subpart do not apply to primary lead
smelters, lead refiners, or lead remelters.
(b) Table 1 to this subpart specifies
the provisions of subpart A of this part
that apply to owners and operators of
secondary lead smelters subject to this
subpart.
(c) If you are subject to the provisions
of this subpart, you are also subject to
title V permitting requirements under 40
CFR parts 70 or 71, as applicable.
(d) Emissions standards in this
subpart apply at all times.
§ 63.542
For the reasons stated in the
preamble, part 63 of title 40, chapter I,
of the Code of Federal Regulations is
proposed to be amended as follows:
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Table 1 to Subpart X of Part 63—General
Provisions Applicability to Subpart X
Table 2 to Subpart X of Part 63—Emissions
Limits for Secondary Lead Smelting
Furnaces
Table 3 to Subpart X of Part 60—Toxic
Equivalency Factors
Definitions.
Terms used in this subpart are
defined in the Clean Air Act, in subpart
A of this part, or in this section as
follows:
Affirmative defense means, in the
context of an enforcement proceeding, a
response or defense put forward by a
defendant, regarding which the
defendant has the burden of proof, and
the merits of which are independently
and objectively evaluated in a judicial
or administrative proceeding.
Agglomerating furnace means a
furnace used to melt into a solid mass
flue dust that is collected from a
baghouse.
Bag leak detection system means an
instrument that is capable of monitoring
particulate matter (dust) loadings in the
exhaust of a 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,
transmittance or other effect to monitor
relative particulate matter loadings.
Battery breaking area means the plant
location at which lead-acid batteries are
broken, crushed, or disassembled and
separated into components.
Blast furnace means a smelting
furnace consisting of a vertical cylinder
atop a crucible, into which lead-bearing
charge materials are introduced at the
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top of the furnace and combustion air is
introduced through tuyeres at the
bottom of the cylinder, and that uses
coke as a fuel source and that is
operated at such a temperature in the
combustion zone (greater than 980 °C)
that lead compounds are chemically
reduced to elemental lead metal.
Blast furnace charging location means
the physical opening through which raw
materials are introduced into a blast
furnace.
Collocated blast furnace and
reverberatory furnace means operation
at the same location of a blast furnace
and a reverberatory furnace where the
vent streams of the furnaces are mixed
before cooling, with the volumetric flow
rate discharged from the blast furnace
being equal to or less than that
discharged from the reverberatory
furnace.
Dryer means a chamber that is heated
and that is used to remove moisture
from lead-bearing materials before they
are charged to a smelting furnace.
Dryer transition equipment means the
junction between a dryer and the charge
hopper or conveyor, or the junction
between the dryer and the smelting
furnace feed chute or hopper located at
the ends of the dryer.
Electric furnace means a smelting
furnace consisting of a vessel into which
reverberatory furnace slag is introduced
and that uses electrical energy to heat
the reverberatory furnace slag to such a
temperature (greater than 980 °C) that
lead compounds are reduced to
elemental lead metal.
Enclosure hood means a hood that
covers a process fugitive emission
source on the top and on all sides, with
openings only for access to introduce or
remove materials to or from the source
and through which an induced flow of
air is ventilated.
Fugitive dust source means a
stationary source of hazardous air
pollutant emissions at a secondary lead
smelter that is not associated with a
specific process or process fugitive vent
or stack. Fugitive dust sources include,
but are not limited to, roadways, storage
piles, materials handling transfer points,
materials transport areas, storage areas,
process areas, and buildings.
Furnace and refining/casting area
means any area of a secondary lead
smelter in which:
(1) Smelting furnaces are located; or
(2) Refining operations occur; or
(3) Casting operations occur.
Lead alloy means an alloy in which
the predominant component is lead.
Maintenance activity means any of
the following routine maintenance and
repair activities that generate fugitive
lead dust:
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elemental lead or lead alloys through
processing in high-temperature (greater
than 980 °C) furnaces including, but not
limited to, blast furnaces, reverberatory
furnaces, rotary furnaces, and electric
furnaces.
Total enclosure means a roofed and
walled structure with limited openings
to allow access and egress for people
and vehicles that meets the
requirements of § 265.1101(a)(1),
(a)(2)(i), and (c)(1)(i).
Vehicle wash means a device for
removing dust and other accumulated
material from the wheels, body, and
underside of a vehicle to prevent the
inadvertent transfer of lead
contaminated material to another area of
a secondary lead smelter or to public
roadways.
Wet suppression means the use of
water, water combined with a chemical
surfactant, or a chemical binding agent
to prevent the entrainment of dust into
the air from fugitive dust sources.
dryer transition pieces which is
maintained at a higher pressure than the
inside of the dryer.
Process fugitive emissions source
means a source of hazardous air
pollutant emissions at a secondary lead
smelter that is associated with lead
smelting or refining, but is not the
primary exhaust stream from a smelting
furnace, and is not a fugitive dust
source. Process fugitive sources include,
but are not limited to, smelting furnace
charging points, smelting furnace lead
and slag taps, refining kettles,
agglomerating furnaces, and drying kiln
transition pieces.
Process vent means furnace vents,
dryer vents, agglomeration furnace
vents, vents from battery breakers,
building vents, and any ventilation
system controlling lead emissions.
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 refining and alloying the
lead. Included are pot furnaces,
receiving kettles, and holding kettles.
Reverberatory furnace means a
refractory-lined furnace that uses one or
more flames to heat the walls and roof
of the furnace and lead-bearing scrap to
such a temperature (greater than 980 °C)
that lead compounds are chemically
reduced to elemental lead metal.
Rotary furnace (also known as a rotary
reverberatory furnace) means a furnace
consisting of a refractory-lined chamber
that rotates about a horizontal axis and
that uses one or more flames to heat the
walls of the furnace and lead-bearing
scrap to such a temperature (greater
than 980 °C) that lead compounds are
chemically reduced to elemental lead
metal.
Secondary lead smelter means any
facility at which lead-bearing scrap
material, primarily, but not limited to,
lead-acid batteries, is recycled into
elemental lead or lead alloys by
smelting.
Smelting means the chemical
reduction of lead compounds to
§ 63.543 What are my standards for
process vents?
Where:
CFWA = Flow-weighted average concentration
of all process vents.
n = Number of process vents.
Fi = Flow rate from process vent i in dry
standard cubic feet per minute, as
measured during the most recent
compliance test.
Ci = Concentration of lead in process vent i,
as measured during the most recent
compliance test.
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(a) You must maintain the
concentration of lead compounds in any
process vent gas at or below 1.0
milligrams of lead per dry standard
cubic meter (0.00043 grains of lead per
dry standard cubic foot). You must
maintain the flow-weighted average
concentration of lead compounds in
vent gases from a secondary lead facility
at or below 0.20 milligrams of lead per
dry standard cubic meter (0.000087
grains of lead per dry standard cubic
foot).
(1) You must demonstrate compliance
with the flow weighted average
emissions limit on a 12-month rolling
average basis, calculated monthly.
(2) Until 12 monthly weighted average
emissions rates have been accumulated,
calculate only the monthly average
weighted emissions rate.
(3) You must use Equation 1 of this
section to calculate the flow-weighted
average concentration of lead
compounds from process vents:
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(1) Replacement or repair of
refractory, filter bags, or any internal or
external part of equipment used to
process, handle or control leadcontaining materials.
(2) Replacement of any duct section
used to convey lead-containing exhaust.
(3) Metal cutting or welding that
penetrates the metal structure of any
equipment, and its associated
components, used to process leadcontaining material such that lead dust
within the internal structure or its
components can become fugitive lead
dust.
(4) Resurfacing, repair or removal of
ground, pavement, concrete, or asphalt.
Materials storage and handling area
means any area of a secondary lead
smelter in which lead-bearing materials
(including, but not limited to, broken
battery components, reverberatory
furnace slag, flue dust, and dross) are
stored or handled between process steps
including, but not limited to, areas in
which materials are stored in piles, bins,
or tubs, and areas in which material is
prepared for charging to a smelting
furnace.
Partial enclosure means a structure
comprised of walls or partitions on at
least three sides or three-quarters of the
perimeter surrounding stored materials
or process equipment to prevent the
entrainment of particulate matter into
the air.
Pavement cleaning means the use of
vacuum equipment, water sprays, or a
combination thereof to remove dust or
other accumulated material from the
paved areas of a secondary lead smelter.
Plant roadway means any area of a
secondary lead smelter that is subject to
vehicle traffic, including traffic by
forklifts, front-end loaders, or vehicles
carrying whole batteries 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.
Pressurized dryer breaching seal
means a seal system connecting the
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(c) If you combine furnace emissions
from multiple types of furnaces and
these furnaces do not meet the
definition of collocated blast and
reverberatory furnaces, you must
calculate your emissions limit for the
combined furnace stream using
Equation 2.
annual performance test for total
hydrocarbons emissions from each
process vent (no later than 12 calendar
months following the previous
compliance test).
(h) Following the initial performance
or compliance test to demonstrate
compliance with the dioxins and furans
emissions limits specified in paragraph
(b) of this section, you must conduct a
performance test for dioxins and furans
emissions at least once every 5 years
following the previous compliance test.
(i) You must conduct the performance
tests specified in paragraphs (f) through
(h) of this section under such conditions
as the Administrator specifies based on
representative performance of the
affected source for the period being
tested. Upon request, you must make
available to the Administrator such
records as may be necessary to
determine the conditions of
performance tests.
(j) At all times, you must operate and
maintain any affected source, including
associated air pollution control
equipment and monitoring equipment,
in a manner consistent with safety and
good air pollution control practices for
minimizing emissions. Determination of
whether such operation and
maintenance procedures are being used
will be based on information available
to the Administrator that may include,
but is not limited to, monitoring results,
review of operation and maintenance
procedures, review of operation and
maintenance records, and inspection of
the source.
(k) In addition to complying with the
applicable emissions limits for dioxins
and furans listed in Table 2 to this
subpart, you must operate a process to
separate plastic battery casing materials
prior to introducing feed into a blast
furnace.
§ 63.544 What are my process enclosure
standards?
(d) If you combine furnace emissions
with the furnace charging process
fugitive emissions and discharge them
to the atmosphere through a common
emissions point, you must demonstrate
compliance with the applicable total
hydrocarbons concentration limit
specified in paragraph (b) of this section
at a location downstream from the point
at which the two emissions streams are
combined.
(e) If you do not combine the furnace
charging process fugitive emissions with
the furnace process emissions, and
discharge such emissions to the
atmosphere through separate emissions
points, you must maintain the total
hydrocarbons concentration in the
exhaust gas at or below 20 parts per
million by volume, expressed as
propane.
(f) Following the initial performance
or compliance test to demonstrate
compliance with the lead emissions
limits specified in paragraph (a) of this
section, you must conduct an annual
performance test for lead compounds
from each process vent (no later than 12
calendar months following the previous
compliance test), unless you install and
operate a CEMS and continuous
emissions rate monitoring system
meeting the requirements of
§ 63.548(m).
(g) Following the initial performance
or compliance test to demonstrate
compliance with the total hydrocarbons
emissions limits in paragraphs (b) and
(e) of this section, you must conduct an
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(a) Except as provided in paragraph
(d) of this section, you must locate the
fugitive emissions sources listed in
paragraphs (a)(1) through (a)(9) of this
section in a total enclosure that is
maintained at negative pressure at all
times. The total enclosure must meet the
requirements specified in paragraphs
(b)(1) and (b)(2) of this section.
(1) Smelting furnaces.
(2) Smelting furnace charging areas.
(3) Lead taps, slag taps, and molds
during tapping.
(4) Battery breakers.
(5) Refining kettles, casting areas.
(6) Dryers.
(7) Agglomerating furnaces and
agglomerating furnace product taps.
(8) Material handling areas for any
lead bearing materials (drosses, slag,
other raw materials), excluding areas
where unbroken lead acid batteries and
finished lead products are stored.
(9) Areas where dust from fabric
filters, sweepings or used fabric filters
are handled or processed.
(b) You must construct and operate
total enclosures for the sources listed in
paragraph (a) of this section as specified
in paragraphs (b)(1) and (b)(2) of this
section.
(1) You must ventilate the total
enclosure continuously to ensure
negative pressure values of at least 0.02
mm of mercury (0.011 inches of water).
(2) You must maintain the in-draft
velocity of the total enclosure at greater
than or equal to 300 feet per minute at
any opening including, but not limited
to, vents, windows, passages, doorways,
bay doors and roll-ups doors.
(c) You must inspect enclosures and
facility structures that contain any leadbearing materials at least once per
month. You must repair any gaps,
breaks, separations, leak points or other
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vent, the monthly average lead
concentration and monthly average flow
must be used rather than the most
recent compliance test data.
(b) You must meet the applicable
emissions limits for total hydrocarbons
and dioxins and furans from furnace
sources specified in Table 2 of this
subpart.
Where:
CEL = Flow-weighted average emissions limit
(concentration) of combined furnace
vents.
n = Number of furnace vents.
Fi = Flow rate from furnace vent i in dry
standard cubic feet per minute.
CELi = Emissions limit (concentration) of lead
in furnace vent i as specified in Table 2
of this subpart.
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(4) Each month, you must use the
concentration of lead and flow rate
obtained during the most recent
compliance test performed prior to or
during that month to perform the
calculation.
(5) If a continuous emissions
monitoring system (CEMS) is used to
measure the concentration of lead in a
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possible routes for emissions of lead to
the atmosphere within 72 hours of
identification unless you obtain
approval for an extension from the
Administrator before the repair period is
exceeded.
(d) As an alternative to the
requirements specified in paragraphs (a)
through (c) of this section, you can elect
to demonstrate compliance by meeting
the requirements of (d)(1) through (d)(4)
of this section.
(1) You must install compliance
monitors on or near the plant property
boundary, at locations approved by the
Administrator, to demonstrate that the
lead concentration in air is at all times
maintained below a 3-month rolling
average value of 0.15 μg/m3 at each
monitor. This must include at least two
such monitors and at least one of these
monitors must be in a location that is
expected to have the highest air
concentrations at or near the facility
boundary based on ambient dispersion
modeling or other methods approved by
the Administrator.
(2) You must control the process
fugitive emission sources listed in
paragraphs (d)(2)(i) through (d)(2)(vi) of
this section in accordance with the
equipment and operational standards
presented in paragraphs (d)(3) through
(d)(8) of this section.
(i) Smelting furnace and dryer
charging hoppers, chutes, and skip
hoists.
(ii) Smelting furnace lead taps, and
molds during tapping.
(iii) Smelting furnace slag taps, and
molds during tapping.
(iv) Refining kettles.
(v) Dryer transition pieces.
(vi) Agglomerating furnace product
taps.
(3) Process fugitive emission sources
must be equipped with an enclosure
hood meeting the requirements of
(d)(3)(i), (d)(3)(ii), or (d)(3)(iii) of this
section.
(i) All process fugitive enclosure
hoods except those specified for refining
kettles and dryer transition pieces must
be ventilated to maintain a face velocity
of at least 90 meters per minute (300 feet
per minute) at all hood openings.
(ii) Process fugitive enclosure hoods
required for refining kettles must be
ventilated to maintain a face velocity of
at least 75 meters per minute (250 feet
per minute).
(iii) Process fugitive enclosure hoods
required over dryer transition pieces
must be ventilated to maintain a face
velocity of at least 110 meters per
minute (350 feet per minute).
(iv) Ventilation air from all enclosure
hoods must be conveyed to a control
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device meeting the applicable
requirements of § 63.543.
(4) As an alternative to paragraph
(d)(3)(iii) of this section, you may elect
to control the process fugitive emissions
from dryer transition pieces by
installing and operating pressurized
dryer breaching seals at each transition
piece.
(5) For the battery breaking area,
partial enclosure of storage piles, wet
suppression applied to storage piles
with sufficient frequency and quantity
to prevent the formation of dust, and
pavement cleaning twice per day.
(6) For the furnace area, partial
enclosure and pavement cleaning twice
per day.
(7) For the refining and casting area,
partial enclosure and pavement cleaning
twice per day.
(8) For the materials storage and
handling area, partial enclosure of
storage piles, wet suppression applied
to storage piles with sufficient
frequency and quantity to prevent the
formation of dust.
§ 63.545 What are my standards for
fugitive dust sources?
(a) You must 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 and implemented to
control the fugitive dust emissions from
the sources listed in paragraphs (a)(1)
through (a)(8) of this section.
(1) Plant roadways.
(2) Plant buildings.
(3) Plant building exteriors.
(4) Accidental releases.
(5) Battery storage area.
(6) Equipment maintenance areas.
(7) Material storage areas.
(8) Material handling areas.
(b) You must submit the standard
operating procedures manual to the
Administrator or delegated authority for
review and approval.
(c) The controls specified in the
standard operating procedures manual
must at a minimum include the
requirements specified in paragraphs
(c)(1) through (c)(8) of this section,
unless you satisfy the requirements
specified in paragraph (f) of this section.
(1) Cleaning. Where a cleaning
practice is specified, you must clean by
wet wash or a vacuum equipped with a
filter rated by the manufacturer to
achieve 99.97 percent capture efficiency
for 0.3 micron particles in a manner that
does not generate fugitive lead dust.
(2) Plant roadways and paved areas.
You must pave all areas subject to
vehicle traffic and you must clean the
pavement twice per day, except on days
when natural precipitation makes
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cleaning unnecessary or when sand or a
similar material has been spread on
plant roadways to provide traction on
ice or snow. If you use a mobile vacuum
sweeper for pavement cleaning, the
sweeper must meet the requirements
specified in paragraphs (c)(2)(i) or
(c)(2)(ii) of this section.
(i) If the vacuum sweeper uses water
flushing followed by sweeping, the
water flush must use a minimum
application of 0.48 gallons of water per
square yard of pavement cleaned.
(ii) The vacuum sweeper must be
equipped with a filter rated by the
manufacturer to achieve a capture
efficiency of 99.97 for 0.3 micron
particles.
(3) Plant building exterior. For all
buildings that house areas associated
with storage, handling, or processing of
lead bearing materials, you must
perform a monthly cleaning of building
rooftops on structures that are less than
45 feet in height and quarterly cleaning
of buildings that are greater than 45 feet
in height.
(4) Accidental releases. You must
initiate cleaning of all affected areas
within one hour after any accidental
release of lead dust.
(5) Battery storage areas. You must
inspect any unenclosed battery storage
areas twice each day and immediately
move any broken batteries identified to
an enclosure. You must clean residue
from broken batteries within one hour of
identification.
(6) Materials storage and handling
areas. You must wash each vehicle at
each exit of the material storage and
handling areas. The vehicle wash must
include washing of tires, undercarriage
and exterior surface of the vehicle
followed by vehicle inspection. You
must collect all wash water and store
the wash water in a container that is not
open to the atmosphere if the wash
water is not immediately sent to
treatment.
(7) Equipment maintenance. You
must perform all maintenance activities
for any equipment potentially
contaminated with lead bearing material
or lead dust inside an enclosure
maintained at negative pressure. You
must conduct any maintenance activity
that cannot be conducted in a negative
pressure enclosure due to physical
constraints or safety issues inside a
partial or temporary enclosure and use
wet suppression and/or a vacuum
system equipped with a filter rated by
the manufacturer to achieve a capture
efficiency of 99.97 percent for 0.3
micron particles.
(8) Material transport. You must
transport all lead bearing materials
including, but not limited to, furnace
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charging material, baghouse dust, slag
and any material generated from
cleaning activities, capable of generating
any amount of fugitive lead dust within
closed conveyor systems or in sealed,
leak-proof containers unless the
transport activities are contained within
an enclosure.
(d) Your standard operating
procedures manual must specify that
records be maintained of all pavement
cleaning, vehicle washing, wet
suppression, exterior building cleaning,
and battery storage inspection activities
performed to control fugitive dust
emissions.
(e) You must pave all grounds on the
facility or plant groundcover sufficient
to prevent wind-blown dust. You may
use dust suppressants on unpaved areas
that will not support a groundcover
(e.g., roadway shoulders, steep slopes).
(f) As an alternative to the
requirements specified in paragraphs
(c)(1) through (c)(8) of this section, you
can demonstrate to the Administrator
(or delegated State, local, or Tribal
authority) that an alternative measure(s)
is equivalent or better than a practice(s)
described in paragraphs (c)(1) through
(c)(8) of this section.
§ 63.546
Compliance dates.
(a) For affected sources that
commenced construction or
reconstruction on or before May 19,
2011, you must demonstrate compliance
with the requirements of this subpart no
later than [DATE TWO YEARS AFTER
THE DATE OF PUBLICATION OF THE
FINAL RULE IN THE FEDERAL
REGISTER].
(b) For affected sources that
commenced construction or
reconstruction after May 19, 2011, you
must demonstrate compliance with the
requirements of this subpart by [DATE
TWO YEARS AFTER THE DATE OF
PUBLICATION OF THE FINAL RULE IN
THE FEDERAL REGISTER] or upon
startup of operations, whichever is later.
Test methods.
(2) If the measured percent carbon
dioxide is equal to or less than 0.4
percent, you must use a correction
factor (F) of 10.
(3) You must determine the corrected
total hydrocarbons concentration by
multiplying the measured total
hydrocarbons concentration by the
correction factor (F) determined for each
compliance test.
(d) You must use the following test
methods in appendix A of part 60 listed
in paragraphs (d)(1) through (d)(5) of
this section, as specified, to determine
compliance with the emissions
standards for dioxins and furans
specified in § 63.543(b).
(1) EPA Method 1 at 40 CFR part 60,
appendix A–1 to select the sampling
port location and the number of traverse
points.
(2) EPA Method 2 at 40 CFR part 60,
appendix A–1 or EPA Method 5D at 40
CFR part 60, appendix A–3, section 8.3
for positive pressure fabric filters to
measure volumetric flow rate.
(3) EPA Method 3A or 3B at 40 CFR
part 60, appendix A–2 to determine the
oxygen and carbon dioxide
concentrations of the stack gas.
(4) EPA Method 4 at 40 CFR part 60,
appendix A–3 to determine moisture
content of the stack gas.
(5) EPA Method 23 at 40 CFR part 60,
appendix A–7 to determine the dioxins
and furans concentration.
(e) You must determine the dioxins
and furans toxic equivalency by
following the procedures in paragraphs
(e)(1) through (e)(3) of this section.
(1) Measure the concentration of each
dioxins and furans congener shown in
Table 3 of this subpart using EPA
Method 23 at 40 CFR part 60, appendix
A–7. You must correct the concentration
of dioxins and furans in terms of toxic
equivalency to 7 percent O2 using
Equation (3) of this section.
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(a) You must use the test methods
from appendix A of part 60 as listed in
paragraphs (a)(1) through (a)(5) of this
section to determine compliance with
the emissions standards for lead
compounds specified in § 63.543(a).
(1) EPA Method 1 at 40 CFR part 60,
appendix A–1 to select the sampling
port location and the number of traverse
points.
Where:
F = Correction factor (no units).
CO2 = Percent carbon dioxide measured
using EPA Method 3A or 3B at 40 CFR
part 60, appendix A–2, where the
measured carbon dioxide is greater than
0.4 percent.
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§ 63.547
(2) EPA Method 2 at 40 CFR part 60,
appendix A–1 or EPA Method 5D at 40
CFR part 60, appendix A–3, section 8.3
for positive pressure fabric filters, to
measure volumetric flow rate.
(3) EPA Method 3, 3A, or 3B at 40
CFR part 60, appendix A–2 to determine
the dry molecular weight of the stack
gas.
(4) EPA Method 4 at 40 CFR part 60,
appendix A–3 to determine moisture
content of the stack gas.
(5) EPA Method 29 at 40 CFR part 60,
appendix A–8 to determine compliance
with the lead compound emissions
standards. The minimum sample
volume must be 2.0 dry standard cubic
meters (70 dry standard cubic feet) for
each run. You must perform three test
runs and you must determine
compliance using the average of the
three runs.
(b) You must use the following test
methods in appendix A of part 60 listed
in paragraphs (b)(1) through (b)(4) of
this section, as specified, to determine
compliance with the emissions
standards for total hydrocarbons
specified in § 63.543(b) and (e).
(1) EPA Method 1 at 40 CFR part 60,
appendix A–1 to select the sampling
port location and number of traverse
points.
(2) The Single Point Integrated
Sampling and Analytical Procedure of
Method 3B to measure the carbon
dioxide content of the stack gases when
using either EPA Method 3A or 3B at 40
CFR part 60, appendix A–2.
(3) EPA Method 4 at 40 CFR part 60,
appendix A–3 to measure moisture
content of the stack gases.
(4) EPA Method 25A at 40 CFR part
60, appendix A–7 to measure total
hydrocarbons emissions. The minimum
sampling time must be
1 hour for each run. You must perform
a minimum of three test runs. You must
calculate a 1-hour average total
hydrocarbons concentration for each
run and use the average of the three 1hour averages to determine compliance.
(c) You must correct the measured
total hydrocarbons concentrations to 4
percent carbon dioxide as specified in
paragraphs (c)(1) through (c)(3) of this
section.
(1) If the measured percent carbon
dioxide is greater than 0.4 percent in
each compliance test, you must
determine the correction factor using
Equation (2) of this section.
Federal Register / Vol. 76, No. 97 / Thursday, May 19, 2011 / Proposed Rules
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Where:
Cadj = Dioxins and furans concentration
adjusted to 7 percent oxygen.
Cmeas = Dioxins and furans concentration
measured in nanograms per dry standard
cubic meter.
(20.9 ¥ 7) = 20.9 percent oxygen ¥ 7 percent
oxygen (defined oxygen correction
basis).
20.9 = Oxygen concentration in air, percent.
%O2 = Oxygen concentration measured on a
dry basis, percent.
(2) For each dioxins and furans
congener measured as specified in
paragraph (e)(1) of this section, multiply
the congener concentration by its
corresponding toxic equivalency factor
specified in Table 3 to this subpart.
(3) Sum the values calculated as
specified in paragraph (e)(2) of this
section to obtain the total concentration
of dioxins and furans emitted in terms
of toxic equivalency.
(f) You must determine compliance
with the doorway in-draft requirement
for enclosed buildings in § 63.544(b)
using the procedures specified in
paragraphs (f)(1) through (f)(3) of this
section.
(1) You must use a propeller
anemometer or equivalent device
meeting the requirements of paragraphs
(f)(1)(i) through (f)(1)(iii) of this section.
(i) The propeller of the anemometer
must be made of a material of uniform
density and must be properly balanced
to optimize performance.
(ii) The measurement range of the
anemometer must extend to at least 300
meters per minute (1,000 feet per
minute).
(iii) A known relationship must exist
between the anemometer signal output
and air velocity, and the anemometer
must be equipped with a suitable
readout system.
(2) You must determine the doorway
in-draft by placing the anemometer in
the plane of the doorway opening near
its center.
(3) You must demonstrate the
doorway in-draft for each doorway that
is open during normal operation with
all other doorways remaining in the
position they are in during normal
operation.
(g) If you comply with the
requirements specified in § 63.544(d)(1),
you must use the EPA method at 40 CFR
part 50, appendix G to measure the
concentration of lead in air.
(h) If you comply with the
requirements specified in § 63.544(d)(2)
and (d)(3) for enclosure hoods, you must
determine compliance with the face
velocity requirements by using the test
methods in paragraph (h)(1) or (h)(2) of
this section.
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(1) Calculate face velocity using the
procedures in paragraphs (h)(1)(i)
through (h)(1)(iv) of this section.
(i) Method 1 at 40 CFR part 60,
appendix A–1 must be used to select the
sampling port location in the duct
leading from the process fugitive
enclosure hood to the control device.
(ii) Method 2 at 40 CFR part 60,
appendix A–1 must be used to measure
the volumetric flow rate in the duct
from the process fugitive enclosure
hood to the control device.
(iii) The face area of the hood must be
determined from measurement of the
hood. If the hood has access doors, then
the face area must be determined with
the access doors in the position they are
in during normal operating conditions.
(iv) Face velocity must be determined
by dividing the volumetric flow rate as
determined in paragraph (h)(1)(ii) of this
section by the total face area for the
hood determined in paragraph (h)(2)(iii)
of this section.
(2) The face velocity may be measured
directly using the procedures in
paragraphs (h)(2)(i) through (h)(2)(v) of
this section.
(i) A propeller anemometer or
equivalent device must be used to
measure hood face velocity.
(ii) The propeller of the anemometer
must be made of a material of uniform
density and must be properly balanced
to optimize performance.
(iii) The measurement range of the
anemometer must extend to at least 300
meters per minute (1,000 feet per
minute).
(iv) A known relationship must exist
between the anemometer signal output
and air velocity, and the anemometer
must be equipped with a suitable
readout system.
(v) Hood face velocity must be
determined for each hood open during
normal operation by placing the
anemometer in the plane of the hood
opening. Access doors must be
positioned consistent with normal
operation.
§ 63.548
Monitoring requirements.
(a) You must prepare, and at all times
operate according to, a standard
operating procedures manual that
describes in detail procedures for
inspection, maintenance, and bag leak
detection and corrective action plans for
all baghouses (fabric filters or cartridge
filters) that are used to control process
vents, process fugitive, or fugitive dust
emissions from any source subject to the
lead emissions standards in §§ 63.543,
63.544, and 63.545, including those
used to control emissions from building
ventilation.
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(b) You must submit the standard
operating procedures manual for
baghouses required by paragraph (a) of
this section to the Administrator or
delegated authority for review and
approval.
(c) The procedures that you specify in
the standard operating procedures
manual for inspections and routine
maintenance must, 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.
(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) Monthly check of bag tension on
reverse air and shaker-type baghouses.
Such checks are not required for shakertype baghouses using self-tensioning
(spring loaded) devices.
(7) Quarterly confirmation of the
physical integrity of the baghouse
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) Continuous operation of a bag leak
detection system, unless a system
meeting the requirements of paragraph
(m) of this section, for a CEMS and
continuous emissions rate monitoring
system is installed for monitoring the
concentration of lead.
(d) The procedures you specified in
the standard operating procedures
manual for baghouse maintenance must
include, at a minimum, 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, must meet the specification and
requirements of paragraphs (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
1.0 milligram per actual cubic meter
(0.00044 grains per actual cubic foot) or
less.
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(2) The bag leak detection system
sensor must provide output of relative
particulate matter loadings.
(3) The bag leak detection system
must be equipped with an alarm system
that will alarm when an increase in
relative particulate loadings is detected
over a preset level.
(4) You must install and operate the
bag leak detection system in a manner
consistent with the guidance provided
in ‘‘Office of Air Quality Planning and
Standards (OAQPS) Fabric Filter Bag
Leak Detection Guidance’’ EPA–454/R–
98–015, September 1997 (incorporated
by reference) and the manufacturer’s
written specifications and
recommendations for installation,
operation, and adjustment of the system.
(5) 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.
(6) Following initial adjustment, you
must not adjust the sensitivity or range,
averaging period, alarm set points, or
alarm delay time, except as detailed in
the approved standard operating
procedures manual required under
paragraph (a) of this section. You cannot
increase the sensitivity by more than
100 percent or decrease the sensitivity
by more than 50 percent over a 365 day
period unless such adjustment follows a
complete baghouse inspection that
demonstrates that the baghouse is in
good operating condition.
(7) For negative pressure, induced air
baghouses, and positive pressure
baghouses that are discharged to the
atmosphere through a stack, you must
install the bag leak detector 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) You must include in the standard
operating procedures manual required
by paragraph (a) of this section a
corrective action plan that specifies the
procedures to be followed in the case of
a bag leak detection system alarm. The
corrective action plan must include, at
a minimum, the procedures that you
will use to determine and record the
time and cause of the alarm as well as
the corrective actions taken to minimize
emissions as specified in paragraphs
(f)(1) and (f)(2) of this section.
(1) The procedures used to determine
the cause of the alarm must be initiated
within 30 minutes of the alarm.
(2) The cause of the alarm must be
alleviated by taking the necessary
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corrective action(s) that may include,
but not be limited to, those listed in
paragraphs (f)(2)(i) through (f)(2)(vi) of
this section.
(i) Inspecting the baghouse for air
leaks, torn or broken filter elements, or
any other malfunction 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 emissions.
(g) If you use a wet scrubber to control
particulate matter and metal hazardous
air pollutant emissions from an affected
source to demonstrate continuous
compliance with the emissions
standards, you must monitor and record
the pressure drop and water flow rate of
the wet scrubber during the initial
performance or compliance test
conducted to demonstrate compliance
with the lead emissions limit under
§ 63.543(a). Thereafter, you must
monitor and record the pressure drop
and water flow rate values at least once
every hour and you must maintain the
pressure drop and water flow rate at
levels no lower than 30 percent below
the pressure drop and water flow rate
measured during the initial performance
or compliance test.
(h) You must comply with the
requirements specified in paragraphs
(h)(1) through (h)(5) of this section to
demonstrate continuous compliance
with the total hydrocarbons and dioxins
and furans emissions standards.
(1) Continuous temperature
monitoring. You must install, calibrate,
maintain, and continuously operate a
device to monitor and record the
temperature of the afterburner or
furnace exhaust streams consistent with
the requirements for continuous
monitoring systems in subpart A of this
part.
(2) Prior to or in conjunction with the
initial performance or compliance test
to determine compliance with
§ 63.543(b), you must conduct a
performance evaluation for the
temperature monitoring device
according to § 63.8(e). The definitions,
installation specifications, test
procedures, and data reduction
procedures for determining calibration
drift, relative accuracy, and reporting
described in Performance Specification
2, 40 CFR part 60, appendix B, sections
2, 3, 5, 7, 8, 9, and 10 must be used to
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conduct the evaluation. The
temperature monitoring device must
meet the following performance and
equipment specifications:
(i) The recorder response range must
include zero and 1.5 times the average
temperature identified in paragraph
(h)(3) of this section.
(ii) The monitoring system calibration
drift must not exceed 2 percent of 1.5
times the average temperature identified
in paragraph (h)(3) of this section.
(iii) The monitoring system relative
accuracy must not exceed 20 percent.
(iv) The reference method must be a
National Institute of Standards and
Technology calibrated reference
thermocouple-potentiometer system or
an alternate reference, subject to the
approval of the Administrator.
(3) You must monitor and record the
temperature of the afterburner or the
furnace exhaust streams every 15
minutes during the initial performance
or compliance test for total
hydrocarbons and dioxins and furans
and determine an arithmetic average for
the recorded temperature
measurements.
(4) To demonstrate continuous
compliance with the standards for total
hydrocarbons and dioxins and furans,
you must maintain an afterburner or
exhaust temperature such that the
average temperature in any 3-hour
period does not fall more than 28 °C
(50 °F) below the average established in
paragraph (h)(3) of this section.
(i) You must install, operate, and
maintain a digital differential pressure
monitoring system to continuously
monitor each total enclosure as
described in paragraphs (i)(1) through
(i)(6) of this section.
(1) You must install and maintain a
minimum of one building digital
differential pressure monitoring system
at each of the following three walls in
each total enclosure that has a total
ground surface area of 10,000 square
feet or more:
(i) The leeward wall.
(ii) The windward wall.
(iii) An exterior wall that connects the
leeward and windward wall at a
location defined by the intersection of a
perpendicular line between a point on
the connecting wall and a point on its
furthest opposite exterior wall, and
intersecting within plus or minus ten
meters of the midpoint of a straight line
between the two other monitors
specified. The midpoint monitor must
not be located on the same wall as either
of the other two monitors.
(2) You must install and maintain a
minimum of one building digital
differential pressure monitoring system
at the leeward wall of each total
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enclosure that has a total ground surface
area of less than 10,000 square feet.
(3) The digital differential pressure
monitoring systems must be certified by
the manufacturer to be capable of
measuring and displaying negative
pressure in the range of 0.01 to 0.2 mm
mercury (0.005 to 0.11 inches of water)
with a minimum accuracy of plus or
minus 0.001 mm mercury (0.0005
inches of water).
(4) You must equip each digital
differential pressure monitoring system
with a continuous recorder.
(5) You must calibrate each digital
differential pressure monitoring system
in accordance with manufacturer’s
specifications at least once every 12
calendar months or more frequently if
recommended by the manufacturer.
(6) You must equip the digital
differential pressure monitoring system
with a backup, uninterruptible power
supply to ensure continuous operation
of the monitoring system during a
power outage.
(j) You must monitor the doorway indraft velocity at each building opening
once per day to demonstrate continuous
compliance with the in-draft
requirements in § 63.544(b)(2).
(k) If you comply with the
requirements specified in § 63.544(d),
you must comply with the requirements
specified in paragraphs (k)(1) through
(3) of this section.
(1) You must install, operate and
maintain a continuous monitoring
system for the measurement of lead
compound concentrations in air as
specified in paragraphs (k)(1)(i) through
(k)(1)(v) of this section.
(i) You must operate a minimum of
two compliance monitors sufficient in
location and frequency of sample
collection to detect expected maximum
concentrations of lead compounds in air
due to emissions from the affected
source(s) in accordance with a written
plan as described in paragraph (k)(1)(ii)
of this section and approved by the
Administrator. The plan must include
descriptions of the sampling and
analytical methods used. The plan may
take into consideration existing
monitoring being conducted under a
State monitoring plan in accordance
with 40 CFR part 58. At least one 24hour sample must be collected from
each monitor every 6 days except during
periods or seasons exempted by the
Administrator.
(ii) You must submit a written plan
describing and explaining the basis for
the design and adequacy of the
compliance monitoring network, the
sampling, analytical, and quality
assurance procedures, and any other
related procedures, and the justification
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for any seasonal, background, or other
data adjustments within 45 days after
the effective date of this subpart.
(iii) The Administrator at any time
may require changes in, or expansion of,
the monitoring program, including
additional sampling and, more frequent
sampling, revisions to the analytical
protocols and network design.
(iv) If all rolling 3-month average
concentrations of lead in air measured
by the compliance monitoring system
are less than 50 percent of the lead
concentration limits specified in
§ 63.544(d)(1) for 3 consecutive years,
you may submit a proposed revised plan
to reduce the monitoring sampling and
analysis frequency to the Administrator
for review. If approved by the
Administrator, you may adjust your
monitoring accordingly.
(v) For any subsequent period, if any
rolling 3-month average lead
concentration in air measured at any
monitor in the monitoring system
exceeds 50 percent of the concentration
limits specified in § 63.544(d)(1), you
must resume monitoring pursuant to
paragraph (k)(1)(i) of this section at all
monitors until another 3 consecutive
years of lead concentration
measurements is demonstrated to be
less than 50 percent of the lead
concentration limits specified in
§ 63.544(d)(1).
(2) You must monitor the enclosure
hood face velocity at each hood once
per week to demonstrate continuous
compliance with the in-draft
requirements in § 63.544(d)(3).
(3) If you use pressurized dryer
breaching seals in order to comply with
the requirements of § 63.544(d)(4), you
must equip each seal with an alarm that
will ‘‘sound’’ or ‘‘go off’’ if the
pressurized dryer breaching seal
malfunctions.
(l) All new or modified sources
subject to the requirements under
§ 63.543 must install, calibrate,
maintain, and operate a CEMS for
measuring lead emissions and a
continuous emissions rate monitoring
system subject to Performance
Specification 6 of appendix B to part 60
of this chapter. You must comply with
the requirements for CEMS and
continuous emissions rate monitoring
system specified in paragraph (m) of
this section.
(1) Sources subject to the emissions
limits for lead compounds under
§ 63.543(a) must install a CEMS for
measuring lead emissions within 180
days of promulgation of performance
specifications for lead CEMS.
(2) Prior to promulgation of
performance specifications for CEMS
used to measure lead concentrations,
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you must use the procedure described
in § 63.543(a)(1) through (a)(4) to
determine compliance.
(m) If a CEMS is used to measure lead
emissions, you must install a
continuous emissions rate monitoring
system with a sensor in a location that
provides representative measurement of
the exhaust gas flow rate at the sampling
location of the CEMS used to measure
lead emissions, taking into account the
manufacturer’s recommendations. The
flow rate sensor is that portion of the
system that senses the volumetric flow
rate and generates an output
proportional to that flow rate.
(1) The continuous emissions rate
monitoring system must be designed to
measure the exhaust gas flow rate over
a range that extends from a value of at
least 20 percent less than the lowest
expected exhaust flow rate to a value of
at least 20 percent greater than the
highest expected exhaust gas flow rate.
(2) The continuous emissions rate
monitoring system must be equipped
with a data acquisition and recording
system that is capable of recording
values over the entire range specified in
paragraph (m)(1) of this section.
(3) You must perform an initial
relative accuracy test of the continuous
emissions rate monitoring system in
accordance with the applicable
Performance Specification in appendix
B to part 60 of this chapter.
(4) You must operate the continuous
emissions rate monitoring system and
record data during all periods of
operation of the affected facility
including periods of startup, shutdown,
and malfunction, except for periods of
monitoring system malfunctions, repairs
associated with monitoring system
malfunctions, and required monitoring
system quality assurance or quality
control activities including, as
applicable, calibration checks and
required zero and span adjustments.
(5) You must calculate the average
lead concentration and flow rate
monthly to determine compliance with
§ 63.543(a).
(6) When the continuous emissions
rate monitoring system is unable to
provide quality assured data, the
following apply:
(i) When data are not available for
periods of up to 48 hours, the highest
recorded hourly emissions rate from the
previous 24 hours must be used.
(ii) When data are not available for 48
or more hours, the maximum daily
emissions rate based on the previous 30
days must be used.
§ 63.549
Notification requirements.
(a) You must comply with all of the
notification requirements of § 63.9 of
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subpart A, General Provisions.
Electronic notifications are encouraged
when possible.
(b) You must submit the fugitive dust
control standard operating procedures
manual required under § 63.545(a) and
the standard operating procedures
manual for baghouses required under
§ 63.548(a) to the Administrator or
delegated authority along with a
notification that the smelter is seeking
review and approval of these plans and
procedures. You must submit this
notification no later than [DATE ONE
YEAR AFTER PUBLICATION OF THE
FINAL RULE IN THE FEDERAL
REGISTER]. For sources that
commenced construction or
reconstruction after [INSERT THE DATE
OF PUBLICATION OF THE FINAL
RULE IN THE FEDERAL REGISTER],
you must submit this notification no
later than 180 days before startup of the
constructed or reconstructed secondary
lead smelter, but no sooner than [DATE
OF PUBLICATION OF THE FINAL
RULE IN THE FEDERAL REGISTER].
For an affected source that has received
a construction permit from the
Administrator or delegated authority on
or before [INSERT DATE OF
PUBLICATION OF THE FINAL RULE IN
THE FEDERAL REGISTER], you must
submit this notification no later than
[DATE ONE YEAR AFTER
PUBLICATION OF THE FINAL RULE IN
THE FEDERAL REGISTER].
jlentini on DSK4TPTVN1PROD with PROPOSALS2
§ 63.550 Recordkeeping and reporting
requirements.
(a) You must comply with all of the
recordkeeping and reporting
requirements specified in § 63.10 of the
General Provisions that are referenced
in Table 1 to this subpart.
(1) Records must be maintained in a
form suitable and readily available for
expeditious review, according to
§ 63.10(b)(1). However, electronic
recordkeeping and reporting is
encouraged, and required for some
records and reports.
(2) Records must be kept on site for
at least 2 years after the date of
occurrence, measurement, maintenance,
corrective action, report, or record,
according to § 63.10(b)(1).
(b) The standard operating procedures
manuals required in § 63.545(a) and
§ 63.548(a) must be submitted to the
Administrator in electronic format for
review and approval of the initial
submittal and whenever an update is
made to the procedure.
(c) You must maintain for a period of
5 years, records of the information listed
in paragraphs (c)(1) through (c)(15) of
this section.
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(1) Electronic records of the bag leak
detection system output.
(2) 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 corrective actions
taken, and the date and time the cause
of the alarm was corrected.
(3) All records of inspections and
maintenance activities required under
§ 63.548(c) as part of the practices
described in the standard operating
procedures manual for baghouses
required under § 63.548(a).
(4) Electronic records of the pressure
drop and water flow rate values for wet
scrubbers used to control metal
hazardous air pollutant emissions from
process fugitive sources as required in
§ 63.548(g).
(5) Electronic records of the output
from the continuous temperature
monitor required in § 63.548(h)(1), and
an identification of periods when the
3-hour average temperature fell below
the minimum established under
§ 63.548(h)(3), and an explanation of the
corrective actions taken.
(6) Electronic records of the
continuous pressure monitors for total
enclosures required in § 63.548(i), and
an identification of periods when the
pressure was not maintained as required
in § 63.544(b)(1).
(7) Records of the daily measurements
of doorway in-draft velocity required in
§ 63.548(j), and an identification of the
periods when the velocity was not
maintained as required in § 63.544(b)(2).
(8) Records of the inspections of
facility enclosures required in
§ 63.544(c).
(9) Records of all cleaning and
inspections required as part of the
practices described in the standard
operating procedures manual required
under § 63.545(a) for the control of
fugitive dust emissions.
(10) Records of the compliance
monitoring required in § 63.548(k)(1), if
applicable.
(11) Records of the face velocity
measurements required in
§ 63.548(k)(2), if applicable, and an
identification of periods when the face
velocity was not maintained as required
in § 63.544(d)(2) and (d)(3).
(12) Records of the dryer breaching
seal alarms required in § 63.548(k)(3).
(13) Electronic records of the output
of any CEMS installed to monitor lead
emissions meeting the requirements of
§ 63.548(m).
(14) Records of the occurrence and
duration of each malfunction of
operation (i.e., process equipment) or
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the air pollution control equipment and
monitoring equipment.
(15) Records of actions taken during
periods of malfunction to minimize
emissions in accordance with
§ 63.543(j), including corrective actions
to restore malfunctioning process and
air pollution control and monitoring
equipment to its normal or usual
manner of operation.
(d) You must comply with all of the
reporting requirements specified in
§ 63.10 of the General Provisions that
are referenced in Table 1 to this subpart.
(1) You must submit reports no less
frequent than specified under
§ 63.10(e)(3) of the General Provisions.
(2) Once a source reports a violation
of the standard or excess emissions, you
must follow the reporting format
required under § 63.10(e)(3) until a
request to reduce reporting frequency is
approved by the Administrator.
(e) In addition to the information
required under the applicable sections
of § 63.10, you must include in the
reports required under paragraph (d) of
this section the information specified in
paragraphs (e)(1) through (e)(14) of this
section.
(1) Records of the concentration of
lead in each process vent, and records
of the rolling 12-month flow-weighted
average concentration of lead
compounds in vent gases calculated
monthly as required in § 63.543(a).
(2) Records of all alarms from the bag
leak detection system specified in
§ 63.548.
(3) A description of the procedures
taken following each bag leak detection
system alarm pursuant to § 63.548(f)(1)
and (2).
(4) A summary of the records
maintained as part of the practices
described in the standard operating
procedures manual for baghouses
required under § 63.548(a), including an
explanation of the periods when the
procedures were not followed and the
corrective actions taken.
(5) An identification of the periods
when the pressure drop and water flow
rate of wet scrubbers used to control
process fugitive sources dropped below
the levels established in § 63.548(g), and
an explanation of the corrective actions
taken.
(6) Records of the temperature
monitor output, in 3-hour block
averages, for those periods when the
temperature monitored pursuant to
§ 63.548(h) fell below the level
established in § 63.548(h)(4).
(7) Certification that the plastic
separation process for battery breakers
required in § 63.543(k) was operated at
all times the battery breaker was in
service.
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(8) Records of periods when the
pressure was not maintained as required
in § 63.544(b)(1), or the in-draft velocity
was not maintained as required in
§ 63.544(b)(2).
(9) If a malfunction occurred during
the reporting period, the report must
include the number, duration, and a
brief description for each type of
malfunction that occurred during the
reporting period and caused or may
have caused any applicable emissions
limitation to be exceeded. The report
must also include a description of
actions taken by an owner or operator
during a malfunction of an affected
source to minimize emissions in
accordance with § 63.543(j), including
actions taken to correct a malfunction.
(10) A summary of the fugitive dust
control measures performed during the
required reporting period, including an
explanation of the periods when the
procedures outlined in the standard
operating procedures manual pursuant
to § 63.545(a) were not followed and the
corrective actions taken. The reports
must not contain copies of the daily
records required to demonstrate
compliance with the requirements of the
standard operating procedures manuals
required under § 63.545(a).
(11) If you comply with the
requirements in § 63.544(d)(1), you must
provide records of all results of air
monitoring required in § 63.548(k)(1).
(12) Records of periods when the
enclosure hood face velocity was not
maintained as required in § 63.544(d)(3).
(13) Records of the dryer seal
breaching alarms required in
§ 63.548(k)(3).
(14) You must submit records
pursuant to paragraphs (e)(14)(i)
through (iii) of this section.
(i) As of January 1, 2012 and within
60 days after the date of completing
each performance test, as defined in
§ 63.2 and as required in this subpart,
you must submit performance test data,
except opacity data, electronically to
EPA’s Central Data Exchange by using
the Electronic Reporting Tool (see
https://www.epa.gov/ttn/chief/ert/
ert_tool.html/). Only data collected
using test methods compatible with the
Electronic Reporting Tool are subject to
this requirement to be submitted
electronically into EPA’s WebFIRE
database.
(ii) Within 60 days after the date of
completing each CEMS performance
evaluation test, as defined in § 63.2 and
required by this subpart, you must
submit the relative accuracy test audit
data electronically into EPA’s Central
Data Exchange by using the Electronic
Reporting Tool as mentioned in
paragraph (e)(14)(i) of this section. Only
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data collected using test methods
compatible with the Electronic
Reporting Tool are subject to this
requirement to be submitted
electronically into EPA’s WebFIRE
database.
(iii) All reports required by this
subpart not subject to the requirements
in paragraphs (e)(14)(i) and (ii) of this
section must be sent to the
Administrator at the appropriate
address listed in § 63.13. The
Administrator or the delegated authority
may request a report in any form
suitable for the specific case (e.g., by
electronic media such as Excel
spreadsheet, on CD or hard copy). The
Administrator retains the right to
require submittal of reports subject to
paragraphs (e)(14)(i) and (ii) of this
section in paper format.
§ 63.551
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 (c)(4) of this section.
(1) Approval of alternatives to the
requirements in §§ 63.541, 63.543
through 63.544, § 63.545, and § 63.546.
(2) Approval of major alternatives to
test methods for under § 63.7(e)(2)(ii)
and (f), as defined in § 63.90, and as
required in this subpart.
(3) Approval of major alternatives to
monitoring under § 63.8(f), as defined in
§ 63.90, and as required in this subpart.
(4) Approval of major alternatives to
recordkeeping and reporting under
§ 63.10(f), as defined in § 63.90, and as
required in this subpart.
§ 63.552 Affirmative defense for
exceedance of emissions limit during
malfunction.
In response to an action to enforce the
standards set forth in this subpart, you
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may assert an affirmative defense to a
claim for civil penalties for exceedances
of such standards that are caused by
malfunction, as defined at § 63.2.
Appropriate penalties may be assessed,
however, if you fail to meet your burden
of proving all of the requirements in the
affirmative defense. The affirmative
defense shall not be available for claims
for injunctive relief.
(a) Affirmative defense. To establish
the affirmative defense in any action to
enforce such a limit, you must timely
meet the notification requirements in
paragraph (b) of this section, and must
prove by a preponderance of evidence
that:
(1) The excess emissions:
(i) Were caused by a sudden,
infrequent, and unavoidable failure of
air pollution control and monitoring
equipment, process equipment, or a
process to operate in a normal or usual
manner.
(ii) Could not have been prevented
through careful planning, proper design
or better operation and maintenance
practices.
(iii) Did not stem from any activity or
event that could have been foreseen and
avoided, or planned for.
(iv) Were not part of a recurring
pattern indicative of inadequate design,
operation, or maintenance.
(2) Repairs were made as
expeditiously as possible when the
applicable emissions limitations were
being exceeded. Off-shift and overtime
labor were used, to the extent
practicable to make these repairs.
(3) The frequency, amount and
duration of the excess emissions
(including any bypass) were minimized
to the maximum extent practicable
during periods of such emissions.
(4) If the excess emissions resulted
from a bypass of control equipment or
a process, then the bypass was
unavoidable to prevent loss of life,
personal injury, or severe property
damage.
(5) All possible steps were taken to
minimize the impact of the excess
emissions on ambient air quality, the
environment and human health.
(6) All emissions monitoring and
control systems were kept in operation
if at all possible, consistent with safety
and good air pollution control practices.
(7) All of the actions in response to
the excess emissions were documented
by properly signed, contemporaneous
operating logs.
(8) At all times, the affected source
was operated in a manner consistent
with good practices for minimizing
emissions.
(9) A written root cause analysis has
been prepared, the purpose of which is
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to determine, correct, and eliminate the
primary causes of the malfunction and
the excess emissions resulting from the
malfunction event at issue. The analysis
shall also specify, using best monitoring
methods and engineering judgment, the
amount of excess emissions that were
the result of the malfunction.
(b) Notification. The owner or
operator of the affected source
experiencing an exceedance of its
emissions limit(s) during a malfunction,
shall notify the Administrator by
telephone or facsimile transmission as
soon as possible, but no later than two
business days after the initial
occurrence of the malfunction, it wishes
to avail itself of an affirmative defense
to civil penalties for that malfunction.
The owner or operator seeking to assert
an affirmative defense, shall also submit
a written report to the Administrator
within 45 days of the initial occurrence
of the exceedance of the standard in this
subpart to demonstrate, with all
necessary supporting documentation,
that it has met the requirements set forth
in paragraph (a) of this section. The
owner or operator may seek an
extension of this deadline for up to 30
additional days by submitting a written
request to the Administrator before the
expiration of the 45 day period. Until a
request for an extension has been
approved by the Administrator, the
owner or operator is subject to the
requirement to submit such report
within 45 days of the initial occurrence
of the exceedance.
TABLE 1 TO SUBPART X OF PART 63—GENERAL PROVISIONS APPLICABILITY TO SUBPART X
Applies to subpart X
63.1 .................................................
63.2 .................................................
63.3 .................................................
63.4 .................................................
63.5 .................................................
63.6(a), (b), (c) ................................
63.6(d) .............................................
63.6(e)(1)(i) .....................................
63.6(e)(1)(ii) .....................................
63.6(e)(1)(iii) ....................................
63.6(e)(2) .........................................
63.6(e)(3) .........................................
63.6(f)(1) ..........................................
63.6(g) .............................................
63.6(h) .............................................
63.6(i) ..............................................
63.6(j) ..............................................
§ 63.7(a)–(d) ....................................
§ 63.7(e)(1) ......................................
§ 63.7(e)(2)–(e)(4) ...........................
63.7(f), (g), (h) .................................
63.8(a)–(b) .......................................
63.8(c)(1)(i) ......................................
63.8(c)(1)(ii) .....................................
63.8(c)(1)(iii) ....................................
63.8(c)(2)–(d)(2) ..............................
63.8(d)(3) .........................................
63.8(e)–(g) .......................................
63.9(a), (b), (c), (e), (g), (h)(1)
through (3), (h)(5) and (6), (i) and
(j).
63.9(f) ..............................................
63.9(h)(4) .........................................
63.10 (a) ..........................................
63.10 (b)(1) .....................................
63.10(b)(2)(i) ...................................
63.10(b)(2)(ii) ...................................
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Reference
Yes.
Yes.
Yes.
Yes.
Yes.
Yes.
No ..................................................
No ..................................................
No.
Yes.
No ..................................................
No.
No.
Yes.
No ..................................................
Yes.
Yes.
Yes.
No ..................................................
Yes.
Yes.
Yes.
No ..................................................
Yes.
No.
Yes.
Yes, except for last sentence
Yes.
Yes.
63.10(b)(2)(iii) ..................................
63.10(b)(2)(iv)–(b)(2)(v) ...................
63.10(b)(2)(vi)–(b)(2)(xiv) ................
63.(10)(b)(3) ....................................
63.10(c)(1)–(9) ................................
63.10(c)(10)–(11) ............................
63.10(c)(12)–(c)(14) ........................
63.10(c)(15) .....................................
63.10(d)(1)–(4) ................................
63.10(d)(5) .......................................
63.10(e)–((f) ....................................
63.11 ...............................................
63.12 to 63.15 .................................
Yes.
No.
Yes.
Yes.
Yes.
No ..................................................
Yes.
No.
Yes.
No ..................................................
Yes.
No ..................................................
Yes.
VerDate Mar<15>2010
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No.
No ..................................................
Yes.
Yes.
No.
No ..................................................
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Comment
Section reserved.
See 63.543(j) for general duty requirement.
Section reserved.
No opacity limits in rule.
See 63.543(i).
See 63.543(j) for general duty requirement.
Reserved.
See 63.550 for recordkeeping of occurrence and duration of malfunctions and recordkeeping of actions taken during malfunction.
See 63.550 for recordkeeping of malfunctions.
See 63.550(c)(7) for reporting of malfunctions.
Flares will not be used to comply with the emission limits.
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TABLE 2 TO SUBPART X OF PART 63—EMISSIONS LIMITS FOR SECONDARY LEAD SMELTING FURNACES
You must meet the following emissions
limits
Total hydrocarbon
ppm by volume
expressed as propane corrected to
4 percent carbon
dioxide
For vents from these processes
Collocated blast and reverberatory furnace ...............................................................................................
Collocated blast and reverberatory furnace when the Reverberatory furnace is not operating ................
Collocated blast and reverberatory furnace that commence construction after June 9, 1994 ..................
Collocated blast and reverberatory furnace that commence construction after [INSERT DATE 24
MONTHS AFTER PUBLICATION OF THE FINAL RULE IN THE FEDERAL REGISTER].
Blast furnace ...............................................................................................................................................
Blast furnaces that commence construction or reconstruction after June 9, 1994 ...................................
Reverberatory and electric furnace ............................................................................................................
Reverberatory and electric furnace that commence construction or reconstruction after [INSERT DATE
24 MONTHS AFTER PUBLICATION OF THE FINAL RULE IN THE FEDERAL REGISTER].
Rotary furnaces ..........................................................................................................................................
Rotary Furnaces that commence construction or reconstruction after [INSERT DATE 24 MONTHS
AFTER PUBLICATION OF THE FINAL RULE IN THE FEDERAL REGISTER].
Dioxin and furan
(dioxins and
furans)
nanograms/dscm
expressed as TEQ
corrected to
7 percent O2
20 ppmv
360 ppmv
20 ppmv
20 ppmv
0.50 ng/dscm.
170 ng/dscm.
0.50 ng/dscm.
0.50 ng/dscm.
360 ppmv
70 ppmv
12 ppmv
12 ppmv
170 ng/dscm.
10 ng/dscm.
0.20 ng/dscm.
0.10 ng/dscm.
610 ppmv
610 ppmv
1.0 ng/dscm.
1.0 ng/dscm.
TABLE 3 TO SUBPART X OF PART 60—TOXIC EQUIVALENCY FACTORS
Toxic
equivalency
factor
Dioxin/Furan congener
2,3,7,8-tetrachlorinated dibenzo-p-dioxin ..............................................................................................................................................
1,2,3,7,8-pentachlorinated dibenzo-p-dioxin ..........................................................................................................................................
1,2,3,4,7,8-hexachlorinated dibenzo-p-dioxin ........................................................................................................................................
1,2,3,7,8,9-hexachlorinated dibenzo-p-dioxin ........................................................................................................................................
1,2,3,6,7,8-hexachlorinated dibenzo-p-dioxin ........................................................................................................................................
1,2,3,4,6,7,8-heptachlorinated dibenzo-p-dioxin ....................................................................................................................................
octachlorinated dibenzo-p-dioxin ...........................................................................................................................................................
2,3,7,8-tetrachlorinated dibenzofuran ....................................................................................................................................................
2,3,4,7,8-pentachlorinated dibenzofuran ...............................................................................................................................................
1,2,3,7,8-pentachlorinated dibenzofuran ...............................................................................................................................................
1,2,3,4,7,8-hexachlorinated dibenzofuran .............................................................................................................................................
1,2,3,6,7,8-hexachlorinated dibenzofuran .............................................................................................................................................
1,2,3,7,8,9-hexachlorinated dibenzofuran .............................................................................................................................................
[FR Doc. 2011–11220 Filed 5–18–11; 8:45 am]
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]]>Agencies
[Federal Register Volume 76, Number 97 (Thursday, May 19, 2011)]
[Proposed Rules]
[Pages 29032-29081]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: 2011-11220]
[[Page 29031]]
Vol. 76
Thursday,
No. 97
May 19, 2011
Part II
Environmental Protection Agency
-----------------------------------------------------------------------
40 CFR Part 63
National Emissions Standards for Hazardous Air Pollutants: Secondary
Lead Smelting; Proposed Rule
��Federal Register / Vol. 76 , No. 97 / Thursday, May 19, 2011 /
Proposed Rules��
[[Page 29032]]
-----------------------------------------------------------------------
ENVIRONMENTAL PROTECTION AGENCY
40 CFR Part 63
[EPA-HQ-OAR-2011-0344; FRL-9303-4]
RIN 2060-AQ68
National Emissions Standards for Hazardous Air Pollutants:
Secondary Lead Smelting
AGENCY: Environmental Protection Agency (EPA).
ACTION: Proposed rule.
-----------------------------------------------------------------------
SUMMARY: EPA is proposing amendments to the national emissions
standards for hazardous air pollutants for Secondary Lead Smelting to
address the results of the residual risk and technology review that EPA
is required to conduct by the Clean Air Act. These proposed amendments
include revisions to the stack emissions limits for lead; revisions to
the fugitive dust emissions control requirements; the addition of total
hydrocarbons emissions limits for reverberatory, electric, and rotary
furnaces; the addition of emissions limits and work practice
requirements for dioxins and furans; and the modification and addition
of testing and monitoring and related notification, recordkeeping, and
reporting requirements. We are also proposing to revise provisions
addressing periods of startup, shutdown, and malfunction to ensure that
the rules are consistent with a recent court decision.
DATES: Comments must be received on or before July 5, 2011. Under the
Paperwork Reduction Act, comments on the information collection
provisions are best assured of having full effect if the Office of
Management and Budget (OMB) receives a copy of your comments on or
before June 20, 2011.
Public Hearing. If anyone contacts EPA requesting to speak at a
public hearing by May 31, 2011, a public hearing will be held on June
3, 2011.
ADDRESSES: Submit your comments, identified by Docket ID Number EPA-HQ-
OAR-2011-0344, by one of the following methods:
https://www.regulations.gov: Follow the on-line
instructions for submitting comments.
E-mail: a-and-r-docket@epa.gov, Attention Docket ID Number
EPA-HQ-OAR-2011-0344.
Fax: (202) 566-9744, Attention Docket ID Number EPA-HQ-
OAR-2011-0344.
Mail: U.S. Postal Service, send comments to: EPA Docket
Center, EPA West (Air Docket), Attention Docket ID Number EPA-HQ-OAR-
2011-0344, U.S. Environmental Protection Agency, Mailcode: 2822T, 1200
Pennsylvania Ave., NW., Washington, DC 20460. Please include a total of
two copies. In addition, please mail a copy of your comments on the
information collection provisions to the Office of Information and
Regulatory Affairs, Office of Management and Budget (OMB), Attn: Desk
Officer for EPA, 725 17th Street, NW., Washington, DC 20503.
Hand Delivery: U.S. Environmental Protection Agency, EPA
West (Air Docket), Room 3334, 1301 Constitution Ave., NW., Washington,
DC 20004, Attention Docket ID Number EPA-HQ-OAR-2011-0344. Such
deliveries are only accepted during the Docket's normal hours of
operation, and special arrangements should be made for deliveries of
boxed information.
Instructions. Direct your comments to Docket ID Number EPA-HQ-OAR-
2011-0344. EPA's policy is that all comments received will be included
in the public docket without change and may be made available on-line
at https://www.regulations.gov, including any personal information
provided, unless the comment includes information claimed to be
confidential business information (CBI) or other information whose
disclosure is restricted by statute. Do not submit information that you
consider to be CBI or otherwise protected through https://www.regulations.gov or e-mail. The https://www.regulations.gov Web site
is an ``anonymous access'' system, which means EPA will not know your
identity or contact information unless you provide it in the body of
your comment. If you send an e-mail comment directly to EPA without
going through https://www.regulations.gov, your e-mail address will be
automatically captured and included as part of the comment that is
placed in the public docket and made available on the Internet. If you
submit an electronic comment, EPA recommends that you include your name
and other contact information in the body of your comment and with any
disk or CD-ROM you submit. If EPA cannot read your comment due to
technical difficulties and cannot contact you for clarification, EPA
may not be able to consider your comment. Electronic files should avoid
the use of special characters, any form of encryption, and be free of
any defects or viruses. For additional information about EPA's public
docket, visit the EPA Docket Center homepage at https://www.epa.gov/epahome/dockets.htm.
Docket. EPA has established a docket for this rulemaking under
Docket ID Number EPA-HQ-OAR-2011-0344. All documents in the docket are
listed in the https://www.regulations.gov index. Although listed in the
index, some information is not publicly available, e.g., CBI or other
information whose disclosure is restricted by statute. Certain other
material, such as copyrighted material, is not placed on the Internet
and will be publicly available only in hard copy. Publicly available
docket materials are available either electronically in https://www.regulations.gov or in hard copy at the EPA Docket Center, EPA West,
Room 3334, 1301 Constitution Ave., NW., Washington, DC. The Public
Reading Room is open from 8:30 a.m. to 4:30 p.m., Monday through
Friday, excluding legal holidays. The telephone number for the Public
Reading Room is (202) 566-1744, and the telephone number for the EPA
Docket Center is (202) 566-1742.
Public Hearing. If a public hearing is held, it will begin at 10
a.m. on June 3, 2011 and will be held at EPA's campus in Research
Triangle Park, North Carolina, or at an alternate facility nearby.
Persons interested in presenting oral testimony or inquiring as to
whether a public hearing is to be held should contact Ms. Virginia
Hunt, Office of Air Quality Planning and Standards, Sector Policies and
Programs Division, (D243-02), U.S. Environmental Protection Agency,
Research Triangle Park, North Carolina 27711; telephone number: (919)
541-0832.
FOR FURTHER INFORMATION CONTACT: For questions about this proposed
action, contact Mr. Chuck French, Sector Policies and Programs Division
(D243-02), Office of Air Quality Planning and Standards, U.S.
Environmental Protection Agency, Research Triangle Park, North Carolina
27711, telephone (919) 541-7912; fax number: (919) 541-5450; and e-mail
address: french.chuck@epa.gov. For specific information regarding the
risk modeling methodology, contact Ms. Elaine Manning, Health and
Environmental Impacts Division (C539-02), Office of Air Quality
Planning and Standards, U.S. Environmental Protection Agency, Research
Triangle Park, North Carolina 27711; telephone number: (919) 541-5499;
fax number: (919) 541-0840; and e-mail address: manning.elaine@epa.gov.
For information about the applicability of the NESHAP to a particular
entity, contact the appropriate person listed in Table 1 of this
preamble.
[[Page 29033]]
Table 1--List of EPA Contacts for the NESHAP Addressed in This Proposed
Action
------------------------------------------------------------------------
NESHAP for: OECA Contact \1\ OAQPS Contact \2\
------------------------------------------------------------------------
Secondary Lead Smelting......... Maria Malave, Chuck French,
(202) 564-7027 (919) 541-7912,
malave.maria@epa.g french.chuck@epa.gov. ov
------------------------------------------------------------------------
\1\ EPA Office of Enforcement and Compliance Assurance.
\2\ EPA Office of Air Quality Planning and Standards.
SUPPLEMENTARY INFORMATION:
Preamble Acronyms and Abbreviations
Several acronyms and terms used to describe industrial processes,
data inventories, and risk modeling are included in this preamble.
While this may not be an exhaustive list, to ease the reading of this
preamble and for reference purposes, the following terms and acronyms
are defined here:
ADAF age-dependent adjustment factors
AEGL acute exposure guideline levels
AERMOD air dispersion model used by the HEM-3 model
ANPRM advance notice of proposed rulemaking
ATSDR Agency for Toxic Substances and Disease Registry
BACT best available control technology
BLDS bag leak detection system
CAA Clean Air Act
CBI Confidential Business Information
CEMS continuous emissions monitoring system
CFR Code of Federal Regulations
CTE central tendency exposure
D/F dioxins and furans
EJ environmental justice
EPA Environmental Protection Agency
ERPG Emergency Response Planning Guidelines
ERT Electronic Reporting Tool
HAP hazardous air pollutants
HEM-3 Human Exposure Model, Version 3
HEPA high efficiency particulate air
HHRAP Human Health Risk Assessment Protocols
HI Hazard Index
HON hazardous organic national emissions standards for hazardous air
pollutants
HQ Hazard Quotient
ICR information collection request
IRIS Integrated Risk Information System
Km kilometer
LAER lowest achievable emissions rate
lb/yr pounds per year
MACT maximum achievable control technology
MACT Code Code within the NEI used to identify processes included in
a source category
MDL method detection level
mg/acm milligrams per actual cubic meter
mg/dscm milligrams per dry standard cubic meter
mg/m\3\ milligrams per cubic meter
MIR maximum individual risk
MRL minimum risk level
NAAQS National Ambient Air Quality Standard
NAC/AEGL Committee National Advisory Committee for Acute Exposure
Guideline Levels for Hazardous Substances
NAICS North American Industry Classification System
NAS National Academy of Sciences
NATA National Air Toxics Assessment
NEI National Emissions Inventory
NESHAP National Emissions Standards for Hazardous Air Pollutants
NOAEL no observed adverse effects level
NRC National Research Council
NTTAA National Technology Transfer and Advancement Act
O&M operation and maintenance
OAQPS Office of Air Quality Planning and Standards
ODW Office of Drinking Water
OECA Office of Enforcement and Compliance Assurance
OHEA Office of Health and Environmental Assessment
OMB Office of Management and Budget
PB-HAP hazardous air pollutants known to be persistent and bio-
accumulative in the environment
PM particulate matter
POM polycyclic organic matter
ppmv parts per million volume
RACT reasonably available control technology
RBLC RACT/BACT/LAERClearinghouse
REL reference exposure level
RFA Regulatory Flexibility Act
RfC reference concentration
RfD reference dose
RIA Regulatory Impact Analysis
RME reasonable maximum exposure
RTR residual risk and technology review
SAB Science Advisory Board
SBA Small Business Administration
SCC Source Classification Codes
SF3 2000 Census of Population and Housing Summary
SIP State Implementation Plan
SOP standard operating procedures
SSM startup, shutdown, and malfunction
TEF toxic equivalency factors
TEQ toxic equivalency quotient
THC total hydrocarbons
TOSHI target organ-specific hazard index
TPY tons per year
TRIM Total Risk Integrated Modeling System
TTN Technology Transfer Network
UF uncertainty factor
[mu]/m\3\ microgram per cubic meter
UL upper limit
UMRA Unfunded Mandates Reform Act
UPL upper predictive limit
URE unit risk estimate
VOC volatile organic compounds
VOHAP volatile organic hazardous air pollutants
WESP wet electrostatic precipitator
WHO World Health Organization
WWW worldwide Web
Organization of this Document. The information in this preamble is
organized as follows:
I. General Information
A. What is the statutory authority for this action?
B. Does this action apply to me?
C. Where can I get a copy of this document and other related
information?
D. What should I consider as I prepare my comments for EPA?
II. Background
A. Overview of the Source Category and MACT Standards
B. What data collection activities were conducted to support
this action?
III. Analyses Performed
A. Addressing Unregulated Emissions Sources
B. How did we estimate risks posed by the source category?
C. How did we consider the risk results in making decisions for
this proposal?
D. How did we perform the technology review?
E. What other issues are we addressing in this proposal?
IV. Analyses Results and Proposed Decisions
A. What are the results of our analyses and proposed decisions
regarding unregulated emissions sources?
B. What are the results of the risk assessments and analyses?
C. What are our proposed decisions based on risk acceptability
and ample margin of safety?
D. What are the results and proposed decisions based on our
technology review?
E. What other actions are we proposing?
F. What is the relationship of the Secondary Lead Smelting
standards proposed in today's action and implementation of the lead
NAAQS?
G. Compliance Dates
V. Summary of Cost, Environmental, and Economic Impacts
A. What are the affected sources?
B. What are the air quality impacts?
C. What are the cost impacts?
D. What are the economic impacts?
E. What are the benefits?
VI. Request for Comments
VII. Submitting Data Corrections
VIII. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory Planning and Review and
Executive Order 13563: Improving Regulation and Regulatory Review
B. Paperwork Reduction Act
C. Regulatory Flexibility Act
D. Unfunded Mandates Reform Act
E. Executive Order 13132: Federalism
[[Page 29034]]
F. Executive Order 13175: Consultation and Coordination With
Indian Tribal Governments
G. Executive Order 13045: Protection of Children From
Environmental Health Risks and Safety Risks
H. Executive Order 13211: Actions Concerning Regulations That
Significantly Affect Energy Supply, Distribution, or Use
I. National Technology Transfer and Advancement Act
J. Executive Order 12898: Federal Actions To Address
Environmental Justice in Minority Populations and Low-Income
Populations
I. General Information
A. What is the statutory authority for this action?
Section 112 of the CAA establishes a two-stage regulatory process
to address emissions of hazardous air pollutants (HAP) from stationary
sources. In the first stage, after EPA has identified categories of
sources emitting one or more of the HAP listed in CAA section 112(b),
CAA section 112(d) calls for us to promulgate NESHAP for those sources.
``Major sources'' are those that emit or have the potential to emit 10
tons per year (tpy) or more of a single HAP or 25 tpy or more of any
combination of HAP. For major sources, these technology-based standards
must reflect the maximum degree of emissions reductions of HAP
achievable (after considering cost, energy requirements, and non-air
quality health and environmental impacts) and are commonly referred to
as maximum achievable control technology (MACT) standards.
MACT standards must require the maximum degree of emissions
reduction through the application of measures, processes, methods,
systems, or techniques, including, but not limited to, measures that
(A) reduce the volume of or eliminate pollutants through process
changes, substitution of materials or other modifications; (B) enclose
systems or processes to eliminate emissions; (C) capture or treat
pollutants when released from a process, stack, storage, or fugitive
emissions point; (D) are design, equipment, work practice, or
operational standards (including requirements for operator training or
certification); or (E) are a combination of the above (CAA section
112(d)(2)(A)-(E)). The MACT standards may take the form of design,
equipment, work practice, or operational standards where EPA first
determines either that, (A) a pollutant cannot be emitted through a
conveyance designed and constructed to emit or capture the pollutants,
or that any requirement for, or use of, such a conveyance would be
inconsistent with law; or (B) the application of measurement
methodology to a particular class of sources is not practicable due to
technological and economic limitations (CAA sections 112(h)(1)-(2)).
The MACT ``floor'' is the minimum control level allowed for MACT
standards promulgated under CAA section 112(d)(3) and may not be based
on cost considerations. For new sources, the MACT floor cannot be less
stringent than the emissions control that is achieved in practice by
the best-controlled similar source. The MACT floors for existing
sources can be less stringent than floors for new sources, but they
cannot be less stringent than the average emissions limitation achieved
by the best-performing 12 percent of existing sources in the category
or subcategory (or the best-performing five sources for categories or
subcategories with fewer than 30 sources). In developing MACT
standards, we must also consider control options that are more
stringent than the floor. We may establish standards more stringent
than the floor based on considerations of the cost of achieving the
emissions reductions, any non-air quality health and environmental
impacts, and energy requirements.
EPA is then required to review these technology-based standards and
revise them ``as necessary (taking into account developments in
practices, processes, and control technologies)'' no less frequently
than every 8 years, under CAA section 112(d)(6). In conducting this
review, EPA is not obliged to completely recalculate the prior MACT
determination, and, in particular, is not obligated to recalculate the
MACT floors. NRDC v. EPA, 529 F.3d 1077, 1084 (DC Cir., 2008).
The second stage in standard-setting focuses on reducing any
remaining ``residual'' risk according to CAA section 112(f). This
provision requires, first, that EPA prepare a Report to Congress
discussing (among other things) methods of calculating the risks posed
(or potentially posed) by sources after implementation of the MACT
standards, the public health significance of those risks, and EPA's
recommendations as to legislation regarding such remaining risk. EPA
prepared and submitted this report (Residual Risk Report to Congress,
EPA-453/R-99-001) in March 1999. Congress did not act in response to
the report, thereby triggering EPA's obligation under CAA section
112(f)(2) to analyze and address residual risk.
Section 112(f)(2) of the CAA requires us to determine, for source
categories subject to certain MACT standards, whether those emissions
standards provide an ample margin of safety to protect public health.
If the MACT standards that apply to a source category emitting a HAP
that is ``classified as a known, probable, or possible human carcinogen
do not reduce lifetime excess cancer risks to the individual most
exposed to emissions from a source in the category or subcategory to
less than one-in-one million,'' EPA must promulgate residual risk
standards for the source category (or subcategory) as necessary to
provide an ample margin of safety to protect public health (CAA section
112(f)(2)(A)). This requirement is procedural. It mandates that EPA
establish CAA section 112(f) residual risk standards if certain risk
thresholds are not satisfied, but does not determine the level of those
standards. NRDC v. EPA, 529 F. 3d at 1083. The second sentence of CAA
section 112(f)(2) sets out the substantive requirements for residual
risk standards: protection of public health with an ample margin of
safety based on EPA's interpretation of this standard in effect at the
time of the Clean Air Act amendments. Id. This refers to the Benzene
NESHAP, described in the next paragraph. EPA may adopt residual risk
standards equal to existing MACT standards if EPA determines that the
existing standards are sufficiently protective, even if (for example)
excess cancer risks to a most exposed individual are not reduced to
less than one-in-one million. Id. at 1083, (``If EPA determines that
the existing technology-based standards provide an `ample margin of
safety,' then the Agency is free to readopt those standards during the
residual risk rulemaking''). Section 112(f)(2) of the CAA further
authorizes EPA to adopt more stringent standards, if necessary ``to
prevent, taking into consideration costs, energy, safety, and other
relevant factors, an adverse environmental effect.'' \1\
---------------------------------------------------------------------------
\1\ ``Adverse environmental effect'' is defined in CAA section
112(a)(7) as any significant and widespread adverse effect, which
may be reasonably anticipated to wildlife, aquatic life, or natural
resources, including adverse impacts on populations of endangered or
threatened species or significant degradation of environmental
qualities over broad areas.
---------------------------------------------------------------------------
As just noted, CAA section 112(f)(2) expressly preserves our use of
the two-step process for developing standards to address any residual
risk and our interpretation of ``ample margin of safety'' developed in
the National Emissions Standards for Hazardous Air Pollutants: Benzene
Emissions From Maleic Anhydride Plants, Ethylbenzene/Styrene Plants,
Benzene Storage Vessels,
[[Page 29035]]
Benzene Equipment Leaks, and Coke By-Product Recovery Plants (Benzene
NESHAP) (54 FR 38044, September 14, 1989). The first step in this
process is the determination of acceptable risk. The second step
provides for an ample margin of safety to protect public health, which
is the level at which the standards are set (unless a more stringent
standard is necessary to prevent, taking into consideration costs,
energy, safety, and other relevant factors, an adverse environmental
effect).
The terms ``individual most exposed,'' ``acceptable level,'' and
``ample margin of safety'' are not specifically defined in the CAA.
However, CAA section 112(f)(2)(B) preserves EPA's interpretation set
out in the Benzene NESHAP, and the court in NRDC v. EPA concluded that
EPA's interpretation of CAA section 112(f)(2) is a reasonable one. See
NRDC v. EPA, 529 F.3d at 1083 (DC Cir. 2008), which says ``[S]ubsection
112(f)(2)(B) expressly incorporates EPA's interpretation of the Clean
Air Act from the Benzene standard, complete with a citation to the
Federal Register.'' See also, A Legislative History of the Clean Air
Act Amendments of 1990, volume 1, p. 877 (Senate debate on Conference
Report). We also notified Congress in the Residual Risk Report to
Congress that we intended to use the Benzene NESHAP approach in making
CAA section 112(f) residual risk determinations (EPA-453/R-99-001, p.
ES-11).
In the Benzene NESHAP, we stated as an overall objective:
* * * in protecting public health with an ample margin of
safety, we strive to provide maximum feasible protection against
risks to health from hazardous air pollutants by (1) protecting the
greatest number of persons possible to an individual lifetime risk
level no higher than approximately 1-in-1 million; and (2) limiting
to no higher than approximately 1-in-10 thousand [i.e., 100-in-1
million] the estimated risk that a person living near a facility
would have if he or she were exposed to the maximum pollutant
concentrations for 70 years.
The Agency also stated that, ``The EPA also considers incidence
(the number of persons estimated to suffer cancer or other serious
health effects as a result of exposure to a pollutant) to be an
important measure of the health risk to the exposed population.
Incidence measures the extent of health risks to the exposed population
as a whole, by providing an estimate of the occurrence of cancer or
other serious health effects in the exposed population.'' The Agency
went on to conclude that ``estimated incidence would be weighed along
with other health risk information in judging acceptability.'' As
explained more fully in our Residual Risk Report to Congress, EPA does
not define ``rigid line[s] of acceptability,'' but rather considers
broad objectives to be weighed with a series of other health measures
and factors (EPA-453/R-99-001, p. ES-11). The determination of what
represents an ``acceptable'' risk is based on a judgment of ``what
risks are acceptable in the world in which we live'' (Residual Risk
Report to Congress, p. 178, quoting the DC Circuit's en banc Vinyl
Chloride decision at 824 F.2d 1165) recognizing that our world is not
risk-free.
In the Benzene NESHAP, we stated that ``EPA will generally presume
that if the risk to [the maximum exposed] individual is no higher than
approximately 1-in-10 thousand, that risk level is considered
acceptable.'' 54 FR 38045. We discussed the maximum individual lifetime
cancer risk as being ``the estimated risk that a person living near a
plant would have if he or she were exposed to the maximum pollutant
concentrations for 70 years.'' Id. We explained that this measure of
risk ``is an estimate of the upper bound of risk based on conservative
assumptions, such as continuous exposure for 24 hours per day for 70
years.'' Id. We acknowledge that maximum individual lifetime cancer
risk ``does not necessarily reflect the true risk, but displays a
conservative risk level which is an upper-bound that is unlikely to be
exceeded.'' Id.
Understanding that there are both benefits and limitations to using
maximum individual lifetime cancer risk as a metric for determining
acceptability, we acknowledged in the 1989 Benzene NESHAP that
``consideration of maximum individual risk * * * must take into account
the strengths and weaknesses of this measure of risk.'' Id.
Consequently, the presumptive risk level of 100-in-1 million (1-in-10
thousand) provides a benchmark for judging the acceptability of maximum
individual lifetime cancer risk, but does not constitute a rigid line
for making that determination.
The Agency also explained in the 1989 Benzene NESHAP the following:
``In establishing a presumption for MIR [maximum individual cancer
risk], rather than a rigid line for acceptability, the Agency intends
to weigh it with a series of other health measures and factors. These
include the overall incidence of cancer or other serious health effects
within the exposed population, the numbers of persons exposed within
each individual lifetime risk range and associated incidence within,
typically, a 50-kilometer (km) exposure radius around facilities, the
science policy assumptions and estimation uncertainties associated with
the risk measures, weight of the scientific evidence for human health
effects, other quantified or unquantified health effects, effects due
to co-location of facilities, and co-emissions of pollutants.'' Id.
In some cases, these health measures and factors taken together may
provide a more realistic description of the magnitude of risk in the
exposed population than that provided by maximum individual lifetime
cancer risk alone. As explained in the Benzene NESHAP, ``[e]ven though
the risks judged `acceptable' by EPA in the first step of the Vinyl
Chloride inquiry are already low, the second step of the inquiry,
determining an `ample margin of safety,' again includes consideration
of all of the health factors, and whether to reduce the risks even
further.'' In the ample margin of safety decision process, the Agency
again considers all of the health risks and other health information
considered in the first step. Beyond that information, additional
factors relating to the appropriate level of control will also be
considered, including costs and economic impacts of controls,
technological feasibility, uncertainties, and any other relevant
factors. Considering all of these factors, the Agency will establish
the standard at a level that provides an ample margin of safety to
protect the public health, as required by CAA section 112(f) (54 FR
38046).
B. Does this action apply to me?
The regulated industrial source category that is the subject of
this proposal is listed in Table 2 of this preamble. Table 2 of this
preamble is not intended to be exhaustive, but rather provides a guide
for readers regarding the entities likely to be affected by this
proposed action. These standards, once finalized, will be directly
applicable to affected sources. Federal, State, local, and Tribal
government entities are not affected by this proposed action. As
defined in the source category listing report published by EPA in 1992,
the Secondary Lead Smelting source category is defined as any facility
at which lead-bearing scrap materials (including, but not limited to
lead acid batteries) are recycled by smelting into elemental lead or
lead alloys.\2\ For clarification purposes, all references to lead
emissions in this preamble mean ``lead compounds'' (which is a listed
HAP) and all references to lead
[[Page 29036]]
production mean elemental lead (which is not a listed HAP as provided
under CAA section 112(b)(7)).
---------------------------------------------------------------------------
\2\ USEPA. Documentation for Developing the Initial Source
Category List--Final Report, USEPA/OAQPS, EPA-450/3-91-030, July,
1992.
Table 2--NESHAP and Industrial Source Categories Affected by This Proposed Action
----------------------------------------------------------------------------------------------------------------
Source category NESHAP NAICS code \1\ MACT code \2\
----------------------------------------------------------------------------------------------------------------
Secondary Lead Smelting..................... Secondary Lead Smelting....... 331492 0205
----------------------------------------------------------------------------------------------------------------
\1\ North American Industry Classification System.
\2\ Maximum Achievable Control Technology.
C. Where can I get a copy of this document and other related
information?
In addition to being available in the docket, an electronic copy of
this proposal will also be available on the World Wide Web (WWW)
through the EPA's Technology Transfer Network (TTN). Following
signature by the EPA Administrator, a copy of this proposed action will
be posted on the TTN's policy and guidance page for newly proposed or
promulgated rules at the following address: https://www.epa.gov/ttn/atw/rrisk/rtrpg.html. The TTN provides information and technology exchange
in various areas of air pollution control.
Additional information is available on the residual risk and
technology review (RTR) Web page at: https://www.epa.gov/ttn/atw/rrisk/rtrpg.html. This information includes source category descriptions and
detailed emissions estimates and other data that were used as inputs to
the risk assessments.
D. What should I consider as I prepare my comments for EPA?
Submitting CBI. Do not submit information containing CBI to EPA
through https://www.regulations.gov or e-mail. Clearly mark the part or
all of the information that you claim to be CBI. For CBI information on
a disk or CD-ROM that you mail to EPA, mark the outside of the disk or
CD-ROMas CBI and then identify electronically within the disk or CD-
ROMthe specific information that is claimed as CBI. In addition to one
complete version of the comment that includes information claimed as
CBI, a copy of the comment that does not contain the information
claimed as CBI must be submitted for inclusion in the public docket. If
you submit a CD-ROMor disk that does not contain CBI, mark the outside
of the disk or CD-ROMclearly that it does not contain CBI. Information
not marked as CBI will be included in the public docket and EPA's
electronic public docket without prior notice. Information marked as
CBI will not be disclosed except in accordance with procedures set
forth in 40 CFR part 2. Send or deliver information identified as CBI
only to the following address: Roberto Morales, OAQPS Document Control
Officer (C404-02), Office of Air Quality Planning and Standards, U.S.
Environmental Protection Agency, Research Triangle Park, North Carolina
27711, Attention Docket ID Number EPA-HQ-OAR-2011-0344.
II. Background
A. Overview of the Source Category and MACT Standards
The NESHAP (or MACT rule) for the Secondary Lead Smelting source
category was promulgated on June 13, 1997 (62 FR 32216) and codified at
40 CFR part 63, subpart X. As promulgated in 1997, the NESHAP applies
to affected sources of HAP emissions at secondary lead smelters. The
1997 NESHAP (40 CFR 63.542) defines ``secondary lead smelters'' as
``any facility at which lead-bearing scrap material, primarily, but not
limited to, lead-acid batteries, is recycled into elemental lead or
lead alloys by smelting.'' The MACT rule for the Secondary Lead
Smelting source category does not apply to primary lead smelters, lead
remelters, or lead refiners.
Today, there are 14 secondary lead smelting facilities that are
subject to the MACT rule. No new secondary lead smelters have been
built in the last 20 years, and we anticipate no new secondary lead
smelting facilities in the foreseeable future, although there is one
facility currently in the process of expanding operations.
Lead is used to make various construction, medical, industrial and
consumer products such as batteries, glass, x-ray protection gear and
various fillers. The secondary lead smelting process consists of: (1)
Pre-processing of lead bearing materials, (2) melting lead metal and
reducing lead compounds to lead metal in the smelting furnace, and (3)
refining and alloying the lead to customer specifications.
HAP are emitted from secondary lead smelting as process emissions,
process fugitive emissions, and fugitive dust emissions. Process
emissions are the exhaust gases from feed dryers and from blast,
reverberatory, rotary, and electric furnaces. The HAP in process
emissions are primarily composed of metals (mostly lead compounds, but
also some arsenic, cadmium, and other metals) and also may include
organic compounds that result from incomplete combustion of coke that
is charged to the smelting furnaces as a fuel or fluxing agent or from
fuel natural gas and/or small amounts of plastics or other materials
that get fed into the furnaces along with the lead bearing materials.
Process fugitive emissions occur at various points during the smelting
process (such as during charging and tapping of furnaces) and are
composed primarily of metal HAP. Fugitive dust emissions result from
the entrainment of HAP in ambient air due to material handling, vehicle
traffic, wind erosion from storage piles, and other various activities.
Fugitive dust emissions are composed of metal HAP only.
The MACT rule applies to process emissions from blast,
reverberatory, rotary, and electric smelting furnaces, agglomerating
furnaces, and dryers; process fugitive emissions from smelting furnace
charging points, smelting furnace lead and slag taps, refining kettles,
agglomerating furnace product taps, and dryer transition pieces; and
fugitive dust emissions sources such as roadways, battery breaking
areas, furnace charging and tapping areas, refining and casting areas,
and material storage areas. For process sources, the NESHAP specifies
numerical emissions limits for lead compounds (as a surrogate for metal
HAP) for the following types of smelting furnaces: (1) Collocated
reverberatory and blast furnaces (reverberatory/blast), (2) blast
furnaces, and (3) reverberatory furnaces not collocated with blast
furnaces, rotary furnaces, and electric furnaces. Lead compound
emissions from all smelting furnace configurations are limited to an
outlet concentration of 2.0 milligrams per dry standard cubic meter
(mg/dscm) (0.00087 grains per dry standard cubic foot (gr/dscf)), 40
CFR 63.543(a). Total hydrocarbon (THC) emissions (as a surrogate for
organic HAP) from existing and new collocated reverberatory/blast
furnace
[[Page 29037]]
configurations are limited to an outlet concentration of 20 parts per
million volume (ppmv) (expressed as propane) corrected to 4 percent
carbon dioxide (CO2) to account for dilution. THC emissions
are limited to 360 ppmv (as propane) at 4 percent CO2 from
existing blast furnaces and 70 ppmv (as propane) at 4 percent
CO2 from new blast furnaces (40 CFR 63.543(c)). The NESHAP
does not specify emissions limits for THC emissions from reverberatory
furnaces not collocated with blast furnaces, rotary furnaces, and
electric furnaces.
The 1997 NESHAP requires that process fugitive emissions sources be
equipped with an enclosure hood meeting minimum face velocity
requirements or be located in a total enclosure subject to general
ventilation that maintains the building at negative pressure (40 CFR
63.543(b)). Ventilation air from the enclosure hoods and total
enclosures is required to be conveyed to a control device. Lead
emissions from these control devices are limited to 2.0 mg/dscm
(0.00087 gr/dscf) (40 CFR 63.544(c)). Lead emissions for all dryer
emissions vents and agglomerating furnace vents are limited to 2.0 mg/
dscm (0.00087 gr/dscf) (40 CFR 63.544(d)). The 1997 NESHAP also
requires the use of bag leak detection systems (BLDS) for continuous
monitoring of baghouses in cases where a high efficiency particulate
air (HEPA) filter was not used in series with a baghouse (40 CFR
63.548(c)(9)).
For fugitive dust sources, as defined in 40 CFR 63.545, the 1997
NESHAP requires that the smelting process and all control devices be
operated at all times according to a standard operating procedures
(SOP) manual developed by the facility. The SOP manual is required to
describe, in detail, the measures used to control fugitive dust
emissions from plant roadways, battery breaking areas, furnace areas,
refining and casting areas, and material storage and handling areas.
B. What data collection activities were conducted to support this
action?
In June 2010, EPA issued an information collection request (ICR),
pursuant to CAA section 114, to six companies that own and operate the
14 secondary lead smelting facilities. The ICR requested available
information regarding process equipment, control devices, point and
fugitive emissions, practices used to control fugitive emissions, and
other aspects of facility operations. The six companies completed the
surveys for their facilities and submitted the responses to us in the
fall of 2010. In addition to the ICR survey, each facility was asked to
submit reports for any emissions tests conducted in 2003 or later. We
received lead emissions test data from all 14 facilities with some
facilities submitting data for multiple years. Additionally, EPA
requested that eight facilities conduct additional emissions tests in
2010 for certain HAP from specific processes that were considered
representative of the industry. Pollutants tested included most HAP
metals, dioxins and furans, and certain organic HAP. The results of
these tests were submitted to EPA in the fall of 2010 and are available
in the docket for this action.
III. Analyses Performed
In this section we describe the analyses performed to support the
proposed decisions for the RTR for this source category.
A. Addressing Unregulated Emissions Sources
In the course of evaluating the Secondary Lead Smelting source
category, we identified certain HAP for which we failed to establish
emission standards in the original MACT. See National Lime v. EPA, 233
F. 3d 625, 634 (DC Cir. 2000) (EPA has ``clear statutory obligation to
set emissions standards for each listed HAP''). Specifically, we
evaluated emissions standards for three HAP (or groups of HAP),
described below, that are not specifically regulated in the existing
1997 MACT standard, or are only regulated for certain emissions points.
As described below, for two of these groups of HAP (i.e., organic HAP
and dioxins and furans) we are proposing emissions limits pursuant to
112(d)(2) and 112(d)(3). For the other HAP (mercury compounds), we are
proposing standards based on work practices pursuant to 112(h). The
results and proposed decisions based on the analyses performed pursuant
to CAA section 112(d)(2), 112(d)(3), and 112(h) are presented in
Section IV.A of this preamble.
1. Organic HAP
EPA did not establish standards for organic HAP emitted from
reverberatory furnaces not collocated with blast furnaces, rotary
furnaces, and electric furnaces in the 1997 NESHAP. EPA is therefore
proposing to set emissions limits for organic HAP emissions from these
furnace configurations in today's action based on emissions data
received in response to the ICR.
2. Mercury
The 1997 NESHAP specified emissions limits for metal HAP (e.g.,
arsenic, cadmium, lead) in terms of a lead emissions limit (i.e., lead
is used as a surrogate for metal HAP). There is no explicit standard
for mercury and we are therefore proposing a standard pursuant to
section 112 (as described further in section IV.A of this preamble).
3. Dioxins and Furans
Lastly, with regard to dioxin and furan emissions, because the 1997
NESHAP did not include emissions limits, we are proposing emissions
standards for dioxins and furans pursuant to CAA section 112(d)(3). We
are also proposing work practices for dioxins and furans.
B. How did we estimate risks posed by the source category?
EPA conducted a risk assessment that provided estimates of the
maximum individual cancer risk (MIR) posed by the HAP emissions from
the 14 sources in the source category, the distribution of cancer risks
within the exposed populations, total cancer incidence, estimates of
the maximum target organ-specific hazard index (TOSHI) for chronic
exposures to HAP with the potential to cause chronic non-cancer health
effects, worst-case screening estimates of hazard quotients (HQ) for
acute exposures to HAP with the potential to cause non-cancer health
effects, and an evaluation of the potential for adverse environmental
effects. In June of 2009, the EPA's Science Advisory Board (SAB)
conducted a formal peer review of our risk assessment methodologies in
its review of the document entitled, ``Risk and Technology Review (RTR)
Assessment Methodologies''.\3\ We received the final SAB report on this
review in May of 2010.\4\ Where appropriate, we have responded to the
key messages from this review in developing the current risk
assessment; we will be continuing our efforts to improve our
assessments by incorporating updates based on the SAB recommendations
as they are developed and become available. The risk assessment
consisted of seven primary steps, as discussed below.
---------------------------------------------------------------------------
\3\ U.S. EPA, 2009. Risk and Technology Review (RTR) Risk
Assessment Methodologies: For Review by the EPA's Science Advisory
Board with Case Studies--MACT I Petroleum Refining Sources and
Portland Cement Manufacturing. EPA-452/R-09-006. https://www.epa.gov/ttn/atw/rrisk/rtrpg.html.
\4\ U.S. EPA, 2010. SAB's Response to EPA's RTR Risk Assessment
Methodologies. https://yosemite.epa.gov/sab/sabproduct.nsf/
4AB3966E263D943A8525771F00668381/$File/EPA-SAB-10-007-unsigned.pdf.
---------------------------------------------------------------------------
The docket for this rulemaking contains the following document,
which provides more information on the risk
[[Page 29038]]
assessment inputs and models: Draft Residual Risk Assessment for the
Secondary Lead Smelting Source Category.
1. Establishing the Nature and Magnitude of Actual Emissions and
Identifying the Emissions Release Characteristics
For each facility in the Secondary Lead Smelting source category,
we compiled an emissions profile (including emissions estimates, stack
parameters, and location data) based on the information provided by the
industry in the ICR, the emissions test data, various calculations, and
the NEI. The site-specific emissions profiles include annual estimates
of process, process fugitive, and fugitive dust emissions for the 2008-
2010 timeframe, as well as emissions release characteristics such as
emissions release height, temperature, velocity, and location
coordinates.
The primary risk assessment is based on estimates of the actual
emissions (though we also analyzed allowable emissions and the
potential risks due to allowable emissions). We received a substantial
amount of emissions test data and other information that enabled us to
derive estimates of stack emissions of certain HAP for all of the
facilities. However, we did not have test data for all pollutants at
all emissions points. Therefore, we estimated emissions of some
pollutants from certain emissions points (for which we had no emissions
data) using test data from similar source types with similar controls.
With regard to fugitive emissions, because they cannot be readily
captured or directly measured, fugitive emissions are a more
challenging emissions type to estimate. In 2010, as part of an
information collection request (ICR), EPA asked the Secondary Lead
industry to provide their best estimate of the emissions from fugitive
sources (e.g., building openings, raw material storage piles, roadways,
parking areas) at their facilities and to provide a description of the
basis for the estimates (e.g., test data, emissions factors, mass
balance calculations, engineering judgment). For our analysis of
fugitive emissions for the source category, we first reviewed and
evaluated the estimates of fugitive lead emissions that were submitted
by each of the facilities in response to the 2010 ICR to determine the
reliability and appropriateness of those estimates as an input to our
risk analyses and other assessments. We concluded that there were
significant gaps and incomplete documentation for a number of
facilities, a large amount of variability in estimates between the
facilities, and various significant uncertainties. For example, five
facilities did not provide any estimates of fugitive emissions, while a
few other facilities provided emissions estimates that were quite
incomplete. Thus, we developed estimates of fugitive emissions for all
facilities in the source category based on a methodology described in
the emissions development technical document (Draft Development of the
RTR Emissions Dataset for the Secondary Lead Smelting Source Category)
for this rulemaking, which is available in the docket. In this
methodology, we began with estimates provided by one facility in the
ICR which were well-documented and covered all the various fugitive
emissions sources expected at these facilities. Using the ICR
responses, other available information on fugitive emissions (including
scientific literature), and various assumptions and calculations, we
scaled these estimates to derive site-specific fugitive emissions
estimates at each of the other 13 facilities. The estimates calculated
using this methodology were used as inputs to the risk assessment
modeling.
The results of the risk assessment modeling (which are described
further in section IV below) indicated that the fugitive dust emissions
were the largest contributor to the risks due to lead emissions. The
impacts of fugitive emissions were generally considerably greater than
the impacts due to stack emissions. Because of these impacts, and
because of the difficulties and uncertainties associated with
estimating fugitive emissions, we decided to do further analyses and
review of the fugitive emissions estimates as a quality assurance check
on the initial fugitive emissions estimates. Therefore, we consulted
further with industry representatives, gathered additional information
from the EPA's Toxics Release Inventory, evaluated the ICR responses
further, and performed various other analyses, which led to the
development of an alternative set of fugitive emissions estimates based
on a slightly different methodology. The total fugitive estimates of
lead for the industry calculated based on the alternative approach are
within 10 percent of our initial estimates. We did not rerun the model
with the alternative estimates because we know that the overall results
would be quite similar and would not change our overall conclusions and
decisions (described later in this notice). Further details on all the
emissions data, calculations, estimates, and uncertainties, are in the
emissions technical document (Draft Development of the RTR Emissions
Dataset for the Secondary Lead Smelting Source Category) which is
available in the docket for this action. We are seeking comments on our
emissions data and estimates, and the fugitive emissions estimation
methodologies and any other potential appropriate methods or data that
could be used to estimate fugitive emissions from these facilities.
2. Establishing the Relationship Between Actual Emissions and MACT-
Allowable Emissions Levels
The emissions data in our data set are estimates of actual
emissions on an annual basis for stacks and fugitives for the 2008-2010
timeframe. With most source categories, we generally find that
``actual'' emissions levels are lower than the emissions levels that a
facility is allowed to emit under the MACT standards. The emissions
levels allowed to be emitted by the MACT standards are referred to as
the ``MACT-allowable'' emissions levels. This represents the highest
emissions level that could be emitted by facilities without violating
the MACT standards.
As we have discussed in prior residual risk and technology review
rules, assessing the risks at the MACT-allowable level is inherently
reasonable since these risks reflect the maximum level at which sources
could emit while still complying with the MACT standards. However, we
also explained that it is reasonable to consider actual emissions,
where such data are available, in both steps of the risk analysis, in
accordance with the Benzene NESHAP (54 FR 38044, September 14, 1989).
It is reasonable to consider actual emissions because sources typically
seek to perform better than required by emissions standards to provide
an operational cushion to accommodate the variability in manufacturing
processes and control device performance. Facilities' actual emissions
may also be significantly lower than MACT-allowable emissions for other
reasons such as State requirements, better performance of control
devices than required by the MACT standards, or reduced production.
For the Secondary Lead Smelting source category, we evaluated
actual and allowable emissions for both stack emissions and fugitive
dust emissions. As described earlier in this section, the actual
emissions data for this source category were compiled based on the ICR
responses, available test data, various calculations, and the NEI. We
estimated actual emissions for all HAP that we identified in the
dataset. The
[[Page 29039]]
analysis of allowable emissions was largely focused on lead compound
emissions, which we considered the most important HAP emitted from this
source category based on our screening level risk assessment and the
HAP for which we had the most data. However, we also considered
allowable emissions for other HAP.
With regard to fugitive emissions, because there are no numerical
emissions limits, and because all facilities are required to implement
identical fugitive emissions control work-practices, we assume that the
allowable fugitive emissions from this source category are equal to the
actual emissions.
To estimate emissions at the MACT-allowable level from stacks
(e.g., process, process fugitive, and building vents), we estimated the
emissions that would occur if facilities were continuously emitting
lead at the maximum allowed by the existing MACT standard (i.e., 2.0
mg/dscm) from all vents. We then compared these estimated allowable
emissions to the estimated emissions using the actual stack test data
for each facility. We realize that these estimates of allowable
emissions are theoretical high-end estimates as facilities must
maintain average emissions levels at some level below the MACT limit to
ensure compliance with the standard at all times because of the day-to-
day variability in emissions. Nevertheless, these high-end estimates of
allowable emissions were adequate for us to estimate the magnitude of
allowable emissions and the differences between the estimates of actual
emissions and the MACT allowable emissions.
Based on this analysis, we conclude that all facilities are
emitting lead at levels lower than allowable; however, the range of
differences between actual and allowable is significant. For two
facilities, the estimated actual emissions were only moderately lower
than allowable (about 2-3 times lower). The majority of other
facilities have estimated actual emissions in the range of 10 to 100
times lower than allowable. Finally, one facility, which has highly
advanced controls, has estimated actual emissions of about 1,500 times
below the MACT allowable emissions level.
We then developed a ratio of MACT-allowable to actual emissions for
each facility in the source category. After developing these ratios, we
applied them on a facility-by-facility basis to the maximum modeled
ambient lead concentrations to estimate the maximum ambient
concentrations that would occur if all stacks were emitting at maximum
allowable levels. The ratios were applied to stack emissions while
leaving fugitive dust emissions at actual levels since, as described
above, actual fugitive dust emissions were assumed to be equal to
allowable fugitive dust emissions. The estimates of MACT-allowable
emissions are described further in the technical document: Draft
Development of the RTR Emissions Dataset for the Secondary Lead
Smelting Source Category. The estimates of risks due to allowable
emissions are summarized in Section IV.B of this preamble and described
further in the draft risk report: Draft Residual Risk Assessment for
the Secondary Lead Smelting Source Category.
3. Conducting Dispersion Modeling, Determining Inhalation Exposures,
and Estimating Individual and Population Inhalation Risks
Both long-term and short-term inhalation exposure concentrations
and health risks from the source category addressed in this proposal
were estimated using the Human Exposure Model (Community and Sector
HEM-3 version 1.1.0). The HEM-3 performs three of the primary risk
assessment activities listed above: (1) Conducting dispersion modeling
to estimate the concentrations of HAP in ambient air, (2) estimating
long-term and short-term inhalation exposures to individuals residing
within 50 km of the modeled sources, and (3) estimating individual and
population-level inhalation risks using the exposure estimates and
quantitative dose-response information.
The dispersion model used by HEM-3 is AERMOD, which is one of EPA's
preferred models for assessing pollutant concentrations from industrial
facilities.\5\ To perform the dispersion modeling and to develop the
preliminary risk estimates, HEM-3 draws on three data libraries. The
first is a library of meteorological data, which is used for dispersion
calculations. This library includes 1 year of hourly surface and upper
air observations for 130 meteorological stations, selected to provide
coverage of the United States and Puerto Rico. A second library, of
United States Census Bureau census block \6\ internal point locations
and populations, provides the basis of human exposure calculations
based on the year 2000 U.S. Census. In addition, for each census block,
the census library includes the elevation and controlling hill height,
which are also used in dispersion calculations. A third library of
pollutant unit risk factors and other health benchmarks is used to
estimate health risks. These risk factors and health benchmarks are the
latest values recommended by EPA for HAP and other toxic air
pollutants. These values are available at https://www.epa.gov/ttn/atw/toxsource/summary.html and are discussed in more detail later in this
section.
---------------------------------------------------------------------------
\5\ U.S. EPA. Revision to the Guideline on Air Quality Models:
Adoption of a Preferred General Purpose (Flat and Complex Terrain)
Dispersion Model and Other Revisions (70 FR 68218, November 9,
2005).
\6\ A census block is the smallest geographic area for which
census statistics are tabulated.
---------------------------------------------------------------------------
In developing the risk assessment for chronic exposures, we used
the estimated annual average ambient air concentrations of each of the
HAP emitted by each source for which we have emissions data in the
source category. The air concentrations at each nearby census block
centroid were used as a surrogate for the chronic inhalation exposure
concentration for all the people who reside in that census block. We
calculated the MIR for the facilities as the cancer risk associated
with a lifetime (70-year period) of exposure to the maximum
concentration at the centroid of inhabited census blocks. Individual
cancer risks were calculated by multiplying the estimated lifetime
exposure to the ambient concentration of each of the HAP (in micrograms
per cubic meter) by its unit risk estimate (URE), which is an upper
bound estimate of an individual's probability of contracting cancer
over a lifetime of exposure to a concentration of 1 microgram of the
pollutant per cubic meter of air. In general, for residual risk
assessments, we use URE values from EPA's Integrated Risk Information
System (IRIS). For carcinogenic pollutants without EPA IRIS values, we
look to other reputable sources of cancer dose-response values, often
using California Environmental Protection Agency (CalEPA) URE values,
where available. In cases where new, scientifically credible dose
response values have been developed in a manner consistent with EPA
guidelines and have undergone a peer review process similar to that
used by EPA, we may use such dose-response values in place of, or in
addition to, other values, if appropriate. For this review, URE values
and their sources (e.g., IRIS, CalEPA) can be found in Table 2.6-1(a)
in the risk assessment document entitled, Draft Residual Risk
Assessment for the Secondary Lead Smelting Source Category, which is
available in the docket for this proposed rulemaking.
Incremental individual lifetime cancer risks associated with
emissions from the 14 facilities in the source category were estimated
as the sum of the risks for each of the carcinogenic
[[Page 29040]]
HAP (including those classified as carcinogenic to humans, likely to be
carcinogenic to humans, and suggestive evidence of carcinogenic
potential \7\) emitted by the modeled source. Cancer incidence and the
distribution of individual cancer risks for the population within 50 km
of the sources were also estimated for the source category as part of
these assessments by summing individual risks. A distance of 50 km is
consistent with both the analysis supporting the 1989 Benzene NESHAP
(54 FR 38044) and the limitations of Gaussian dispersion models,
including AERMOD.
---------------------------------------------------------------------------
\7\ These classifications also coincide with the terms ``known
carcinogen, probable carcinogen, and possible carcinogen,''
respectively, which are the terms advocated in the EPA's previous
Guidelines for Carcinogen Risk Assessment, published in 1986 (51 FR
33992, September 24, 1986). Summing the risks of these individual
compounds to obtain the cumulative cancer risks is an approach that
was recommended by the EPA's Science Advisory Board (SAB) in their
2002 peer review of EPA's NATA entitled, NATA--Evaluating the
National-scale Air Toxics Assessment 1996 Data--an SAB Advisory,
available at: https://yosemite.epa.gov/sab/sabproduct.nsf/
214C6E915BB04E14852570CA007A682C/$File/ecadv02001.pdf.
---------------------------------------------------------------------------
To assess the risk of non-cancer health effects from chronic
exposures, we summed the HQ for each of the HAP that affects a common
target organ system to obtain the HI for that target organ system (or
target organ-specific HI, TOSHI). The HQ is the estimated exposure
divided by the chronic reference value, which is either the EPA RfC,
defined as ``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,'' or, in
cases where an RfC is not available, the Agency for Toxic Substances
and Disease Registry (ATSDR) chronic Minimal Risk Level (MRL) or the
CalEPA Chronic Reference Exposure Level (REL). Notably, the REL is
defined as ``the concentration level at or below which no adverse
health effects are anticipated for a specified exposure duration.''
Worst-case screening estimates of acute exposures and risks were
also evaluated for each of the HAP at the point of highest off-site
exposure for each facility (i.e., not just the census block centroids)
assuming that a person was located at this spot at a time when both the
peak (hourly) emissions rate and worst-case hourly dispersion
conditions occurred. In general, acute HQ values were calculated using
best available, short-term dose-response values. These acute dose-
response values include REL, Acute Exposure Guideline Levels (AEGL),
and Emergency Response Planning Guidelines (ERPG) for 1-hour exposure
durations. Notably, for HAP emitted from this source category, REL
values were the only such dose-response values available. As discussed
below, we used conservative assumptions for emissions rates,
meteorology, and exposure location for our acute analysis.
As described in the CalEPA's Air Toxics Hot Spots Program Risk
Assessment Guidelines, Part I, The Determination of Acute Reference
Exposure Levels for Airborne Toxicants, an acute REL value (https://www.oehha.ca.gov/air/pdf/acuterel.pdf) is defined as ``the
concentration level at or below which no adverse health effects are
anticipated for a specified exposure duration.'' REL values are based
on the most sensitive, relevant, adverse health effect reported in the
medical and toxicological literature. REL values are designed to
protect the most sensitive individuals in the population by the
inclusion of margins of safety. Since margins of safety are
incorporated to address data gaps and uncertainties, exceeding the REL
does not automatically indicate an adverse health impact.
To develop screening estimates of acute exposures, we first
developed estimates of maximum hourly emissions rates by multiplying
the average actual annual hourly emissions rates by a factor to cover
routinely variable emissions. We chose the factor to use based on
process knowledge and engineering judgment and with awareness of a
Texas study of short-term emissions variability, which showed that most
peak emissions events, in a heavily-industrialized 4-co
