Reducing Toxic Pollution from Power Plants EPA’s Proposed Mercury and Air Toxics Standards March...
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Transcript of Reducing Toxic Pollution from Power Plants EPA’s Proposed Mercury and Air Toxics Standards March...
Reducing Toxic Pollution from Power PlantsEPA’s Proposed Mercury and Air Toxics Standards
March 22, 2011
Overview of the Regulatory Action• On March 16, EPA proposed Mercury and Air Toxics Standards, the first national standards to
reduce emissions of toxic air pollutants from new and existing coal- and oil-fired power plants – often the biggest contributors to air pollution
• Standards would reduce emissions of:
• Metals, including mercury (Hg), arsenic, chromium, and nickel
• Acid gases, including hydrogen chloride (HCl) and hydrogen fluoride (HF)
• Particulate matter
• These pollutants are linked to cancer, IQ loss, heart disease, lung disease and premature death
• Standards create uniform emissions-control requirements based on proven, currently in-use technologies and processes
• Compliance time line set by Clean Air Act: up to 4 years (3 years plus an additional year if granted by the permitting authority)
• EPA is also proposing a new source performance standard (NSPS) for particulate, sulfur dioxide (SO2), and nitrogen oxide (NOX) emissions from new sources
2
Toxic Emissions from Power Plants Are a Serious Public Health Concern• Power plants release mercury, arsenic, other metals, acid gases, and particles that all harm
people’s health.
• Uncontrolled releases of mercury from power plants damage children’s developing brains, reducing their IQ and their ability to learn
• Mercury and many of the other toxic pollutants also pollute our nation’s lakes, streams, and fish
• Other metals such as arsenic, chromium, and nickel can cause cancer
• Acid gases cause lung damage and contribute to asthma, bronchitis and other chronic respiratory disease, especially in children and the elderly
• Particles cause premature death and a wide range of lung and heart diseases
• People who eat large amounts of fish from mercury-contaminated freshwater lakes and rivers in the U.S. are at the greatest risk of exposure
• This includes Native American, Laotian, Vietnamese, African-American, Hispanic, and Caucasian subsistence fishers and their families
• The standards would also result in additional reductions of SO2, preventing thousands of deaths
and hundreds of thousands of illnesses each year 3
Sources:NEI Trends Data (2009) and CAMD Data & Maps (2010) (SO2, NOX)NEI Trends Data (2009) (PM10)2005 NATA Inventory Modified for the Utility MACT 2005 Base Year (2010) (Hg)Inventory of U.S. Greenhouse Gas Emissions and Sinks: 1990-2008 (2010) (CO2)“Other” sources include transportation, other mobile sources, and industrial sources
Other Sectors
Other emissions include: Trace metals (nickel, arsenic, selenium and others) HCl, HF Dioxin/furans Trace organics Others (e.g., cyanide) Radionuclides
Emissions have substantial public health, environment, and other welfare implications.
Nitrogen Oxides (NOx), 200915.3 Million Tons
Particulate Matter (PM10), 200814.8 Million Tons
Mercury (Hg), 2005 105 Tons
Other Sectors
Electric Power
13.3 Million Tons 87%
2.0 Million Tons 13%
Electric Power
Other Sectors
14.3 Million Tons 96%
Electric Power
Other Sectors
Electric Power
2.6 Billion Tons 40%
52 Tons 50%
53 Tons 50%
Sulfur Dioxide (SO2), 20099.5 Million Tons
3.8 Million Tons 40%
5.7 Million Tons 60%
Electric Power
Carbon Dioxide (CO2), 20086.5 Billion Tons
3.9 Billion Tons 60%
0.5 Million Tons 4%
Other Sectors
Electric Power
Power Sector:A Major Share of US Air Emissions
4
In the U.S., Power Plants Emit:
5
60% of the SO2
20% of the chromium13% of the NOx
organics, dioxins/furans, and others
50% of the mercury
over 50% of many acid gases
30% ofthe nickel
60% of the arsenic
Sources: NEI Trends Data (2009) and IPM (2010) (SO2, NOX); Proposed toxics rule modeling platform, based on inventory used for 2005 NATA (Hg);Inventory used for 2005 NATA (other toxics)
6
History of Clean Air Act Power Plant Controls for Mercury/Air Toxics• 1990 Clean Air Act Amendments created Acid Rain provisions and revised provisions
to require controls to reduce emissions of toxic air pollutants from industrial sources• EPA was required to do a study within 3 years, and then list power plants for regulation under the
air toxics provisions if the Administrator found that it was appropriate and necessary
• 1998: EPA released Utility Toxics Study Report to Congress
• 2000: EPA listed power plants for regulation under the Clean Air Act air toxics provisions • Once listed, EPA had 2 years to issue an air toxics standard• Mercury cited as pollutant of greatest concern but other toxics include arsenic, chromium,
cadmium, nickel, hydrochloric acid, dioxin/furan
• 2005: Bush Administration EPA reversed 2000 finding, de-listed power plants from regulation under air toxics provisions, and finalized Clean Air Mercury Rule (CAMR) – allowing trading
• 2008: DC Circuit found the de-listing to be illegal and vacated CAMR • EPA must propose utility MACT standards by March 16, 2011, and issue final standards by
November 16, 2011, pursuant to a consent decree• EPA’s proposed rule requires power plant controls for toxics, including mercury, to be issued in
2011 and require compliance by existing sources 3-4 years later• A quarter of a century will have passed since the 1990 Clean Air Act became law
7
Power Plants Are the Largest RemainingSource of Mercury Emissions in the U.S.
• In 1990 three industry categories made approximately two-thirds of total U.S. mercury emissions
– Two of the three are now subject to air toxics standards
– So are many other industries such as cement plants and steel manufacturers
• Today, 20 years after the 1990 CAA Amendments passed, no Federal limit for toxic emissions – including mercury – exists for coal- or oil-fired power plants
Industrial Category
1990 Emissions
tons per year (tpy)
2005 Emissions
(tpy)
%
Reduction
Power Plants
59 53 10%
Municipal Waste Combustors
57 2 96%
Medical Waste Incinerators
51 <1 >98%
Source: EPA’s 2005 NATA Inventory Modified for the Toxics Rule 2005 Base Year (2010)
Affected Facilities: 1,350 Coal and Oil-Fired Units at 525 Power Plants
8
• Approximately 1,200 coal-fired units
• 45% percent of nationwide electricity generation
• Bituminous coal ~ 50% of coal generation
• Subbituminous ~45% of coal generation
• Lignite ~ 5% of coal generation
• Includes units that burn coal, coal refuse, or a synthetic gas derived from coal or solid oil (e.g. petroleum coke) either exclusively, in any combination together, or in any combination with other supplemental fuels (e.g., tire-derived fuels)
• Approximately 150 oil-fired units
• 1% of nationwide electricity generation
• Natural gas power plants are not affected by this rule
• EPA expects most facilities would install technologies to comply with this rule
9
Location of Coal- and Oil-Fired Power Plants
Source: National Electric Energy Data System (NEEDS 4.10) (EPA, December 2010)
What the Toxics Rule Proposes
• Coal- and oil-fired power plants are covered by this rule• All hazardous air pollutants must have standards• EPA must set emission standards for existing sources in the category that
are at least as stringent as the emission reductions achieved by the average of the top 12% best controlled sources for source categories with 30 or more sources
• Requirements for Coal-Fired Units– Mercury: numeric emission limit would prevent 91% of mercury in coal from
being released to the air– Acid Gases: HCl numeric emission limit as a surrogate, with an alternate
surrogate of SO2
– Non-mercury metallic pollutants (e.g., arsenic, chromium): numeric emission limit for total PM as a surrogate, with an alternate surrogate of total metal air toxics
– Organic air toxics (including dioxin/furans): work practice standards, instead of numeric emission limits, due to low-detected emission levels in the ICR data. Would ensure optimal combustion preventing dioxin/furan emissions
10
What the Toxics Rule Proposes (cont.)• Requirements for Oil-Fired Units
– Acid Gases: HCl and HF numerical emission limits– Metal Air Toxics: numerical emission limits for total metal air toxics (including
mercury) with individual metal air toxic numerical limits as an alternate– Organic air toxics (including dioxin/furans): work practice standards, instead
of numeric emission limits, due to low-detected emission levels in the ICR data. Would ensure optimal combustion preventing dioxin/furan emissions
• Emissions averaging within a contiguous facility is allowed• Monitoring Requirements
– Hg CEMS or sorbent traps for mercury– HCl CEMS or SO2 CEMS for acid gases– PM CEMS for metals– Emissions testing, parameter monitoring, and fuel analyses allowed for metals
and acid gases– Thirty day averaging period for monitoring accommodates process variability
and, coupled with CEMS, facilitates compliance– Records of work practice standards (annual tune ups) are proposed for
organic HAP emissions 11
Emissions from Covered Sources
Note: Historic HCl emissions based on single emission factor; projected emissions based on fuel-specific Cl assumptions and removal efficiencies.
► The base case includes the Transport Rule as proposed and all other existing federal and state controls and enforceable agreements.
► Emission totals presented here reflect all covered coal steam and IGCC electric generating units > 25 MW.
► The policy case imposes mercury and HCl emission rate limitations on these units, and requires fabric filters on a subset of those units.
► The mercury content of the coal consumed in the base case by EGUs > 25 MW is 75 tons in 2015; emissions from those units under the Toxics Rule represent more than a 90% reduction in that mercury.
12
5.8
3.8 3.7 3.5
1.7 1.7 1.7
0
1
2
3
4
5
6
7
2009 2015 2020 2030
Mill
ion
Tons
SO2 Emissions
351.6
74.4 70.8 64.86.6 6.9 7.2
050
100150200250300350400
2005 2015 2020 2030
Thou
sand
Ton
s
HCl Emissions
52.9
29.1 29.4 29.6
6.4 6.5 6.6
0
10
20
30
40
50
60
2005 2015 2020 2030
Tons
Hg Emissions
Sources Can Achieve These Standards
13
• Proven control technologies to reduce these emissions such as scrubbers, fabric filters, and activated carbon injection are widely available
• Many units already use one or more of these technologies
• As a result of this standard, some power plants will upgrade existing controls (especially particulate matter controls like electrostatic precipitators)
• Power plants may also install new controls (such as fabric filters, dry sorbent injection, or activated carbon injection)
174
299
141
5377
175
54 65
146 146
243
0
50
100
150
200
250
300
350
Wet FGD Dry FGD DSI SCR ACI FF
2015
Cap
acity
(GW
)
Base
Proposed Toxics Rule
Retrofit pollution control installations on coal-fired capacity (by technology) with the base case and with the proposed Toxics Rule, 2015 (measured in GW capacity). Source: Integrated Planning Model run by EPA, 2011
FGD: flu gas desulfurization (scrubber)
DSI: dry sorbent injectionSCR: selective catalytic reductionACI: activated carbon injectionFF: fabric filter
FGD – 96% SO2 removal; 99% HCl removal DSI – 70% SO2 removal; 90% HCl removalSCR – 80% NOx removal ACI – 90% Hg removalFF – PM control
Cost and Retirement Projections
► Private compliance costs to utilities are distinct from the overall social cost of the policy. The compliance costs depicted are increased costs of operating the electric generation system throughout the US.
► Incremental retired coal capacity in 2015 is about 10 GW. Also, it is important to recognize:► EPA identified about 11 GW of firm retirements
announced for 2010-2015 that were removed from modeling
► EPA modeling suggests forecasted natural gas prices alone close about 4 GW of coal-fired capacity in 2015 in the base case, and Transport Rule may close an additional 1 GW.
► Toxics Rule and Transport Rule (as proposed) together close 11 GW of coal in 2015.
► Closures are distributed throughout the US.
14
$10.9 $10.1 $10.0
$0
$5
$10
$15
2015 2020 2030
Billi
ons $
2007
Incremental Compliance Cost for the Power Sector
9.87
-0.18 -0.46 -0.77-5
0
5
10
15
Capa
city
(GW
)
Incremental Retired Capacity in 2015
Coal Steam CC CT Nuclear
2015 Capacity(before retirements)
Total: 1,028 GWCoal Steam & IGCC: 314 GW
Average Consumer Electricity Price Projections
National average increase of 3.7% in 2015 that declines over time
15
90 8910293 92
104
0
50
100
150
2015 2020 2030
2007
-yea
r mill
s/kW
h
Average National Retail Electricity PriceBase Proposed Toxics Rule
0
20
40
60
80
100
120
140
160
2007
mill
s/KW
h
2015 Retail Electricity PriceBase Proposed Toxics Rule
0
20
40
60
80
100
120
140
160
2007
mill
s/KW
h
2020 Retail Electricity PriceBase Proposed Toxics Rule
Generation and Capacity Projections
► Coal-fired generation is slightly reduced as a result of the proposed rule.► Increase in demand is met largely with additional natural gas-fired generation► IPM results suggest that the sector will be able to comply with the Toxics Rule while
relying primarily on existing generating assets► Overcapacity at existing combined cycle units responds to displaced generation
in 2015► An additional 8 GW of new capacity is projected by 2030 relative to the base
case, most of which is natural gas combined cycle.16
2.00 1.96 2.02 1.98 2.06 2.01
0.83 0.83 0.83 0.84 0.81 0.82
0.69 0.73 0.83 0.87 1.16 1.210.29 0.29 0.29 0.29
0.29 0.290.25 0.25
0.29 0.290.33 0.33
0
1
2
3
4
5
Base Tox R Base Tox R Base Tox R
Mill
ion
GW
h
Generation MixOther
Oil
Non-HydroRenewablesHydro
Natural Gas
Nuclear
Coal
2015 2020 2030
2.77
7.40
0.02
0.02
0.68
0.08
0.09
0
2
4
6
8
10
2015 2020 2030
Capa
city
(GW
)
Incremental New Capacity
Natural Gas CC Wind Biomass
Impacts on Coal Consumption and Natural Gas
• Natural gas consumption is expected to increase 3-6 percent by the power sector from 2015-2030.
• Over this time, “delivered” natural gas prices to the power sector and at Henry Hub (wellhead) will have an average increase less than 10 cents per million Btus, about 1.3 percent.
• Over this time, residential consumers would see an average price increase of less than 1 percent .
• Coal use from major regions decreases slightly from the proposed Toxics Rule. There is a slight increase in use of interior coals in some years.
• There is some increase in bituminous coal use and decline in other coal types used.
17
11,450 11,628 11,297 11,547 11,440 11,703
7,762 7,668 7,984 7,885 8,599 8,073
904 609 1,059 651 718 657
0
5,000
10,000
15,000
20,000
25,000
2015 Base2015 Tox R2020 Base2020 Tox R2030 Base2030 Tox R
Trill
ion
Btu
Coal Use by RankLignite Subbituminous Bituminous
942
551 543 557 553 599 567
227 233 239 228240 252
183 168 174 165154 153
30 30 37 37 38 38
0
200
400
600
800
1,000
1,200
Base Tox R Base Tox R Base Tox R
Mill
ion
Tons
Power Sector Coal UseImports Waste Coal Appalachia Interior West
Proposed Toxic Rule Health Benefits
• The value of the improvements to health alone total $59 billion to $140 billion each year
• This means that for every dollar spent to reduce this pollution, we would get $5-$13 in health benefits
• Each year, the proposed rule would prevent serious health effects including:– 6,800-17,000 premature deaths– 11,000 heart attacks– 120,000 asthma attacks– 850,000 missed work or “sick” days
• Avoiding “sick days” saves companies and families money. It is particularly important for the millions of Americans whose jobs do not provide paid sick leave and who risk losing their jobs if they miss work too often– The proposed rule would also prevent 12,200 hospital admissions and
emergency room visits; 4,500 cases of chronic bronchitis; and 5,100,000 days when people must restrict their activities each year
18
Source: EPA Regulatory Impact Analysis
The Toxics Rule: Implementation
• When we compare the investments that will be required to comply with these standards with investments that this same industry has made in the past they do not look out of line.
– In each of 2007 through 2010, over 20 GWs of advanced pollution control equipment was installed. This includes a peak of over 35 GWs of scrubbers and SCRs in 2009.
• The act contains key flexibilities such as providing permitting agencies the discretion to provide one-year extensions (beyond the general three year time-frame for compliance required by the Act) that will be key to addressing any facility-specific concerns.
• While we project some retirements of old/inefficient and less frequently used coal-fired generation, the large amounts of extra generating capacity that currently exist will be key to being able to ensure reliable electricity (NERC default reserve margins are 15%, absent the rule, average capacity margins are about 25%).
19
Public Hearings and Comment
• The public is encouraged to provide EPA with comments on this proposed Toxics Rule• The Agency will seek comments for 60 days following publication in the
Federal Register and the proposed rule is currently available on EPA’s website.
• Public Hearings• Locations
• Philadelphia, PA (EPA Region 3 Headquarters)• Atlanta, GA (EPA Region 4 Headquarters)• Chicago, IL (EPA Region 5 Headquarters)
• For more information on how to attend these public hearings, please visit: http://www.epa.gov/airquality/powerplanttoxics
• Technical Contact:• Bill Maxwell (919-541-5430, [email protected])
20
Summary – Bottom-Line
• This proposed rule will result in tremendous public health benefits, worth many times the cost.
• The rule will require the power sector to invest in commercially available, cost effective, proven technology. That investment will provide jobs for tens of thousands of Americans during a period of high unemployment, create demand for products like cement, that are experiencing low demand, and create a modern clean American power sector.
• This rule has been long delayed. It is important for public health, that the rule we issue conform to the dictates of the Clean Air Act as interpreted by the courts so that it will withstand a judicial challenge.
21Thank you!