Appendix G to Part 75 - Determination of CO2 Emissions
40:18.0.1.1.4.10.1.1.12 : Appendix G
Appendix G to Part 75 - Determination of CO2 Emissions 1.
Applicability
The procedures in this appendix may be used to estimate CO2 mass
emissions discharged to the atmosphere (in tons/day) as the sum of
CO2 emissions from combustion and, if applicable, CO2 emissions
from sorbent used in a wet flue gas desulfurization control system,
fluidized bed boiler, or other emission controls.
2. Procedures for Estimating CO2 Emissions From Combustion
Use the following procedures to estimate daily CO2 mass
emissions from the combustion of fossil fuels. The optional
procedure in section 2.3 of this appendix may also be used for an
affected gas-fired unit. For an affected unit that combusts any
nonfossil fuels (e.g., bark, wood, residue, or refuse), either use
a CO2 continuous emission monitoring system or apply to the
Administrator for approval of a unit-specific method for
determining CO2 emissions.
2.1 Use the following equation to calculate daily CO2 mass
emissions (in tons/day) from the combustion of fossil fuels. Where
fuel flow is measured in a common pipe header (i.e., a pipe
carrying fuel for multiple units), the owner or operator may use
the procedures in section 2.1.2 of appendix D of this part for
combining or apportioning emissions, except that the term “SO2 mass
emissions” is replaced with the term “CO2 mass emissions.”
Where: Wco2 = CO2 emitted from combustion,
tons/day. MWc = Molecular weight of carbon (12.0). MWo2 = Molecular
weight of oxygen (32.0) Wc = Carbon burned, lb/day, determined
using fuel sampling and analysis and fuel feed rates.
2.1.1 Collect at least one fuel sample during each week that the
unit combusts coal, one sample per each shipment or delivery for
oil and diesel fuel, one fuel sample for each delivery for gaseous
fuel in lots, one sample per day or per hour (as applicable) for
each gaseous fuel that is required to be sampled daily or hourly
for gross calorific value under section 2.3.5.6 of appendix D to
this part, and one sample per month for each gaseous fuel that is
required to be sampled monthly for gross calorific value under
section 2.3.4.1 or 2.3.4.2 of appendix D to this part. Collect coal
samples from a location in the fuel handling system that provides a
sample representative of the fuel bunkered or consumed during the
week.
2.1.2 Determine the carbon content of each fuel sample using one
of the following methods: ASTM D3178-89 (Reapproved 2002) or ASTM
D5373-02 (Reapproved 2007) for coal; ASTM D5291-02, Standard Test
Methods for Instrumental Determination of Carbon, Hydrogen, and
Nitrogen in Petroleum Products and Lubricants, ultimate analysis of
oil, or computations based upon ASTM D3238-95 (Reapproved 2000) and
either ASTM D2502-92 (Reapproved 1996) or ASTM D2503-92 (Reapproved
1997) for oil; and computations based on ASTM D1945-96 (Reapproved
2001) or ASTM D1946-90 (Reapproved 2006) for gas (all incorporated
by reference under § 75.6 of this part).
2.1.3 Use daily fuel feed rates from company records for all
fuels and the carbon content of the most recent fuel sample under
this section to determine tons of carbon per day from combustion of
each fuel. (All ASTM methods are incorporated by reference under §
75.6.) Where more than one fuel is combusted during a calendar day,
calculate total tons of carbon for the day from all fuels.
2.2 For an affected coal-fired unit, the estimate of daily CO2
mass emissions given by equation G-1 may be adjusted to account for
carbon retained in the ash using the procedures in either section
2.2.1 through 2.2.3 or section 2.2.4 of this appendix.
2.2.1 Determine the ash content of the weekly sample of coal
using ASTM D3174-00, “Standard Test Method for Ash in the Analysis
Sample of Coal and Coke from Coal” (incorporated by reference under
§ 75.6 of this part).
2.2.2 Sample and analyze the carbon content of the fly-ash
according to ASTM D5373-02 (Reapproved 2007), Standard Test Methods
for Instrumental Determination of Carbon, Hydrogen, and Nitrogen in
Laboratory Samples of Coal and Coke” (incorporated by reference
under § 75.6 of this part).
2.2.3 Discount the estimate of daily CO2 mass emissions from the
combustion of coal given by equation G-1 by the percent carbon
retained in the ash using the following equation:
(Eq. G-2) where, WNCO2 = Net CO2 mass emissions
discharged to the atmosphere, tons/day. WCO2 = Daily CO2 mass
emissions calculated by equation G-1, tons/day. MWC02 = Molecular
weight of carbon dioxide (44.0). MWc = Molecular weight of carbon
(12.0). A% = Ash content of the coal sample, percent by weight. C%
= Carbon content of ash, percent by weight. WCOAL = Feed rate of
coal from company records, tons/day.
2.2.4 The daily CO2 mass emissions from combusting coal may be
adjusted to account for carbon retained in the ash using the
following equation:
WNCO2 = .99
WCO2 (Eq. G-3) where, WNCO2 = Net CO2
mass emissions from the combustion of coal discharged to the
atmosphere, tons/day. .99 = Average fraction of coal converted into
CO2 upon combustion. WCO2 = Daily CO2 mass emissions from the
combustion of coal calculated by equation G-1, tons/day.
2.3 In lieu of using the procedures, methods, and equations in
section 2.1 of this appendix, the owner or operator of an affected
gas-fired or oil-fired unit (as defined under § 72.2 of this
chapter) may use the following equation and records of hourly heat
input to estimate hourly CO2 mass emissions (in tons).
(Eq. G-4) Where: WCO2 = CO2 emitted from
combustion, tons/hr. MW CO2 = Molecular weight of carbon dioxide,
44.0 lb/lb-mole. Fc = Carbon based F-factor, 1040 scf/mmBtu for
natural gas; 1,420 scf/mmBtu for crude, residual, or distillate
oil; and calculated according to the procedures in section 3.3.5 of
appendix F to this part for other gaseous fuels. H = Hourly heat
input in mmBtu, as calculated using the procedures in section 5 of
appendix F of this part. Uf = 1/385 scf CO2/lb-mole at 14.7 psia
and 68 °F. 3. Procedures for Estimating CO2 Emissions From Sorbent
When the affected unit has a wet flue gas desulfurization
system, is a fluidized bed boiler, or uses other emission controls
with sorbent injection, use either a CO2 continuous emission
monitoring system or an O2 monitor and a flow monitor, or use the
procedures, methods, and equations in sections 3.1 through 3.2 of
this appendix to determine daily CO2 mass emissions from the
sorbent (in tons).
3.1 When limestone is the sorbent material, use the equations
and procedures in either section 3.1.1 or 3.1.2 of this
appendix.
3.1.1 Use the following equation to estimate daily CO2 mass
emissions from sorbent (in tons).
(Eq. G-5) where, SECO2 = CO2 emitted from
sorbent, tons/day. WCaCO3 = CaCO3 used, tons/day. Fu = 1.00, the
calcium to sulfur stoichiometric ratio. MWCO2 = Molecular weight of
carbon dioxide (44). MWCaCO3 = Molecular weight of calcium
carbonate (100).
3.1.2 In lieu of using Equation G-5, any owner or operator who
operates and maintains a certified SO2-diluent continuous emission
monitoring system (consisting of an SO2 pollutant concentration
monitor and an O2 or CO2 diluent gas monitor), for measuring and
recording SO2 emission rate (in lb/mmBtu) at the outlet to the
emission controls and who uses the applicable procedures, methods,
and equations such as those in EPA Method 19 in appendix A to part
60 of this chapter to estimate the SO2 emissions removal efficiency
of the emission controls, may use the following equations to
estimate daily CO2 mass emissions from sorbent (in tons).
(Eq. G-6) where, SECO2 = CO2 emitted from
sorbent, tons/day. MWCO2 = Molecular weight of carbon dioxide (44).
MWSO2 = Molecular weight of sulfur dioxide (64). WSO2 = Sulfur
dioxide removed, lb/day, as calculated below using Eq. G-7. Fu =
1.0, the calcium to sulfur stoichiometric ratio. and
(Eq. G-7) where: WSO2 = Weight of sulfur
dioxide removed, lb/day. SO20 = SO2 mass emissions monitored at the
outlet, lb/day, as calculated using the equations and procedures in
section 2 of appendix F of this part. %R = Overall percentage SO2
emissions removal efficiency, calculated using equations such as
those in EPA Method 19 in appendix A to part 60 of this chapter,
and using daily instead of annual average emission rates.
3.2 When a sorbent material other than limestone is used, modify
the equations, methods, and procedures in section 3.1 of this
appendix as follows to estimate daily CO2 mass emissions from
sorbent (in tons).
3.2.1 Determine a site-specific value for Fu, defined as the
ratio of the number of moles of CO2 released upon capture of one
mole of SO2, using methods and procedures satisfactory to the
Administrator. Use this value of Fu (instead of 1.0) in either
equation G-5 or equation G-6.
3.2.2 When using equation G-5, replace MWCaCO3, the molecular
weight of calcium carbonate, with the molecular weight of the
sorbent material that participates in the reaction to capture SO2
and that releases CO2, and replace WCaCO3, the amount of calcium
carbonate used (in tons/day), with the amount of sorbent material
used (in tons/day).
4. Procedures for Estimating Total CO2 Emissions
When the affected unit has a wet flue gas desulfurization
system, is a fluidized bed boiler, or uses other emission controls
with sorbent injection, use the following equation to obtain total
daily CO2 mass emissions (in tons) as the sum of combustion-related
emissions and sorbent-related emissions.
Wt = WCO2 + SECO2 (Eq. G-8) where, Wt = Estimated total CO2 mass
emissions, tons/day. WCO2 = CO2 emitted from fuel combustion,
tons/day. SECO2 = CO2 emitted from sorbent, tons/day. 5. Missing
Data Substitution Procedures for Fuel Analytical Data
Use the following procedures to substitute for missing fuel
analytical data used to calculate CO2 mass emissions under this
appendix.
5.1-5.1.2 [Reserved] 5.2 Missing Carbon Content Data
Use the following procedures to substitute for missing carbon
content data.
5.2.1 In all cases (i.e., for weekly coal samples or composite
oil samples from continuous sampling, for oil samples taken from
the storage tank after transfer of a new delivery of fuel, for
as-delivered samples of oil, diesel fuel, or gaseous fuel delivered
in lots, and for gaseous fuel that is supplied by a pipeline and
sampled monthly, daily or hourly for gross calorific value) when
carbon content data is missing, report the appropriate default
value from Table G-1.
5.2.2 The missing data values in Table G-1 shall be reported
whenever the results of a required sample of fuel carbon content
are either missing or invalid. The substitute data value shall be
used until the next valid carbon content sample is obtained.
5.3 Gross
Calorific Value Data
For a gas-fired unit using the procedures of section 2.3 of this
appendix to determine CO2 emissions, substitute for missing gross
calorific value data used to calculate heat input by following the
missing data procedures for gross calorific value in section 2.4 of
appendix D to this part.
[58 FR 3701, Jan. 11, 1993, as amended at 60 FR 26556, May 17,
1995; 61 FR 25585, May 22, 1996; 64 FR 28671, May 26, 1999; 67 FR
40475, June 12, 2002; 67 FR 57274, Sept. 9, 2002; 73 FR 4376, Jan.
24, 2008]