oEPA
United States
Environmental Protection
Agency
THE EMISSIONS & GENERATION
RESOURCE INTEGRATED DATABASE
eGRID Technical Guide with Year 2020 Data
eGRIDP
2020
Office of Atmospheric Programs
Clean Air Markets Division
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eGRID2020
Technical Guide
FINAL
January 2022
Prepared for:
Clean Air Markets Division
Office of Atmospheric Programs
U.S. Environmental Protection Agency
Washington, DC 20460
Prepared by:
Abt Associates
6130 Executive Blvd.
Rockville, MD 20852
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NOTICES
Notices
This document has been reviewed by the Clean Air Markets Division (CAMD), Office of
Atmospheric Programs (OAP), U.S. Environmental Protection Agency (EPA), and approved for
distribution.
Technical Support Document for eGR!D2020
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ACKNOWLEDGM ENTS
Acknowledgments
This edition of eGRID was developed under the leadership of Mr. Travis Johnson and Dr. Jeremy
Schreifels of EPA" s Clean Air Markets Division (CAMD) and Dr. Jonathan Dorn, Ms. MarissaHoer,
Mr. David Cooley, Mr. Matt Pasquali, and Ms. Liz Shenaut of Abt Associates, Inc. The eGRID
concept was originated by Mr. Rick Morgan, former EPA Senior Energy Analyst in EPA" s Office of
Atmospheric Programs, and historical development was led by Mr. Art Diem of EPA" s Office of Air
Quality Planning and Standards.
Technical Support Document for eGRID2020
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CONTENTS
Contents
Notices i
Acknowledgments ii
Contents iii
Abbreviations and Acronyms vi
1. Introduction 10
2. Summary of eGRID2020 Data 11
2.1 eGRID Files 11
2.2 What's New in eGRID 12
2.3 Uses and Users of eGRID 12
2.4 eGRID Data Sources 15
3. eGRID Methodology 16
3.1 Estimation of Emissions 16
3.1.1 Unit Level and Plant Level Unadjusted Emission Estimates 17
3.1.1.1 Annual Emission Estimates for CO2, NOk, and SO2 17
3.1.1.2 Annual Emission Estimates for CH4,N20, and CO2 equivalent 19
3.1.1.3 Annual Emission Estimates for Mercury 21
3.1.2 Plant Level Adjusted Emission Estimates 21
3.1.2.1 Adj ustments for Bi omass 22
3.1.2.2 Adj ustments for CHP 23
3.1.2.3 Plant-level adjustment example calculation 24
3.1.3 Emission Rate Estimates 25
3.1.3.1 Generation 26
3.1.3.2 Heat Input 26
3.1.3.3 Emission Rates 27
3.2 Determination of Plant Primary Fuel 29
3.3 Estimation of Resource Mix 29
3.4 Aggregating Plant-Level Data 30
3.4.1 Balancing Authority 30
3.4.2 eGRID Subregion 31
3.4.3 NERC Region 33
3.5 Grid Gross Loss 33
4. Specific eGRID Identifier Codes, Name Changes, Associations, and Data Updates 36
4.1 Plant Level 36
4.1.1 Plant ID Changes 36
4.1.2 Generator/Unit ID Changes. 36
4.1.3 Longitude/Latitude Updates 37
4.1.4 EPA/CAMD Plants Not Connected to the Grid 37
4.1.5 Net Generation Updates 38
5. Description of Data Elements. 39
5.1 The UNIT (Unit) File 39
5.2 The GEN (Generator) File. 46
5.3 The PLNT (Plant) File. 49
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CONTENTS
5.4 The ST (State) File 64
5.5 The BA (Balanting Authority) File 71
5.6 The SRL (eGRID Subregion) File 71
5.7 The NRL (NERC Region) File 72
5.8 The US (U.S.) File 72
5.9 The Regional Grid Gross Loss File. 72
6. References 74
Appendix A. eGRID File Structure - Variable Descriptions for eGRID2020 78
Appendix B. eGRID Subregion and NERC Region Representational Maps. 105
Appendix C. Crosswalks and Additional Data Tables 107
Emission Factors - NOx, CO2, SO2, CH4, andN20 107
Biomass fuels used in 1he Plant file biomass emission adjustments. 122
Plant ORIS PI. II) Changes 123
Geothermal Geotype 125
English to Metric Conversion Factors 125
Appendix D. Information on Prior Editions of eGRID 126
Tables
Table 3-1. Comparison of 100-Year GWPs 20
Table 3-2. Example Biomass and CHP CO2 Emissions Adjustment Calculation 25
Table 3-3. Fuel-based Emission Rates - Primary Fuel Category 27
Table 3-4. eGRID Subregion Acronym and Names for eGRID 32
Table 3-5. NERC Region Acronym and Names for eGRID 33
Table 3-6. eGRI 1)2020 Grid Gross Loss (%) 35
Table 4-1. eGRID2020 Latitude/Longitude Updates 37
Table 4-2. eGRID2020 EPA/CAMD Plants Not Connected to the Grid 38
Table 4-3. eGRID2020 Net Generation Updates for Georgetown Plant (ORIS 7759) 38
Table A-1. eGRID File Structure, eGRI 1)2020 UNIT File 78
Table A-2. eGRID File Structure, eGRID2020 GEN Generator File 79
Table A-3. eGRID File Structure, eGRI 1)2020 PLNT Plant File 80
Table A-4. eGRID File Structure, eGRI 1)2020 ST State File. 84
Table A-5. eGRID File Structure, eGRID2020 BA File, Balancing Authority (BA) File. 88
Table A-6. eGRID File Structure, eGRID2020 SRL File, eGRID Subregion File 92
Table A-7. eGRID File Structure, eGRID2020 NRL File, NERC Region File. 96
Table A-8. eGRID File Structure, eGRID2020 U.S. File, United States File 100
Table A-9. eGRID File Structure, eGRID2020 GGL File, Grid Gross Loss (%) File 104
Table C-l. eGRID Emission Factors for CO2, CH4, andN20 107
Table C-2. eGRID Emission Factors for Nitrogen Oxides (NOk) 108
Table C-3. Sulfur dioxide (SO2) emission factors 115
Table C-4. Fuel types and pollutants included in the Plant file biomass emission adjustments 122
Table C-5. Crosswalk of Plant ID changes 123
Table C-l. Geothermal Emission Factors by Geotype and Pollutant 125
Table C-8. Conversion Factors 125
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CONTENTS
Figures
Figure B-l. eGRID Subregion Representational Map 105
Figure B-2. NERC Region Representational Map 106
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ABBREVIATIONS AND ACRONYMS
Abbreviations and Acronyms
40 CFR Part 75
AB 32
AR4
AR5
BA
BBtu
Btu
CAMD
CHP
CH4
C02
C02e
DOE
DVRPC
EF
eGRID
eGRID1996
eGRID 1997
eGRID 1998
eGRID2000
eGRID2004
eGRID2005
eGRID2007
eGRID2009
Code of Federal Regulations Title 40 Part 75, which specifies air emissions
monitoring and reporting requirements delineated in EPA regulations
Assembly Bill 32 - California Global Warming Solutions Act
Fourth Assessment Report of the Intergovernmental Panel on Climate
Change
Fifth Assessment Report of the Intergovernmental Panel on Climate Change
Balancing authority
Billion Btu
British thermal unit
Clean Air Markets Division
Combined heat and power (cogeneration)
Methane
Carbon dioxide
Carbon dioxide equivalent
U.S. Department of Energy
Delaware Valley Regional Planning Commission
Emission factor
Emissions & Generation Resource Integrated Database
First edition of Emissions & Generation Resource Integrated Database with
year 1996 data
Second edition of the Emissions & Generation Resource Integrated Database
with year 1997 data
Third edition of the Emissions & Generation Resource Integrated Database
with year 1998 data
Fourth edition of the Emissions & Generation Resource Integrated Database
with years 1999 and 2000 data (1996-1998 data were also reissued without
change)
Fifth edition of the Emissions & Generation Resource Integrated Database
with year 2004 data
Sixth edition of the Emissions & Generation Resource Integrated Database
with year 2005 data (2004 data were also reissued without change)
Seventh edition of the Emissions & Generation Resource Integrated Database
with year 2007 data (2005 and 2004 data were also reissued without change)
Eighth edition of the Emissions & Generation Resource Integrated Database
with year 2009 data (2007, 2005, and 2004 data were also reissued without
change)
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ABBREVIATIONS AND ACRONYMS
eGRID2010 Ninth edition of the Emissions & Generation Resource Integrated Database
with year 2010 data
eGRID2012 Tenth edition of the Emissions & Generation Resource Integrated Database
with year 2012 data
eGRID2014 Eleventh edition of the Emissions & Generation Resource Integrated
Database with year 2014 data
eGRID2016 Twelfth edition of the Emissions & Generation Resource Integrated Database
with year 2016 data
eGRID2018 Thirteenth edition of the Emissions & Generation Resource Integrated
Database with year 2018 data
eGRID2019 Fourteenth edition of the Emissions & Generation Resource Integrated
Database with year 2019 data
eGRID2020 Fifteenth edition of the Emissions & Generation Resource Integrated
Database with year 2020 data
EGC Electric generating company
EIA Energy Information Administration
ELCALLOC Electric allocation factor
EPA U. S. Environmental Protection Agency
FERC Federal Energy Regulatory Commission
FIPS Federal Information Processing Standards
GGL Grid gross loss
GHG Greenhouse gas
GWh Gigawatt-hour
GWP Global warming potential
Hg Mercury
ICR Information collection request
ID Identifier
IPCC Intergovernmental Panel on Climate Change
IPM Integrated Planning Model
ISO Independent System Operator
kg Kilogram
kWh Kilowatt-hour
lb Pound
MISO Midcontinent Independent System Operator
GJ Gigajoule
MMBtu Million Btu
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ABBREVIATIONS AND ACRONYMS
MMcf Million cubic feet
MSB Municipal solid waste - biomass component
MSN Municipal solid waste - non-biomass component
MSW Municipal solid waste
MW Megawatt
MWh Megawatt-hour
NATCARB National Carbon Sequestration Database and Geographic Information System
NEMS National Energy Modeling System
NERC North American Electric Reliability Corporation
NESCAUM Northeast States for Coordinated Air Use Management
NETL National Energy Technology Laboratory
NGO Nongovernmental Organization
NOx Nitrogen oxides
NREL National Renewable Energy Laboratory
N2O Nitrous oxide
OAP Office of Atmospheric Programs
ORIS Office of Regulatory Information Systems
ORISPL Office of Regulatory Information Systems Plant code
ORNL Oak Ridge National Laboratory
OTC Ozone Transport Commission
RECs Renewable Energy Credits
RTO Regional Transmission Organization
SAR Second Assessment Report of the Intergovernmental Panel on Climate
Change
SO2 Sulfur dioxide
TAR Third Assessment Report of the Intergovernmental Panel on Climate Change
TJ Terajoule
VRSA Voluntary Renewable Set-Aside Account
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SUMMARY OF eGRID YEAR 2020 DATA
1. Introduction
The Emissions & Generation Resource Integrated Database (eGRID) is a comprehensive source of
data on the environmental characteristics of almost all electric power generated in the United States.
The preeminent source of emissions data for the electric power sector, eGRID is based on available
plant-specific data for all U. S. electricity generating plants that provide power to the electric grid and
report data to the U. S. government. Data reported include, but are not limited to, net electric
generation; resource mix (for renewable and nonrenewable generation); mass emissions of carbon
dioxide (CO2), nitrogen oxides (NOx), sulfur dioxide (SO2), methane (CH4), nitrous oxide (N2O), and
mercury (Hg); emission rates for CO2, NOx, SO2, CH4, and N2O; heat input; and nameplate capacity.
eGRID reports this information on an annual basis (as well as by ozone season for NOx) at different
levels of aggregation.
eGRID2020, released in January 2022 is the fifteenth edition of eGRID. eGRID2020 includes two
Excel workbooks, one with English units and one with metric units, that contain generator and unit
spreadsheets as well as spreadsheets by aggregation level for datayear 2020: plant, state, balancing
authority, eGRID subregion, NERC region, and United States. The workbooks also include a
spreadsheet that displays the grid gross loss and the variables that are used in its estimation for year
2020.
This document provides a description of eGRID2020, including the methodology for developing the
Excel spreadsheets for each level of aggregation and the grid gross loss calculation. Section 2
provides a summary of the database; Section 3 presents the methodology for emissions estimations,
including adjustments for biomass and combined heat and power (CHP); Section 4 discusses eGRID
specific identification codes, name changes and associations; Section 5 describes the data elements in
detail; and Section 6 provides a list of references. There is also a set of four Appendices - Appendix
A includes the file structure; Appendix B includes the eGRID subregion and NERC region
representational maps; Appendix C includes crosswalks between different datasets and relevant data
tables; and Appendix D contains information on previous releases of eGRID.
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SUMMARY OF eGRID YEAR 2020 DATA
2. Summary of eGRID2020 Data
2.1 eGRID Files
eGRID2020 contains electric power data at different levels of aggregation. The eGRID2020 data are
displayed in two workbooks, one with English units of measure and the other with metric units of
measure. As the database name implies, the focus of the data spreadsheets is on two areas: generation
and emissions. In the English unit workbook, generation is expressed in both MWh and as a
percentage (called "resource mix" - generation of a certain fuel or resource type divided by total
generation). Carbon dioxide, NOx, and SO2 emissions are expressed in short tons; CH4, N2O, and Hg
emissions are expressed in pounds; emission rates for CO2, NOx, SO2, CH4, and N2O are expressed in
lb/MWh and lb/MMBtu. In the Metric unit workbook, generation is expressed in MWh, Gigajoules
(GJ), and as a percentage. Carbon dioxide, NOx, and SO2 emissions are expressed in metric tons;
CH4, N2O, and Hg emissions are expressed in kilograms; emission rates for CO2, NOx, SO2, CH4, and
N2O are expressed in both kg/MWh and kg/GJ. See Table C-8 for a list of English to Metric
conversion factors.
The eGRID2020 workbooks can be downloaded from the EPA eGRID website,
https://www.epa. gov/egrid. along with Summary Tables and this document. The workbooks contain
eight levels of data aggregation:
UNIT (unit), with 28,872 records;
GEN (generator), with 30,193 records;
PLNT (plant), with 12,668 records;
ST (state), with 52 records;
BA (balancing authority), with 72 records;
SRL (eGRID subregion), with 27 records;
NRL (NERC region), with 9 records; and
US, with 1 record.
The unit spreadsheet is sorted by state abbreviation, plant name, plant code, and unit ID. The
generator spreadsheet is sorted by state abbreviation, plant name, plant code, and generator ID. The
plant spreadsheet is sorted by state abbreviation, plant name, and plant code. The state spreadsheet is
sorted by state abbreviation, the balancing authority spreadsheet is sorted by balancing authority
name, the eGRID subregion spreadsheet is sorted by eGRID subregion name, and the NERC region
spreadsheet is sorted by NERC region acronym. The year 2020 grid gross loss spreadsheet is also
included in the workbook.
The spreadsheet structure for each of the spreadsheets is included in Appendix A. The spreadsheet
structure also includes a description of the variables and the original data sources.
Users should take note that eGRID" s emissions and emission rates are calculated at the sources of
generation and do not account for losses from transmission and distribution infrastructures. Please
refer to Section 3.5 for information on how to account for line losses when assigning emission rates to
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SUMMARY OF eGRID YEAR 2020 DATA
estimate indirect emissions associated with electricity purchases. Aggregated eGRID data only
account for U. S. generation that takes place within the aggregated area and do not account for any
electricity that is imported from or exported to other areas. The grid gross loss calculation, however,
does account for U. S. regional interchanges with other U. S. regions as well as Canada and Mexico.
In addition, although eGRID is based on existing Federal data sources, its development requires
substantial attention to quality control. Accurate matching of entities from different databases requires
great care, even where identification codes are available. Inconsistencies between data sources,
missing data, and ambiguous data necessitate adjustments to values of individual data elements,
especially identification data. In general, however, questionable data are not altered in order to
maintain consistency with the original data sources.
Please note that only certain eGRID spreadsheets can be linked from year 2020 to years 2019, 2018,
2016, 2014, 2012, 2010, 2009,2007, 2005, or 2004. The spreadsheets that can be linked include the
NERC region (by NERC acronym), eGRID subregion (by eGRID subregion acronym), state (by state
abbreviation), plant (by Office of Regulatory Information Systems Plant [ORISPL] code), and the
US.
2.2 What's New in eGRID
There is one new change to the eGRID methodology in eGRID2020:
The NERC regions ASCC in Alaska and HICC in Hawaii were no longer included in the
EIA-860 Plant file and are therefore not included in eGRID2020. All plants in Alaska and
Hawaii have been assigned to a NERC region matching their state name and abbreviation,
AK and HI respectively.
2.3 Uses and Users of eGRID
eGRID data support a wide variety of users globally through a wide variety of uses. eGRID is
valuable to those in the Federal Government, state and local governments, non-governmental
organizations, academia, and companies who are generally seeking environmental information from
the electric power sector in the United States. eGRID is most often used for the estimation of indirect
emissions from electricity purchases, in greenhouse gas (GHG) inventories, for carbon footprinting,
and for estimating avoided emissions from programs and projects that would reduce the consumption
for grid supplied electricity. eGRID data are cited by emission inventory and registry protocols,
various emission calculation tools and applications, many academic papers, and many consultants,
and it is used for many research applications and efforts.
Within EPA, eGRID data are used in the following applications and programs: Power Profiler web
application, Climate Leaders protocols, ENERGYSTAR's Portfolio Manager and Target Finder,
Waste Wise Office Carbon Footprint Tool, the Personal Greenhouse Gas Emissions Calculator, the
Greenhouse Gas Equivalencies Calculator, and the Green Power Equivalency Calculator.
When the EPA announced its "Apps for the Environment" challenge using EPA data, developers
across the U. S. responded. EPA announced the winners on November 8, 2011 and the two top
winning apps Light Bulb Finder (http: // www. 1 i ghtbul blinder .net/) and Hootroot use eGRID data for
a mobile app and/or a web app, as did several other entries (EPA, 2011). Another of the winning
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SUMMARY OF eGRID YEAR 2020 DATA
entries, Joulebug (http://j oulebug. com/), uses eGRID data and developed a game to save energy as
both a web and free iPhone app.
One of the most popular uses of eGRID is to determine the indirect GHG emissions from electricity
purchases and avoided GHG emissions from projects and programs that reduce the demand for grid
supplied electricity. For example, The Climate Registry, California's Mandatory GHG emissions
reporting program (AB 32), and the Greenhouse Gas Protocol Initiative cite eGRID for use in
estimating scope 2 (indirect) GHG emissions from electricity purchases in the United States (TCR,
2019; CARB, 2007; Greenhouse Gas Protocol, 2016). Most carbon footprint calculators that are
applicable to the United States use eGRID data.
The website, www, fuel economy, gov, resulting from an EPA-U.S. Department of Energy (DOE)
partnership, provides fuel economy information that consumers can use to make knowledgeable
decisions when buying a car. The information can also help consumers achieve the best fuel economy
from currently owned cars. This website showcases its Greenhouse Gas Emissions for Electric and
Plug-in Hybrid Electric Vehicles calculator, http://www.fueleconomy.gov/feg/label/calculator.! sp.
which uses eGRID data to estimate the total GHG emissions from electric and plug-in hybrid
vehicles, including emissions from electricity used to charge the vehicle. eGRID is cited as a data
source at http://www.fueleconomy.gov/feg/label/calculations-information.shtml. In a similar vein, the
Union of Concerned Scientists published a 2012 report using eGRID data to support its study results
that it is advantageous to switch to a battery-powered vehicle, although there are wide differences in
both real electricity costs and GHG emissions, depending on the region in which you live (UCS,
2012).
eGRID is also used by other Federal Government agencies such as Oak Ridge National Laboratory
(ORNL) for their Combined Heat and Power Calculator, the National Energy Technology Laboratory
(NEIL) for their sponsored distributed National Carbon Sequestration Database and Geographic
Information System (NATCARB), and the National Renewable Energy Laboratory (NREL) for their
micropower distributed generation optimization model named HOMER.
States and local governments rely on eGRID data for electricity labeling (environmental disclosure
programs), emissions inventories, and registries as well as for efforts to analyze air emissions from
the electric power sector. Several states have published state specific emissions information from
eGRID or have used eGRID to inform policy decisions. The Maryland Department of the
Environment determined eligibility for participation in the Voluntary Renewable Set-Aside Account
(VRSA) using eGRID factors (Maryland, 2010); and in 2009, the Delaware Valley Regional Planning
Commission (DVRPC) ~ a nine county region in Pennsylvania and New Jersey completed a 2005
GHG inventory in support of regional efforts to quantify and reduce emissions associated with
climate change, using eGRID factors (DVRPC, 2010).
Tracking systems for renewable energy credits (RECs), such as ISO-New England's Generation
Information System and PJM Environmental Information Services' Generation Attribute Tracking
System utilize eGRID data.
ISO New England used eGRID rates in developing the 2017 New England Electric Generator Air
Emissions Report (http://www.iso-ne.com/svstem-planning/system-plans-studies/emissions).
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eGRID is additionally used for nongovernmental organizations' (NGOs) tools and analysis. The
following is a list of some known users and applications of eGRID data: Northeast States for
Coordinated Air Use Management (NESCAUM) analysis; Powerscorecard.org; Ozone Transport
Commission (OTC)'s Emission Workbook; GHG Protocol Initiative; Rocky Mountain Institute's
Community Energy Finder; Leonardo Academy's Cleaner and Greener Environmental Program;
National Resource Defense Council's Benchmarking Air Emissions; Berkeley Institute of the
Environment; Cool Climate Carbon Footprint Calculator; Climate and Air Pollution Planning
Assistant; Emission Solution's Carbon Footprint Calculator; International Council for Local
Environmental Initiatives' Clean Air software, United States Department of Transportation Federal
Transit Administration, Google PowerMeter; National Public Radio's Visualizing the U.S. Electric
Grid; International Code Council; American Society of Heating, Refrigerating, and Air-Conditioning
Engineers; American Council for an Energy-Efficient Economy's Local Energy Efficiency Policy
Calculator; and World Resource Institute's Carbon Value Analysis Tool.
Carbon Visuals, which illustrate accurate volumetric images to visualize the carbon footprint of all
U. S. power stations, used eGRID subregion GHG emission factors
(http://www.carbonvisuals. com/projects/2015/6/23/visualising-the-carbon-footprint-of-all-us-power-
stations?rq=egrid; Carbon Visuals, 2014).
The University of California, Berkeley's CoolClimate Carbon Footprint Maps use eGRID data (Jones
andKammen, 2013).
Several papers have been written to clarify issues and respond to questions about the uses of eGRID.
The following provides details on some of the most recent presentations and papers.
In January 2021, "Using eGRID for Environmental Footprinting of Electricity Purchases,"
(Huetteman et al., 2021) was published on the EPA website.
In October 2019, "EPA's 2018 Emissions & Generation Resource Integrated Database
(eGRID): Updates and Improvements," (Dorn et al., 2019a) was presented at the 18th Annual
Community Modeling and Analysis System Conference.
In August 2019, "Adding Particulate Matter to EPA's eGRID Database," (Dorn et al., 2019b)
was presented at EPA's 2019 International Emissions Inventory Conference.
In June 2019, "Adding Particulate Matter to EPA's eGRID Database, "(Hoeretal., 2019)was
presented at the Air and Waste Management Association's 112th Annual Conference &
Exhibition.
In October 2018, "EPA's Emissions & Generation Resource Integrated Database (eGRID):
Improvements and Applications" (Cooley et al., 2019) was presented at the 17th Annual
Community Modeling and Analysis System Conference.
In May 2016, "How Part 75 Data is Used in GHG Reporting and EE/RE Quantification,"
(Johnson, 2016a) was presented at the EPRI Continuous Emissions Monitoring User Group
Conference.
In February 2016, "Emissions & Generation Resource integrated Database (eGRID),"
(Johnson, 2016b) was presented at the Energy, Utility, and Environment Conference.
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In October 2015, "EPA's Emissions & Generation Resource Integrated Database (eGRID):
Improvements and Applications: (Dorn et al. ,2015) was presented at the Community
Modeling and Analysis System Conference.
In February 2015, "eGRID Updates," (Johnson, Schreifels, and Quiroz, 2015) was presented
at the Energy, Utility, and Environment Conference.
The paper "Using EPA's eGRID to Estimate GHG Emissions Reductions from Energy
Efficiency" (Diem, Salhotra, and Quiroz, 2013) was presented at the International Energy
Program Evaluation Conference, in August 2013.
In January 2013, "Using eGRID Data for Carbon Footprinting Electricity Purchases," (Diem
and Quiroz, 2013) was presented at the Energy, Utility, and Environment Conference.
The paper "How to use eGRID for Carbon Footprinting Electricity Purchases in Greenhouse
Gas Emission Inventories" (Diem and Quiroz, 2012) was presented at the EPA 2012
International Emission Inventory Conference in August 2012.
2.4 eGRID Data Sources
eGRID is developed using the following key data sources:
CAMD's Power Sector Emissions Data (EPA/CAMD): this includes data reported to EPA by
electric generating units to comply with the regulations in 40 CFR Part 75 and 40 CFR Part
63. Data include annual emissions of C02,NOx, SO2, andHg; ozone season emissions of
NOx; and annual and ozone season generation and heat input. The data are available at
https://www.epa. gov/airmarkets/power-sector-emissions-data. CAMD's Power Sector
Emissions Data used in eGRID2020 was queried on September 27, 2021.
EIA-860: this includes data reported to EIA on electric generators. Data include nameplate
capacity, prime mover, primary fuel type, and indication of whether the generator is a
combined-heat-and-power unit (EIA, 2021a). The EIA-860 data used in eGRID2020 was
released on September 9, 2021. Generators from Puerto Rico were included in the EIA-860
monthly reports. The EIA-860 monthly data used in eGRID2020 was released in February
2021 and downloaded on November 3, 2021 (EIA, 2021b).
EIA-923: this includes data reported to EIA on fuel consumption and generation. Data
include monthly generation and heat input at the unit or generator level for a subset of units
and generators, and at the prime mover level for all plants. As discussed in more detail below,
eGRID2020 uses unit- or generator-level data where available, and prime mover-level data
for all other units and generators (EIA, 2021c). The EIA-923 data used in eGRID2020 was
released on September 15, 2021.
The key identifier of plants in CAMD's Power Sector Emissions Data and EIA datasets is the
ORISPL code. While the ORISPL code generally matches well for plants in the different datasets,
there are some plants that have different ORISPL codes between CAMD's Power Sector Emissions
Data and EIA data. These plants are listed in Appendix C.
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3. eGRID Methodology
This section describes the methodologies utilized to develop eGRID2020. Some methods used for
eGRID2020 are modified or refined from previous editions of eGRID, and are so noted in this
section. Also see Section 2.2 for a list of changes to eGRID2020.
3.1 Estimation of Emissions
The Unit file and Plant file in eGRID2020 include emissions data for CO2, NOx, SO2, CH4, and N2O,
and the Unit file includes Hg emissions.1 Carbon dioxide (CO2) is a product of combusting fossil
fuels, as well as biogenic and other materials, and is the primary greenhouse gas (GHG) emitted by
human activities that is driving global climate change; nitrogen oxides (NOx) are also emitted by
electric generating units and are precursors to the formation of ozone, or smog, and fine particulates
(PM2.5), and also contributes to acid rain and other environmental and human health impacts; sulfur
dioxide (SO2) is emitted by electric generating units, especially with coal combustion, and is a
precursor to acid rain and PM2.5 and is associated with other environmental and human health
impacts. Methane (CH4) and nitrous oxide (N2O), two other GHGs emitted by electric generating
units, have been included in eGRID since datayear 2005 at the plant level. The eGRID emissions
data for the three GHGs are used as default factors in a variety of climate protocols (including The
Climate Registry, California"s Mandatory GHG emissions reporting program (AB 32), and EPA's
Climate Leaders) for indirect emissions estimation calculations (TCR, 2019; CARB, 2007; EPA,
2021).
Emissions estimates are included at the unit level, in the Unit file, as well as summed to the plant
level, in the Plant file. The sum of unit level emissions from the Unit file will equal the unadjusted
plant level emissions in the Plant file, apart from Hg emissions.
Plant level emissions in eGRID reflect a combination of monitored and estimated data. Emissions and
emission rates in eGRID represent emissions and rates at the point(s) of generation. While they do
account for losses within the generating plants (net generation), they do not take into account any
power purchases, imports, or exports of electricity into a specific state or any other grouping of
plants, and they do not account for any transmission and distribution losses between the points of
generation and the points of consumption. Also, eGRID does not account for any pre-combustion
emissions associated with the extraction, processing, and transportation of fuels and other materials
used at the plants or any emissions associated with the construction of the plants.
eGRID emissions and heat input that are displayed in the Unit file are unadjusted, while the Plant file
contains emissions and heat input that are adjusted for biomass and/or CHP units, where applicable.
The Plant file also contains unadjusted emissions. The subsequent aggregation files are based on
adjusted emissions. All emission rates in the Plant file and all aggregation files are based on adjusted
1 The Plant file also containfields for emissions of mercury. However, while electric generating units started to
report mercury data to C AMD's Power Sector Emissions Data in 2015, the data are incomplete. We have
included the unit-level emissions, butsince only a subset of the units at one plant may list mercury
emissions, we have not summed these emissions to the plant-level. Therefore, we have retainedthese fields
in anticipation of being able to report plant-levelmercury emissions and emission rates in a future edition
of eGRID.
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emissions, net generation, and adjusted heat input. Both the source(s) of emissions data and
adjustment flags are provided in the Plant file.
3.1.1 Unit Level and Plant Level Unadjusted Emission Estimates
3.1.1.1 Annual Emission Estimates for CO2, NOx, and SO2
Unit File
Unit level emissions in the eGRID Unit file are estimated in a three-step process:
1. We include unit-level emissions and heat input data from CAMD's Power Sector Emissions
Data;
2. For units that report to EIA at the unit level but not to CAMD's Power Sector Emissions
Data, we include the reported unit-level heat input from EIA; and
3. For all other units that report EIA at the plant level, we distribute prime mover-level heat
input to each unit based on that unit's proportion of nameplate capacity.
For units that report to EIA but not to CAMD's Power Sector Emissions Data (steps 2 and 3), we
estimate emissions by multiplying the heat input by the fuel-specific emission factors shown in
Appendix C.
Generally, emission sources that are included in CAMD's Power Sector Emissions Data are fossil
fuel-fired boilers and turbines serving an electric generator with a nameplate capacity greater than 25
MW and producing electricity for sale. Additionally, some sources not serving a generator or serving
a generator less than 25 MW also report to CAMD's Power Sector Emissions Data.
For units that are included in CAMD's Power Sector Emissions Data only during the ozone season,
the non-ozone season heat input is taken from the EI A-923. The non-ozone season heat input for each
included unit was distributed from the prime-mover level based on the nameplate capacity of that unit
(step 3 above). The EIA-923 distributed non-ozone season heat input is added to the ozone season
heat input from CAMD's Power Sector Emissions Data. Non-ozone season emissions for NOx are
calculated and added to the reported CAMD's Power Sector Emissions Data ozone season NOx
emissions. The emissions for CO2 and SO2 for these units are calculated using the methodology
discussed below, using the updated heat input. The heat input and emission adjustment only applies to
167 units out of the total 247 units in CAMD's Power Sector Emissions Data that reported only
during the ozone season. There are 80 units that cannot be updated to reflect annual data values due to
differences for these units in CAMD's Power Sector Emissions Data and EIA data.
CO2
As discussed above, the majority of CO2 emissions reported in eGRID2020 are monitored data from
CAMD's Power Sector Emissions Data. For units that report to EIA but not to CAMD's Power
Sector Emissions Data, or for units from CAMD's Power Sector Emissions Data where there are gaps
in CO2 emissions data, the CO2 emissions are estimated based on heat input and an emission factor.
The emission factors are primarily from the default CO2 emission factors from the EPA Mandatory
Reporting of Greenhouse Gases Final Rule (EPA, 2009, Table C-l). For fuel types that are included
in eGRID2020 but are not in the EPA Mandatory Reporting of Greenhouse Gases Final Rule,
additional emission factors are used from the 2006 Intergovernmental Panel on Climate Change
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(IPCC) Guidelines for National Greenhouse Gas Inventories and the EPA Inventory of U. S.
Greenhouse Gas Emissions and Sinks: 1990-2015 (IPCC, 2007a; EPA, 2017).
Several fuel types do not have direct reported emission factors, so emission factors from similar fuel
types are used:
The emission factor for natural gas is used to estimate emissions from process gas and other
gas;
The emission factor for anthracite, bituminous, and lignite coal are used to estimate emissions
from refined coal and waste coal; and
The emission factor for other biomass liquids is used to estimate emissions from sludge waste
and liquid wood waste.
The CO2 emissions from hydrogen, nuclear, purchased steam, solar, waste heat, water, wind, and
energy storage are considered to be zero. The CO2 emissions for units with a fuel cell prime mover
are also assumed to be zero.
A list of the CO2 emission factors used in eGRID2020 can be found in Table C-l in Appendix C.
NOx
Similar to CO2, the emissions from NOx come from monitored data from CAMD's Power Sector
Emissions Data where available.
For all other units, the NOx emissions are based on heat input multiplied by an emission factor. For
some units, EIA reports unit-level NOx emission rates (lb/MMBtu) for both annual and ozone season
emissions, from EIA Form 923, Schedule 8C. These unit-level emissions rates are multiplied by the
unit-level heat input used to estimate annual and ozone season NOx emissions. For all other units that
report to EIA but are not included in CAMD's Power Sector Emissions Data, the unit-level heat input
is multiplied by a prime mover- and fuel-specific emission factor from EPA's AP-42 Compilation of
Air Pollutant Emission Factors or the EIA Electric Power Annual (EPA, 1995; EIA, 2021f, Table A-
2).
Ozone season NOx emissions include emissions from May through September. For units where the
NOx emissions are estimated with an emission factor, theNOx ozone season emissions are based on
the emission factor multiplied by the heat input for May through September.
See Table C-2 in Appendix C for the NOx emission factors used in eGRID2020.
SO2
As with the other pollutants, emissions of SO2 are taken from monitored data from CAMD's Power
Sector Emissions Data where available.
For all other units, SO2 emissions are based on heat input multiplied by an emission factor. Unlike for
NOx, EIA does not report unit-level emissions rates for SO2. Therefore, the SO2 emissions for all
units not included in CAMD's Power Sector Emissions Data are estimated using emission factors
from EPA's AP-42 or the EIA Electric Power Annual, which are specific to fuel, prime mover, and in
the case of boilers, boiler type (EPA 1995; EIA, 2021f, Table A-l).
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For some fuels, such as coal and oil, the emission factor from AP-42 depends on the sulfur content of
the fuel. For many units, EI A reports monthly unit-level data on the sulfur content of the fuel
consumed, and these data are used with the AP-42 emission factors to estimate SO2 emissions. For
units without unit-level data on the sulfur content of fuels, the sulfur content is based on an average of
the reported sulfur contents for units that have the same prime mover and fuel type.
For some units for which we calculated SO2 emissions with an emission factor, EIA reports SO2
control efficiencies. For these units the estimated SO2 emissions are multiplied by (1 - control
efficiency) to estimate the controlled emissions. Units that do not have unit-level control efficiency
data are assumed to be uncontrolled. The control efficiencies are not used for units where the
emissions data are from CAMD's Power Sector Emissions Data, because these emissions already take
controls into account.
See Table C-3 in Appendix C for the SO2 emission factors used in eGRID2020.
Geothermal
Geothermal emissions are estimated for CO2, SO2, and NOx. While CO2 is a gas in the geothermal
reservoir, SO2 and NOx result from hydrogen sulfide combustion. The three pollutants' emission
factors, obtained from a 2007 Geothermal Energy Association environmental guide (GEA, 2007), are
applied to plant net generation, and differ depending on the type of geothermal plant as identified in
various reports from the Geothermal Energy Association (now known as Geothermal Rising) (GEA,
2016). For abinary or flash/binary geothermal plant, there are no CO2, SO2, or NOx emissions since
the plant operates a closed system; for a flash geothermal plant, there are no NOx emissions and
minimal CO2 and SO2 emissions; and for a dry steam geothermal plant, there are minimal CO2, SO2,
and NOx emissions.
See Table C-7 in Appendix C for the geothermal emission factors used in eGRID2020.
Plant File
The emissions of CO2, NOx, and SO2 in the Plant file are the sum of all unit-level emissions at a plant
from the Unit file.
3.1.1.2 Annual Emission Estimates for CH4, N20, and C02 equivalent
Emissions for CH4, N2O, and CCh-equivalent (CChe) are included in eGRID2020 at the plant level.2
The emissions for CH4 and N2O are calculated using heat input data and emission factors from the
EPA or the IPCC. The emission factors are primarily from the EPA Mandatory Reporting of
Greenhouse Gases Final Rule (EPA, 2009, Table C-l). For fuel types that are included in eGRID2020
but not in Table C-l of the EPA Mandatory Reporting of Greenhouse Gases Final Rule, additional
emission factors are used from the 2006 IPCC Guidelines for National Greenhouse Gas Inventories
and the EPAInventory of U.S. Greenhouse Gas Emissions and Sinks: 1990-2015 (IPCC, 2007a;
EPA, 2017).
2 Nitrous oxide is an oxide of nitrogen thatis not part of the NOx subset of oxides of nitrogen. N2O is a
greenhouse gas, the emissions of which are contributingto global climate change. N2O should notbe
confused with NOx.
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Several fuel types do not have direct reported emission factors, so emission factors from similar fuel
types are used:
The emission factor for natural gas is used to estimate emissions from process gas and other
gas;
The emission factor for anthracite, bituminous, and lignite coal are used to estimate emissions
from refined coal and waste coal; and
The emission factor for other biomass liquids is used to estimate emissions from sludge waste
and liquid wood waste.
The CH4 and N2O emissions for electricity used from energy storage (megawatt-hours), hydrogen,
nuclear, purchased steam, solar, waste heat, water, and wind are considered to be zero. The CH4 and
N2O emissions from units with a fuel cell prime mover are also considered to be zero.
A list of the CH4 and N2O emission factors used in eGRID2020 can be found in Table C-lin
Appendix C.
The CO2 equivalent (CChe) emissions, in tons, and total output emission rate (lb/MWh) are included
in the Plant file and subsequent aggregation files. The CChe nonbaseload output emission rate (in
lb/MWh) is included at the aggregated State, BA, NERC region, eGRID subregion, and US level in
the eGRID file. CChe emissions are calculated based on the global warming potential of CO2, CH4,
and N2O.
Global warming potential is a value assigned to a GHG so that the emissions of different gases can be
assessed on an equivalent basis to the emissions of the reference gas, CO2. Traditionally, the 100-year
GWPs are used when calculating overall CO2 equivalent emissions, which is the sum of the products
of each GHG emission value and their GWP. Based on the fourth IPCC assessment (2007) (AR4), the
GWP of CO2 is 1, CH4 is 25 and N2O is 298. When calculating the CO2 equivalent, it is important to
ensure that each of the GHG emission values has the same measurement units (i.e. either all in short
tons or all in pounds), as CO2 emissions are expressed in short tons while both CH4 and N2O
emissions are expressed in pounds in eGRID. The GWPs were updated to AR4 in eGRID2018 to
align with other EPA sources reporting CO2 equivalent emissions. Previous versions of eGRID used
the second IPCC assessment (SAR). A comparison of the GWPs for CO2, CH4, andN20 is shown in
Table 3-1 (EPA, 2017, Table 1-3; IPCC, 2007b, Table 3).
Table 3-1. Comparison of 100-Year GWPs
Gas
SAR
TAR
AR4
AR5*
CM
O
O
1
1
1
1
ch4
21
23
25
34
n20
310
296
298
298
*Note that the AR5 values include climate-carbon feedbacks
CChe emissions are calculated by taking the sum of emissions for CO2, CH4, and N2O, each multiplied
by a selected GWP factor for each gas. The following equation outlines the methodology to calculate
CChe emissions using GWP values.
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C02 e Emissions = (GWPC02) x Emissionscc>2) + (GWPCHi x EmissionsCHi) +
(GWPN20 x EmissionsN20)
An example of using AR4 GWP values is calculated as follows:
1. Use AR4 value from Table 3-1 for each selected gas:
GWPC02 = 1
GWPCH4 = 25
GWPNz0 = 298
2. Calculate the total CChe emissions for a plant with the following emissions: 5,000 tons of
CO2, 150 pounds of CH4, and 20 pounds of N2O:
C02 e emissions for C02 = 1 x (5,000 tons of C02) = 5,000 tons
( 1 ton \
CO7 e emissions for CH. = 25 x (150 pounds of CH*) x r = 1.88 tons
\2000 pounds/
( 1 ton \
CO? e emissions for N?0 = 298 x (20 pounds of N20) x = 2.98 tons
\2000 pounds/
3. Add CChe emissions together to obtain final plant emissions in CChe tons:
Total C02e Emissions = (5,000 tons) + (1.875 tons) + (2.98 tons)
Total C02 e Emissions = 5,004.86 tons
3.1.1.3 Annual Emission Estimates for Mercury
Mercury emissions are reported to CAMD's Power Sector Emissions Data at the unit-level and are
directly incorporated into the eGRID Unit file.
Mercury emissions are not summed to the Plant file since the unit-level data may not be available for
all units at a plant. While electric generating units started to report mercury data to CAMD's Power
Sector Emissions Data in 2015 under the Mercury and Air Toxics Standards (MATS), the data may
be incomplete. The unit-level emissions are included in the Unit file, but since only a portion of the
units at one plant may not list mercury emissions, they have not summed these emissions to the plant-
level. However, the fields for Hg emissions and emissions rates in the Plant file have been retained so
that these data may be included in future editions of eGRID.
3.1.2 Plant Level Adjusted Emission Estimates
Emissions reported in eGRID represent emissions from fuel utilized only for electricity generation
For certain plants, there are two possible cases for which we adjust the emission estimates: (1) if the
plant is a CHP facility; and (2) if one or more units at the plant burn biomass, including biogas (such
as landfill, methane, and digester gas). The Plant file reports both adjusted and unadjusted emissions,
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while the Unit file reports only unadjusted emissions. Due to these adjustments, the adjusted
emissions reported in eGRID may be different from emissions reported in other EPA sources.
3.1.2.1 Adjustments for Biomass
Prior editions of eGRID applied a biomass adjustment to the annual emission values based on an
assumption of zero emissions from biomass combustion. This assumes that the amount of carbon
sequestered during biomass growth equals the amount released during combustion, without
consideration of other factors. For reasons of consistency, the same approach is applied in
eGRID2020.
eGRID makes adjustments for biogas emissions, for biomass emissions other than biogas, and for
solid waste emissions for specified pollutants. Solid waste typically consists of a mixture of biogenic
materialssuch as wood, paper, and food wasteand fossil-based materialssuch as plastics and
tires. EIA-923 reports fuel consumption at plants that combust municipal solid waste (MSW) as the
biomass component (MSB) and the non-biomass component (MSN). Emissions from the biomass
component of solid waste are adjusted, while emissions from the non-biomass component of solid
waste are not adjusted. In eGRID2020, the fuel type for these plants is listed as MSW.3
The Plant file includes a biomass adjustment flag to indicate whether a biomass adjustment is made to
the annual emission values for CO2, NOx, SO2, CH4, andN20. The possible biomass adjustments to
emissions are explained below. See Table C-l in Appendix C for atable of biomass fuel types used in
the biomass adjustments to emissions in the Plant file.
For plants that have a biomass adjustment, the amount of emissions that the total emissions are
adjusted by are included in eGRID2020. The emissions adjustment values from CO2 are listed for all
plants with a biomass flag and the emissions adjustment values from NOx, SO2, CH4, and N2O are
listed for plants with a biomass flag with landfill gas. Table A-3 in Appendix A has a list of all the
new fields added to the Plant file, including the biomass emissions adjustment values. Note that for
plants that have both a biomass flag and a CHP flag, the biomass emissions adjustment value
subtracted from the unadjusted emissions value will not match the adjusted emissions value. For these
plants, the CHP adjustment value needs to be accounted for as well. See Section 3.1.2.3 below for a
sample calculation of a plant with both a biomass and CHP adjustment.
C02
The emissions from biomass combustion at a plant are subtracted from the plant's overall unadjusted
CO2 emissions. The CO2 emissions from biomass are reported at the plant level. To determine the
biomass emissions if the CHP adjustment is also flagged, the adjusted emissions value from CHP
plants must first be calculated (since the CHP plant adjustment is applied last; see Section 3.1.2.2
below).
For CAMD's Power Sector Emissions Data units with a prime mover that matches EIA-923 prime
movers that burn one or more biomass fuels, the CO2 emissions are adjusted by subtracting the
biomass CO2 emissions calculated using the corresponding EIA-923 data (EIA, 2021c). In previous
3 Previous editions of eGRID estimated the split between the biomass andnon-biomass components of MSW.
Because the EIA-923 reports these components separately, this estimation is no longernecessary.
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editions of eGRID, there were different flags for the biomass adjustment to represent different
biomass fuels or differences in the emissions data source.
NOx, S02, CH4, andN20
Emissions adjustments for NOx, SO2, CH4, and N2O emissions are only conducted for landfill gas in
eGRID. This adjustment is based on the assumption that in many cases landfills would flare the gas if
they did not combust it for electricity generation. Therefore, we assume that, at a minimum, the gas
would have been combusted in a flare and would have produced some emissions of NOx, SO2, CH4,
and N2O anyway. Similar to the CO2 adjustments, biogas adjustments are made by deducting the
emissions from landfill gas for NOx, SO2, CH4, and N2O from the overall plant total emissions. For
NOx emissions from landfill gas, an emission factor for flaring of landfill gas, 0.02 tons per MMBtu,
is used (EPA, 1995).4 See Table C-l in Appendix C for a list of CH4, andN20 emission factors and
the landfill gas (LFG) values from Table C-3 for a list of SO2 emission factors. Note that CO2 is also
adjusted for landfill gas, as described above.
3.1.2.2 Adjustments for CHP
A CHP facility is a type of generating facility that produces electricity and another form of useful
thermal energy (such as heat or steam) used for industrial, commercial, heating, or cooling purposes.
CHP, also known as cogeneration, can convert energy more efficiently than facilities that separately
produce heat and electricity. Plants in eGRID are designated as CHP facilities based on information
from the EIA-860, EIA-923, and Department of Energy Combined Heat and Power Database datasets
(EIA, 2021c; DOE, 2021). A flag indicating whether or not a plant is a CHP facility is included in the
eGRID Plant file. Since emissions reported in eGRID represent electricity generation only, emissions
associated with useful thermal outputthe amount of heat produced in a CHP facility that is used for
purposes other than making electricityare excluded from the adjusted emissions.
eGRID's CHP adjustment methodology is designed to allocate emissions for CHP plants between
electricity and thermal output. If a plant is a CHP facility, the adjustment is applied to the emissions
and heat input for the entire plant after any biomass adjustment has been made.
The methodology is based on multiplying emissions and heat input by an electric allocation factor,
which is calculated as follows:
1. Calculate the useful thermal output. EIA-923 reports both total fuel consumption and fuel
consumption for electricity generation.5 The useful thermal output value for eGRID2020 data
is calculated from EIA-923 data as 0.8 multiplied by the difference in total heat input and
electricity heat input in MMBtu. The value of 0.8 is an assumed efficiency factor from the
combustion of the consumed fuel (EIA, 2021c).
Useful Thermal Output= 0.8 x (Total Heat Input Electric Heat Input)
4 Note thatthis factor was converted from units of lb/standard cubic foot (scf) to to ns/MMBtu based ona value
of 500 Btu/scf (EPA, 2016).
5 CHP facilities do notreportthese values to EIAseparately. They only report totalfuelconsumption, andEIA
estimates the fuelconsumptionforelectricity generation.
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2. The electric allocation factor is calculated as the ratio of the electricity heat output to the sum
of the electricity and steam heat outputs, where electricity heat output is the net generation in
MWh multiplied by 3.413 to convert it to MMBtu, and steam heat output is 0.75 multiplied
by the useful thermal output, in MMBtu. The 0.75 factor is another assumed efficiency factor,
which accounts for the fact that once fuel is combusted for electricity generation,
approximately 75 percent of the useful thermal output can be utilized for other purposes, such
as space heating or industrial processes.6
3.413 x Net Generation
Electric Allocation Factor = -rr-rz-. , - :-
(0.75 x Useful Thermal Output) + (3.413 x Net Generation)
If the useful thermal output is zero, then the electric allocation factor is set to one. The electric
allocation factor should be between zero and one. If the electric allocation factor is calculated to be
greater than one, it is set to one, and if the electric allocation factor is calculated to be less than zero,
it is set to zero.
In previous editions of eGRID, the CHP adjustment methodology involved a process for estimating
the electric allocation factor in cases where a unit is listed as a CHP unit, but the total heat input and
electric heat input reported by EIA were reported as equal. In discussions with EIA, we have
determined that in these cases, there should be no CHP adjustment made. Therefore, for units listed as
CHP units, but with a total heat input equal to the electric heat input, the useful thermal output is
calculated to be 0, and the electric allocation factor is set to 1. This assumes that all of the heat input
for these units is used for electricity generation and that useful thermal output is not produced.
For plants that have a CHP adjustment, the amount of heat input and emissions that the total
emissions are adjusted by are included in eGRID2020. The emissions adjustment values from heat
input, NOx, SO2, CO2, CH4, and N2O are listed for plants with a CHP flag. Note that for plants that
have both a biomass flag and a CHP flag, the unadjusted emissions multiplied by the electric
allocation factor will not match the adjusted emissions value. For these plants, the biomass
adjustment value needs to be accounted for as well. See Section 3.1.2.3 below for a sample
calculation of a plant with both a biomass and CHP adjustment.
3.1.2.3 Plant-level adjustment example calculation
There are several plants that have both a biomass adjustment and a CHP adjustment. The following
calculation steps are used to determine the final presented CO2 adjusted emission values.
1. The biomass emissions are determined in accordance with section 3.1.2.1 and removed from
the plant unadjusted annual CO2 emissions.
UNCO2 - BI0C02 = PLC02
bio removed
6 This a ssumes thatthe CHP units generate electricity first anduse the waste heat for other purposes, also
known as "topping." While there are some units that generate and use heat first and then use the waste heat
to generate electricity, also known as "bottoming," data from the EIA shows thatthe vast majority of CHP
facilities are topping facilities.
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Where;
UNC02 = plant unadjusted annual CO2 emissions
BI0C02 = plant annual CO2 biomass emissions
PLC02bio removed plant annual CO2 emissions without biomass (intermediate value)
2. The electric allocation factor is determined in accordance with section 3.1.2.2 and the CHP
adjustment is then conducted by multiplying the biomass adjusted plant emissions by the
electric allocation factor.
PLC02bioremoved x ELALLOC = PLC02AN
Where;
PLC02bio removed plant annual CO2 emissions without biomass (intermediate value)
ELALLOC = electric allocation factor (see section 3.1.2.2)
PLC02AN = plant annual CO2 emissions (biomass and CHP adjusted)
3. The amount of CHP adjusted emissions are determined by subtracting the final adjusted plant
emissions from the plant annual CO2 biomass emissions.
PLC02bioremoved PLC02AN = CHPC02
Where;
PLC02bio removed plant annual CO2 emissions without biomass (intermediate value)
PLC02AN = plant annual CO2 emissions (biomass and CHP adjusted)
CHPC02 = plant annual CO2 emissions CHP adjustment value
Table 3-2 and the following equations show an example calculation of how the adjustments are done
together.
Table 3-2. Example Biomass and CHP CO2 Emissions Adjustment Calculation
Plant Name
Fuel
ELALLOC
UNC02
(tons)
BIOC02
(tons)
CHPC02
(tons)
PLC02AN
(tons)
Example Plant
OBG
0.1989
75,817
65,289
8,434
2,094
1. 75,817 tons 62,289 tons = 10,528 tons
2. 10,528 tons x 0.1989 = 2,094 tons
3. 10,528 tons 2,094 tons = 8,434 tons
3.1.3 Emission Rate Estimates
Input and output emission rates are calculated for eGRID at the plant level in the Plant file, and the
subsequent aggregated files. Annual and ozone season net generation and heat input values (adjusted
for CHP plants) are required to calculate the emission rates.
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3.1.3.1 Generation
Net generation, in MWh, is the amount of electricity produced by the generator and transmitted to the
electric grid. Net generation does not include any generation consumed by the plant. If generation
consumed by the plant exceeds the gross generation of that plant, negative net generation will result.
In these cases, the output emissions rates are set to 0, rather than report a negative emissions rate.
Generator-level net generation as well as prime mover-level net generation is obtained from the EIA-
923. Ozone season generation is calculated by summing up the generation for the months of the ozone
season, May through September (EIA, 2021c).
The methodologies employed for obtaining year 2020 net generation data are described below.
Generator-Level Net Generation
The EIA-923 dataset reports generator-level generation for a subset of generators. This generator-
level generation is reported in the Generator File in eGRID2020. For all other generators, which do
not have data on generator-level generation, prime mover-level net generation is distributed to the
generators in the Generator file based on the proportion of nameplate capacity of generators with that
prime mover at a given plant. Ozone season net generation uses the same methodology, but only
includes generation data for May to September. Annual and ozone season generation is distributed to
generators with a status of operating, standby/backup, out of service but was operating for part of the
data year, or retired if the retirement year is 2020. Generation is not distributed to generators if the
generator is not yet in operation or retired before 2020.
In some cases the sum of the generator-level generation does not equal the plant-level generation,
even if all generator-level generation is available for all generators. In order to ensure that the
generation in eGRID matches the plant-level generation data from EIA, distributed prime mover-level
data are used in some cases in place of generator-level generation data.
As explained above, some generator-level net generation data are missing or not reported for various
generators in the 2020 EIA-923. EIA aggregates these missing data to the state level by fuel type, but
it is not possible to distribute them back to the generator level accurately (EIA, 2021c).
Plant-Level Net Generation
The annual generation data in the Plant file are the sum of all generator-level generation at the plant
from the Generator file. The ozone season generation data in the Plant file are a sum of all ozone
season (May-September) generator-level generation at the plant from the Generator file.
Combustion net generation is also developed (as is non-combustion generation) based on the fuel type
generation of each plant. For plants that are only composed of combustion generating units, the plant
combustion net generation is the same as the total plant net generation. For plants that have both
combustion and non-combustion generating units, the combustion net generation will be less than the
total net generation for that plant.
3.1.3.2 Heat Input
Heat input, in MMBtu, is the amount of heat energy consumed by a generating unit that combusts
fuel. The method for assigning unit-level heat input follows the same process as the method for
assigning unit-level CO2 emissions (see section 3.1.1.1). Annual and ozone season unit-level heat
input for eGRID is initially obtained from the reported emissions data from CAMD's Power Sector
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Emissions Data. The heat input from CAMD's Power Sector Emissions Data is based either on stack
flow and CO2/O2 monitoring or fuel flow and the heat content of fuel.
If unit level heat input data from CAMD's Power Sector Emissions Data are not reported or the
overall plant is not included in CAMD's Power Sector Emissions Data, annual and ozone heat input
data are obtained at the unit level or prime mover level from the EIA-923 monthly data (EIA, 2021c).
For units that only report ozone season heat input to CAMD's Power Sector Emissions Data, a
methodology is used to add the additional heat input for non-ozone season months from the EIA-923
(see discussion in Section 3.1.1.1). Note that units that retired in the year 2020 may have operated for
part of the year and can have positive heat input.
The Unit file unit level heat input is summed to the plant level and reported in the Plant file.
3.1.3.3 Emission Rates
Output, input, and combustion emission rates are reported in the Plant, State, Balancing Authority,
eGRID Subregion, NERC Region, and US eGRID files. The fuel-based and nonbaseload emission
rates are reported in the State, Balancing Authority, eGRID Subregion, NERC Region, and US
eGRID files.
Output and Input Emission Rates
Output emission rates for SO2, NOx, CO2, C02e, CH4, and N2O in lb/MWh, are reported in the Plant
file. The output emission rates are calculated as total annual adjusted emissions divided by annual net
generation.
Input emission rates for SO2, NOx, CO2, C02e, CH4, and N2O in lb/MMBtu, are calculated as the total
annual emissions divided by the annual heat input.
Fuel-based Emission Rates
For the State, Balancing Authority, eGRID Subregion, NERC Region, and US eGRID files, coal, oil,
gas, and fossil fuel output and input emission rates are calculated based on a plant's primary fuel (see
Section 3.2). If a plant's primary fuel is coal, oil, gas, or another fossil fuel, then all of its adjusted
emissions, adjusted heat input, and net generation from combustion are included in the respective
aggregation level for that fuel category. For example, all plants in Alabama with coal as primary fuel
will have their emissions, heat input, and combustion net generation summed to the state level and
then the appropriate calculations will be applied to determine the coal-based output and input
emission rates for Alabama. See Table 3-3 for a list of primary fuels and fuel categories used for fuel-
based emission rates in the State, Balancing Authority, eGRID Subregion, NERC Region, and US
eGRID files.
Table 3-3. Fuel-based Emission Rates - Primary Fuel Category
Fuel Code
Description
Fuel Category
BIT
Bituminous coal
Coal
LIG
Lignite coal
Coal
SUB
Subbituminous coal
Coal
RC
Refined coal
Coal
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Fuel Code
Description
Fuel Category
WC
Waste coal
Coal
SGC
Coal-derived synthetic gas
Coal
COG
Coke oven gas
Coal
NG
Natural gas
Gas
BU
Butane gas
Gas
DFO
Distillate fuel oil
Oil
JF
Jet fuel
Oil
KER
Kerosene
Oil
PC
Petroleum coke
Oil
RG
Refinery gas
Oil
RFO
Residual fuel oil
Oil
WO
Waste oil
Oil
BFG
Blast furnace gas
Other fossil
OG
Other gas
Other fossil
TDF
Tire-derived fuel
Other fossil
NonbaseloadEmission Rates
In addition to emission rates for all plants, eGRID also reports emission rates for nonbaseload plants
in the State, Balancing Authority, eGRID Subregion, NERC Region, and US eGRID files. The
nonbaseload emission rates are sometimes used as an estimate to determine the emissions that could
be avoided through projects that displace marginal fossil fuel generation, such as energy efficiency
and/or renewable energy.
Capacity factor is used as a surrogate for determining the amount of nonbaseload generation and
emissions that occur at each plant. While there are other factors that can influence a particular unit's
capacity factor besides dispatch or load order (e.g. maintenance and repairs), capacity factor is used
as a surrogate for dispatch-order for this calculation. The nonbaseload information is published in
eGRID at the aggregate level (state, balancing authority, eGRID subregion, NERC region, and the
US), but not for individual plants.
The nonbaseload emission rates are determined based on the plant-level capacity factor. All
generation and emissions at plants with a low capacity factor (less than 0.2) are considered
nonbaseload and are assigned a nonbaseload factor of 1. Plants with a capacity factor greater than 0.8
are considered baseload and are assigned a nonbaseload factor of 0. For plants with a capacity factor
between 0.2 and 0.8, we use a linear relationship to determine the percent of generation and emissions
that is nonbaseload:
Nonbaseload Factor = 5/3 x (Capacity Factor) + 4/3
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To aggregate the nonbaseload generation and emissions, the plant-level generation and emissions are
multiplied by the nonbaseload factor and summed to the state, balancing authority, eGRID subregion,
NERC region, and US levels. The aggregated nonbaseload emissions and generation are used to
calculate the nonbaseload output emission rates.
While nonbaseload rates can be used to estimate the emissions reductions associated with projects
that displace electricity generation, such as energy efficiency and/or renewable energy, these rates
should not be used for assigning an emission value for electricity use in carbon-footprinting exercises
or GHG emissions inventory efforts. Rather, eGRID subregion-level total output emission rates are
recommended for estimating emissions associated with electricity use (scope 2 emissions).
Note that generation from renewable fuels is not included in the nonbaseload calculations.
Combustion Emission Rates
Combustion output emission rates for all pollutants are estimated at the plant level and higher levels
of aggregation. Combustion fuel-based output emissions rates are calculated by dividing total plant
emissions by the combustion net generation for that plant. Generation from non-combustion sources,
such as nuclear, hydro, geothermal, solar, and wind will not be included in the calculation of this rate.
3.2 Determination of Plant Primary Fuel
The primary fuel of a plant is determined solely by the fuel that has the maximum heat input in the
Unit file.
For plants that do not consume any combustible fuel, the primary "fuel" is determined by the
nameplate capacity of the units at the plant. The fuel from the unit with the highest nameplate
capacity is used as the primary fuel.
See Section 5 for a description of all possible unit and plant primary fuel codes.
The EIA-923 includes solid waste plants as two fuel codes: municipal solid waste - biomass (MSB)
and municipal solid waste - non-biomass (MSN). The EIA-860 only lists municipal solid waste under
one code (MSW). In eGRID2020 the MSW fuel code is the only fuel code used for municipal solid
waste in the Unit, Generator, and Plant files. While the MSB/MSN EIA-923 fuel information is used
to calculate biomass adjusted emissions, these fuel codes are not listed in eGRID2020. See Section
3.1.2.1 for a discussion of the biomass adjustment methodology (EIA, 2021c).
3.3 Estimation of Resource Mix
The resource mix is the collection of nonrenewable and renewable resources that are used to generate
electricity for a plant. Nonrenewable resources include fossil fuels (e.g., coal, oil, gas, and other
fossil) and nuclear energy sources; renewable energy resources include biomass, solar, wind,
geothermal, and hydro. The resource mix is determined by calculating the percentage of the total
generation that a given nonrenewable or renewable resource generated. In eGRID, the resource mix is
represented as generation, in MWh, for each nonrenewable or renewable resource category, as well as
a percentage of the total. Each category for nonrenewable and renewable resources should sum to be
100 percent. eGRID plant resource mix and net generation are derived from the EIA-923 prime
mover level data.
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For cases in which there is only one fuel and its generation is negative, that fuel's generation percent
is assigned 100%. For cases in which there are fuels with both negative and positive net generation,
the generation percentages only include the positive generation in both the denominator and
numerator.
For the three grouped aggregate categoriestotal net generation from nonrenewables, total net
generation from all renewables, and total net generation from renewables minus hydrothe sum of
the total net generation from nonrenewables and from all renewables equals the total net generation.
It should be noted that there are cases where the sum of the generation by fuel type does not equal the
value reported for total annual generation in eGRID. This is because the total annual generation is
calculated using a mix of generator- and prime mover-level data from the EIA-923. The calculation of
generation by fuel type uses only prime mover-level data (EIA, 2021c).
3.4 Aggregating Plant-Level Data
eGRID includes five aggregated files based on the Plant file: State, Balancing Authority (BA),
eGRID Subregion, NERC Region, and the US. The State file data are developed by summing up the
Plant file data (adjusted heat input, adjusted emissions, adjusted fuel-based emissions, net generation,
fuel-based net generation, nameplate capacity, and the plant data values needed to calculate
nonbaseload emission rates), based on the state in which the plant is located. The Balancing
Authority, eGRID Subregion, and NERC Region files are developed by summing up the plant data
for each of the values for each aggregation level. The US file is developed by taking the sum of all
fields for all plants from the Plant file.
Emission rates are recalculated at the state, balancing authority, eGRID subregion, NERC region, and
US levels. Nonbaseload emission rates have also been included at the aggregated level. For a list of
all variables included in the aggregated files, see Sections 5.4 through 5.8.
The totals from the Plant, State, Balancing Authority, eGRID Subregion, NERC Region, and US
files' adjusted heat input, adjusted emissions, adjusted fuel-based emissions, net generation, fuel-
based net generation, and nameplate capacity data are equal, accounting for minor differences due to
rounding.
The following sections describe three of the levels of aggregation used to summarize the data from
the Plant file, including the balancing authority, eGRID subregion, and NERC region levels.
3.4.1 Balancing Authority
A balancing authority is a portion of an integrated power grid for which a single dispatcher has
operational control of all electric generators. A balancing authority is the responsible entity that
integrates resource plans ahead of time, maintains demand and resource balance within a BA area,
and supports interconnection frequency in real time. The balancing authority dispatches generators in
order to meet an area's needs and can also control load to maintain the load-generation balance.
Balancing authority ID codes are assigned to a plant based on the EIA-860 plant-level data and the
balancing authority names are assigned to the corresponding balancing authority ID codes based on
the EIA-861 (EIA, 2021a; EIA, 2021d). In Alaska, Hawaii, and Puerto Rico, isolated electric utility
systems, which are not part of an integrated power grid, have been grouped into nominal balancing
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authorities titled Alaska Miscellaneous, Hawaii Miscellaneous, and Puerto Rico Miscellaneous,
respectively. These three balancing authorities have an ID code of "NA" since there are no ID codes
available from EIA for these regions. Other plants with no listed balancing authority ID in the EIA-
860 plant-level data have a code of "NA" and name of "No Balancing Authority" in eGRID2020.
The balancing authority associated with a plant is reported to the EIA-860 plant-level data and used in
eGRID2020.
Since BAs are not strictly geographically based, shapefiles for mapping them are not available with
eGRID2020.
3.4.2 eGRID Subregion
eGRID subregions are identified and defined by EPA and were developed as a compromise between
NERC regions (which EPA felt were too big) and balancing authorities (which EPA felt were
generally too small). Using NERC regions and balancing authorities as a guide, the subregions were
defined to limit the import and export of electricity in order to establish an aggregated area where the
determined emission rates most accurately matched the generation and emissions from the plants
within that subregion.
A map of the eGRID subregions used for eGRID2020 is included in Appendix B. This map is
representational and shows approximate boundaries that are based on electrical grid attributes, not on
strict geographical boundaries.7
The 27 eGRID subregions are subsets of the NERC regions as configured in December 2010. The
eGRID subregions themselves have not changed substantially since eGRID2000. Note, however, that
some plants operating in each eGRID subregion can change from year to year. A new subregion,
Puerto Rico Miscellaneous (PRMS), was added in eGRID2019 with the addition of Puerto Rico data.
Plants are assigned to eGRID subregions in a multi-step process using NERC regions, balancing
authorities (BAs), Transmission IDs, Utility IDs, and NERC assessment data as a guide.
First, there is one NERC region that is located entirely within an eGRID subregion. Plants in
NERC regions TRE (within eGRID subregion ERCT) are directly assigned the corresponding
eGRID subregion.
Second, plants in BAs where the entire BA is located within the boundaries of an eGRID
subregion are assigned accordingly (e.g., BA CISO is entirely within the boundaries of
eGRID subregion CAMX).
Third, the Transmission or Distribution System Owner ID for each plant, reported in the EIA-
860, in combination with their BA, is used to identify eGRID subregions for the remaining
BAs that do not have a one-to-one match with an eGRID subregion.
7 Note that some areas may fall into multiple eGRID subregions dueto thefactthatthey are supplied by
multiple electricity providers. Visit Power Profiler (https://www.epa.gov/egrid/power-profilef) formore
information on determining the eGRID subregionfora given area.
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Fourth, there are some plants that do not report Transmission ID or where the Transmission
ID and BA span multiple eGRID subregions so an additional step using Utility ID, reported
in the EI A-860, is used to identify additional eGRID subregion matches.
The last step in the process uses Long Term Reliability Assessment data, received from
NERC, to assign additional plants to eGRID subregions based on their NERC assessment
area.
After completing these five steps, there may be a few plants that were not assigned to an eGRID
subregion. If the plant is operational (and not retired or proposed with no heat input, generation, or
emissions data), the historical assignments were retained for these plants, if applicable. For
unassigned plants that were new plants in 2020, manual assignments were made based on the plant's
physical location. All of the plants in Puerto Rico were assigned to the PRMS eGRID subregion.
The 27 eGRID subregion names and their acronyms for eGRID are displayed in Table 3-4.
Table 3-4. eGRID Subregion Acronym and Names for eGRID
eGRID Subregion
eGRID Subregion Name
FRCC
FRCC All
MROE
MRO East
MROW
MRO West
NEWE
NPCC New England
NYCW
NPCC NYC/Westchester
NYLI
NPCC Long Island
NYUP
NPCC Upstate NY
PRMS
Puerto Rico Miscellaneous
RFCE
RFC East
RFCM
RFC Michigan
RFCW
RFC West
SRMW
SERC Midwest
SRMV
SERC Mississippi Valley
SRSO
SERC South
SRTV
SERC Tennessee Valley
SRVC
SERC Virginia/Carolina
SPNO
SPP North
SPSO
SPP South
CAMX
WECC California
NWPP
WECC Northwest
RMPA
WECC Rockies
AZNM
WECC Southwest
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eGRID Subregion
eGRID Subregion Name
ERCT
ERCOT All
AKGD
ASCC Alaska Grid
AKMS
ASCC Miscellaneous
HIOA
HICC Oahu
HIMS
HICC Miscellaneous
3.4.3 NERC Region
NERC region refers to a region designated by the North American Electric Reliability Corporation
(NERC). Each NERC region listed in eGRID represents one of nine regional portions of the North
American electricity transmission grid: six in the contiguous United States, plus Alaska, Hawaii, and
Puerto Rico (which are not part of the formal NERC regions, but are considered so in eGRID). Note
that some plants can change NERC region from year to year. The nine NERC region names and their
acronyms for eGRID are displayed in Table 3-5.
Although some NERC regions include portions of Canada and/or Mexico that are integrated with
U. S. grids, eGRID aggregation data are limited to generation within the U. S.
A representation of the NERC region map used for eGRID is included in Figure B-2 in Appendix B.
This map is representational and shows approximate boundaries that are not based on strict
geographical boundaries.
Table 3-5. NERC Region Acronym and Names for eGRID
NERC Region
NERC Name
AK
Alaska
HI
Hawaii
MRO
Midwest Reliability Organization
NPCC
Northeast Power Coordinating Council
PR
Puerto Rico
RFC
Reliability First Corporation
SERC
SERC Reliability Corporation
TRE
Texas Regional Entity
WECC
Western Electricity Coordinating Council
Note that asof 2019, FRCC was no longera NERC region (FERC, 2019)
Note that asof 2020, ASCC and HICC were no longer included as NERC
regions in the ElAdata.
3.5 Grid Gross Loss
eGRID output emission rates do not account for any line losses between the points of consumption
and the points of generation. For example, because there are line losses, one kilowatt hour of
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electricity consumption requires a little more than one kilowatt hour of electricity generation. To
account for transmission and distribution line losses when applying eGRID output emission rates to
electricity consumption within a certain region, consumption is divided by (one minus the grid gross
loss [as a decimal]) (Table 3-6).
The methodology for calculating grid gross loss uses data from EIA's State Electricity Profiles.8
Utilities report the information used in these calculations directly to EIA through EIA-861. EIA does
not include Puerto Rico in their State Electricity Profiles, so Puerto Rico is not included in the grid
gross loss estimates for eGRID2020.
To align more closely with EIA estimates, the methodology for calculating GGL changed slightly in
2017. The previous methodology used for eGRID2014 and eGRID2016 did not account for interstate
trade values that were included in total disposition for each state, which led to a slight double
counting of values. The revised methodology excludes net exports from each state's total disposition.
The formula for calculating GGL remains nearly the same as the previous methodology, with the
exception that net interstate exports are subtracted from the total disposition in the denominator.
The methodology for estimating grid gross loss uses the following data points for each state from the
EIA State Electricity Profiles:
1. Total Disposition. This is the total amount of electricity sold directly to customers, sold for
resale, furnished without charge, consumed by the respondent without charge, and lost. It is
equal to the total amount of electricity generated.
2. Net Interstate Exports. This is the total amount of electricity exported to other states.
3. Direct Use. This is the total amount of electricity used by plants and/or utilities in the region
that is not sold for wholesale or resale; direct use electricity is not transmitted through the
grid and therefore does not have the potential to be lost.
4. Estimated Losses. This is the total amount of electricity, in MWh, in the region that is
generated but is not sold for resale or wholesale, furnished without charge, or used by the
generator or utility; i. e., electricity that is lost in transmission and distribution.
These data are reported at the state level by EIA. We aggregate them to the NERC Interconnect level
(Eastern, Western, ERCOT (Texas), as well as the states of Alaska and Hawaii, and the entire U. S.).
State boundaries, however, do not perfectly correspond to Interconnect boundaries. Four states
(Montana, Nebraska, New Mexico, and South Dakota) have generation in two Interconnects, and one
state (Texas) has generation in three Interconnects. For these states, we distributed the data from the
State Electricity Profiles based on the proportion of generation from these states in each Interconnect
from the EIA-923 (EIA, 2021c).
The aggregated data are then used to calculate grid gross loss as follows:
Estimated Losses
Grid Gross Loss =
Total Disposition without Exports Direct Use
8 Available at: http://www.eia.gov/electricity/state/See Table 10: Supply and disposition of electricity
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The eGRID2020 estimated grid gross loss percentages for each U.S. interconnect power grid are
included in the worksheet called ""GGL20" in the eGRID workbook and are also displayed in Table
3-6.
Table 3-6. eGRID2020 Grid Gross Loss (%)
Power Grid
Grid Gross Loss (%)
Eastern
5.3%
Western
5.3%
ERCOT
5.2%
Alaska
5.5%
Hawaii
5.6%
U.S.
5.3%
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4. Specific eGRID Identifier Codes, Name Changes, Associations,
and Data Updates
4.1 Plant Level
4.1.1 Plant ID Changes
Some changes to EIA ORISPL ID codes are made in eGRID2020 to better reflect CAMD's Power
Sector Emissions Data.
Some EIA plants are combined into single plants to reflect CAMD's Power Sector Emissions Data.
The plants ArcelorMittal Indiana Harbor West and Indiana Harbor E 5 AC Station (ORISPL
10397 and 54995, respectively) are combined and the ORISPL changed to 10474 to match
with the ArcelorMittal USA - Indiana Harbor East plant from CAMD's Power Sector
Emissions Data.
The plants Sundevil Power Holdings - Gila River and Gila River Power Block 3 (ORISPL
59338 and 59784, respectively) are combined and the ORISPL changed to 55306 to match
with the Gila River Power Station plant from CAMD's Power Sector Emissions Data.
The plants Wayne County and Lee Combined Cycle Plant (ORISPL 7538 and 58215,
respectively) are combined and the ORISPL changed to 2709 to match with the H F Lee
Steam Electric Plant from CAMD's Power Sector Emissions Data.
Some plants in CAMD's Power Sector Emissions Data are combined into single plants to reflect EIA
data.
The plants Frank M Tait Station and Tait Electric Generating Station (ORISPL 2847 and
55248, respectively) in CAMD's Power Sector Emissions Data are listed as one plant, Tait
Electric Generating Station (ORISPL 2847), in EIA data. This plant was previously listed
under both ORISPL ID codes in EIA. For eGRID2020 we have updated the ORISPL ID
codes for this plant in CAMD's Power Sector Emissions Data so they are listed as one plant,
matching the EIA update.
A table of ORISPL ID code changes can be found in Table C-5 in Appendix C.
4.1.2 Generator/Unit ID Changes
Some changes to EIA generator IDs were made due to duplicate generator IDs showing up in
eGRID2020 after changes to Plant IDs were made (see Section 4.1.1 above).
Three generator IDs for retired generators at the H F Lee Steam Electric Plant (ORISPL
2709) were changed from 1, 2, and 3 to 01, 02, and 03 to remove duplicate generator IDs.
Three generator IDs for generators at the V H Braunig (ORISPL 3612) were changed from 1,
2, and 3 to 01, 02, and 03 to remove duplicate generator IDs.
Some changes to CAMD's Power Sector Emissions Data Unit ID codes are made in eGRID2020
when renewable fuel units from EIA data have matching Unit ID codes.
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The CAMD's Power Sector Emissions Data Unit ID codes from the Blewett plant (ORISPL
2707) were changed. There are 4 renewable units from EIA that had the same Unit ID codes,
so the Unit ID codes from CAMD's Power Sector Emissions Data were changed to match the
corresponding EIA Unit ID codes (from 1, 2, 3, and 4 to GT1, GT2, GT3, and GT4).
4.1.3 Longitude/Latitude Updates
The following plants had the wrong latitude and longitude listed in the EIA-860 Plant file. The
following updates, shown in Table 4-1, have been made based on the address provided in the EIA-
860 Plant file for each plant.
Table 4-1. eGRID2020 Latitude/Longitude Updates
Plant ID
Plant Name
Latitude
Longitude
1091
George Neal North
42.325814
-96.381184
54975
New Mexico State University
32.280032
-106.753716
62262
Rolling Upland Wind Farm LLC
42.899029
-75.458456
63003
Midland Wind
41.000000
-89.996844
64850
Wilkes Solar, LLC
36.169000
-81.042000
4.1.4 EPA/CAMD Plants Not Connected to the Grid
There are several plants included in CAMD's Power Sector Emissions Data that are not connected to
the electric grid and are therefore removed from eGRID2020. All plants that have an ORISPL code
that starts with an 88 followed by four digits are not included in eGRID2020. Not all non-grid-
connected facilities follow this practice. Table 4-2 below provides a list of plants that have been
removed from eGRID2020 that do not have an ORISPL code beginning with 88.
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Table 4-2. eGRID2020 EPA/CAMD Plants Not Connected to the Grid
Plant ID
State
Plant Name
478
CO
Zuni
1594
MA
Blackstone
2440
SC
AbiBow US Inc. - Catawba Operations
2549
NY
Huntley Power
10071
VA
Virginia Renewable Power-Portsmouth LLC
10111
Ml
DTE Pontiac North LLC
10381
NC
Coastal Carolina Clean Power LLC
10675
CT
AES Thames
10788
WV
Chemours Belle Plant
50044
OH
The Ohio State University
50151
WV
UCC South Charleston Plant
50202
NY
Niagara Generation, LLC
50247
OH
Smart Papers LLC
50607
PA
Veolia Energy Philadelphia - Schuylkill
54035
NC
Roanoke Valley Energy Facility I
54571
PA
North East Cogeneration Plant
54755
NC
Roanoke Valley Energy Facility II
55098
IX
Frontera Generation Facility
55422
FL
Desoto County Energy Park
55703
TN
Valero Refining Company-Tennessee, LLC
4.1.5 Net Generation Updates
There was one plant, the Georgetown plant (ORIS 7759) in Indiana, that had the wrong net generation
values reported to the EIA-923 for 2020. EI A provided EPA with updated net generation data for this
plant prior to the data being updated on their website. This updated net generation data for this plant
is what was used in eGRID2020. See Table 4-3 below for a comparison of the net generation data
provided in the EIA-923 to the values we used in eGRID2020.
Table 4-3. eGRID2020 Net Generation Updates for Georgetown Plant (ORIS 7759)
EIA-923 Reported Data
(MWh)
Updated Data Used in
eGRID2020 (MWh)
98.526
214.590
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DESCRIPTION OF DATA ELEMENTS
5. Description of Data Elements
eGRID2020 has 8 aggregation files: UNIT (unit), GEN (generator), PLNT (plant), ST (state), BA
(Balancing Authority), SRL (eGRID subregion), NRL (NERC region), and the US (United States
total). eGRID2020 also includes the regional grid gross loss factor data. Appendix A provides the file
structure for eGRID2020, which includes variable descriptions and original data sources. Note that
definitions for similar variables are not repeated after the description in the Plant file. For example, in
the Plant file, the net generation in MWh is defined at the plant level for the data element
PLNGENAN. For each subsequent file, the net generation, XXNGENAN (where XX is ST, BA, SR,
NR, or the US) is not defined; it is simply the sum of PLNGENAN attributed to the aggregation
entity.
Note that values reported as 0 in eGRID are reported as 0 in the original data files. Values reported as
blank in eGRID are either reported as blank in the original data files or are not included in the original
data files. The following data element descriptions apply to fields in both the English unit and metric
unit workbooks, but the descriptions below only are only represented in English units.
5.1 The UNIT (Unit) File
There are 32 variables in the Unit file, which contains unit-level data.
1. eGRID2020 Unit File Sequence Number (SEQUNT20) -
Unit-level records in the 2020 data file are sorted by state abbreviation, plant name,
plant code, and unit ID, and are assigned a unique sequential number beginning with
1. This sequence number is unlikely to be the same as the sequence number in the
eGRID2019 file for the same entity.
2. Data Year (YEAR) -
The current eGRID data year.
3. Plant State Abbreviation (PSTATABB) -
The state abbreviation of the state in which the plant is located.
Source: EIA-860
4. Plant Name (PNAME) -
The name associated with each plant.
Source: EPA/CAMD; EIA-860
5. DOE/EIA ORIS Plant or Facility Code (ORISPL) -
This plant code corresponds to PNAME and was originally developed for power
plants by the Office of Regulatory Information Systems (ORIS), which was apart of
the Federal Power Commission. It is now assigned by EIA and is used as a unique
plant identification code for many EPA electric power databases. Note that some EIA
ORISPL ID codes were changed to reflect CAMD's Power Sector Emissions Data
ORISPL ID codes. See Section 4.1 for a discussion of ORISPL ID changes made to
eGRID2020. See Appendix C for a table of all ORISPL changes made between EIA
and CAMD's Power Sector Emissions Data.
Source: EPA/CAMD; EIA-860
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DESCRIPTION OF DATA ELEMENTS
6. Unit ID (UNITID) -
The unit ID for the unit that produces the emissions.
Source: EPA/CAMD, EIA-923
7. Prime Mover (PRMVR) -
The unit's electric prime mover type.
Possible values are:
BA
= Battery energy storage
BT
= Binary cycle turbine
CA
= Combined cycle steam turbine
CC
= Combined cycle -totalunit
CE
= Compressed air energy storage
CP
= Concentrated solarpower energy storage
CS
= Combined cycle - single shaft
CT
= Combinedcycle combustion turbine
FC
= Fuel cell
FW
= Flywheel energy storage
GT
= Combustion (gas) turbine
HA
= Hydrokinetic turbine - axialflow
HY
= Hydroelectric turbine
IC
= Internal combustion engine (diesel)
OT
= Other turbine
PS
= Hydraulic turbine - reversible (pumped storage)
PV
= Photovoltaic
ST
= Steam turbine (boiler, nuclear, geothermal, and solar steam)
WS
= Wind turbine - offshore
WT
= Wind turbine - onshore
Source: EIA-860
8. Unit Operational Status (UNTOPST) -
The unit's operational status in 2020. Possible values are:
CN = Cancelled (previously reportedas "planned")
CO = New unit under construction
Future = Planned new generator
IP = Planned new generator canceled, indefinitely postponed, orno longerin
resource plan
L = Regulatory approvals pending (notunder construction)
OA = Out of service (returned or will be returned to service)
OP = Operating- in service
OS = Out of service (not expected to be returned to service)
OT = Other
P = Planned for installation but regulatory approvals notinitiated (not under
construction)
RE = Retired - no longer in service
SB = Stand-by (long-term storage)
SC = Cold stand-by (reserve); deactivated
T = Regulatory approvals received (notunder construction)
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DESCRIPTION OF DATA ELEMENTS
TS = Testing, construction complete, butnotyetin commercial operation
U = Underconstruction,lessthan50%constructed
V = Under construction, more than 50% constructed
Source: EPA/CAMD, EIA-860
9. Clean Air Markets Division (CAMD) Program Flag (CAMDFLAG) -
Indicates if the unit was included in CAMD's Power Sector Emissions Data in 2020.
See https://www. epa. gov/airmarkets/programs for additional information.
Source: EPA/CAMD
10. Program Codes (PRGCODE) -
The programs, as reported to CAMD's Power Sector Emissions Data, that the unit
was subject to in 2020. Values may be combined and separated by commas. The
individual values are:
ARP
CSNOX
CSOSGl,CSOSG2
CSS02G1,CSS02G2
MATS
NHNOX
NSPS4T
RGGI
SIPNOX
TXS02
= Acid Rain Program
= Cross-State Air Pollution Rule forNOx (annual)
= Cross-State Air Pollution Rule NOx Ozone Season Program
(Group 1, Group 2)
= Cross-State Air Pollution Rule for SO2 (Group 1, Group 2)
= Mercury and Air Toxics Standards
= New Hampshire's specialNOx program
= New Source Performance Standards Subpart TTTT Program
= Regional Greenhouse Gas Initiative
= NOx SIP CaU
= Texas S02TradingProgram
See https://www. epa. gov/airmarkets/pro grams for additional information.
Source: EPA/CAMD
11. Unit Bottom and Firing Type (BOTFIRTY)
The unit firing type.
Possible values are:
ARCH
CC
CELL
CT
CYCLONE
DUCTBURNER
ENGINE
FLUIDIZED
bed)
IGC
KILN
OTHER BOILER
OTHER TURBINE
= Blank
= Arch-fired boiler
= Combined cycle
= Cell
= Combustionturbine
= Cyclone firing
= Ductburner
= Internal combustion engine
= Fluidized bed firing (circulating, bubbling, orpressurized fluidized
= Integrated gasification combined cycle
= CementKiln
= Otherboiler
= Other turbine
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DESCRIPTION OF DATA ELEMENTS
PROCESS
STOKER
TANGENTIAL
TURBO
VERTICAL
VERTICAL/ARCH
WALL
= Refinery process heater
= Stoker, spreader, vibrating grate, or slingerboiler
= Tangential, concentric, or corner-fired boiler
= Turbo
= Vertically-fired boiler
= Vertical or arch firing
= Wall-fired boiler
Source: EPA/CAMD, EIA-860
12. Number of Associated Generators (NUMGEN) -
The number of generators associated with each EIA-860 boiler in the file.
Source: EIA-860
13. Unit Primary Fuel (FUELU1) -
The primary fuel determined from EIA-923 boiler or generator reported data or the
primary fuel reported to CAMD's Power Sector Emissions Data.
Possible values are:
AB
= Agricultural by pro duct
BFG
= Bla st furnace gas
BIT
= Bituminous coal
BLQ
= Black liquor
COG
= Coke oven gas
DFO
= Distillate fueloil, light fueloil, dieseloil
GEO
= Geothermal
H
= Hydrogen
JF
= Jet fuel
KER
= Kerosene
LFG
= Landfill gas
LIG
= Lignite coal
MSW
= Municipal solid waste
MWH
= Electricity used for energy storage (megawatthour)
NG
= Natural gas
NUC
= Nuclear
OBG
= Otherbiomass gas (digester gas, methane, andotherbiomass gases)
OBL
= Otherbiomass liquids
OBS
= Otherbiomass solid
OG
= Other gas
OTH
= Other
PC
= Petroleum coke
PG
= Gaseous propane
PRG
= Process gas
PUR
= Purchased steam
RC
= Refined coal
RFO
= Residualfueloil, heavy fueloil, petroleum
SGC
= Coal-derived synthetic gas
SLW
= Sludge waste
SUB
= Subbituminouscoal
SUN
= Solar
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DESCRIPTION OF DATA ELEMENTS
TDF
= Tire-derived fuel
WAT
= Water
WC
= Waste coal
WDL
= Wood, wood waste liquid
WDS
= Wood, wood waste solid
WH
= Waste heat
WND
= Wind
WO
= Waste oil
Source: EPA/CAMD, EIA-923, EIA-860
14. Unit Operating Hours (HRSOP) -
The number of hours that a unit from CAMD's Power Sector Emissions Data
reported operating during the year.
Source: EPA/CAMD
15. Unit Unadjusted Annual Heat Input (HTIAN) -
The unit's unadjusted annual total heat input, in MMBtu, based on the values
reported to CAMD's Power Sector Emissions Data or calculated using EIA-923 unit
data.
Source: EPA/CAMD; EIA-923
16. Unit Unadjusted Ozone Season Heat Input (HTIOZ) -
The unit's unadjusted ozone season (May through September) heat input, in MMBtu,
based on the values reported to CAMD's Power Sector Emissions Data or calculated
using EIA-923 unit data.
Source: EPA/CAMD; EIA-923
17. Unit Unadjusted AnnualNOx Emissions (NOXAN) -
The unit's unadjusted NOx emissions, in short tons, based on the values reported to
CAMD's Power Sector Emissions Data or calculated using EIA-923 unit data and
unit-specific emissions rates or the emission factors listed in Appendix C.
Source: EPA/CAMD; EIA-923
18. Unit Unadjusted Ozone Season NOx Emissions (NOXOZ) -
The unit's unadjusted ozone season (May through September) NOx emissions, in
short tons, based on values reported to CAMD's Power Sector Emissions Data or
calculated using EIA-923 unit data and unit-specific ozone-season emissions rates or
the emission factors listed in Appendix C.
Source: EPA/CAMD; EIA-923
19. Unit Unadjusted Annual SO2 Emissions (S02AN) -
The unit's unadjusted annual SO2 emissions, in short tons, based on the values
reported to CAMD's Power Sector Emissions Data or calculated using EIA-923 unit
data and the emission factors listed in Appendix C. When not available, it is zero.
Source: EPA/CAMD; EIA-923
20. Unit Unadjusted Annual CO2 Emissions (C02AN) -
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DESCRIPTION OF DATA ELEMENTS
The unit's unadjusted annual CO2 emissions, in short tons, based on the values
reported to CAMD's Power Sector Emissions Data or calculated using EIA-923 unit
data and emission factors listed in Appendix C.
Source: EPA/CAMD; EIA-923
21. Unit Unadjusted Annual Hg Emissions (HGAN) -
The unit's unadjusted annual Hg emissions, in pounds, based on the values reported
to CAMD's Power Sector Emissions Data.
Source: EPA/CAMD
22. Unit Unadjusted Annual Heat Input Source (HTIANSRC)
Identifies the annual heat input data source.
Source: EPA/CAMD; EIA-923
23. Unit Unadjusted Ozone Season Heat input source (HTIOZSRC)
Identifies the ozone season heat input data source.
Source: EPA/CAMD; EIA-923
24. Unit Unadjusted Annual NOx Emissions Source (NOXANSRC)
Identifies the annual NOx emissions data source.
Source: EPA/CAMD; EIA-923
25. Unit Unadjusted Ozone Season NOx Emissions Source (NOXOZSRC)
Identifies the ozone-season NOx emissions data source.
Source: EPA/CAMD; EIA-923
26. Unit Unadjusted Annual SO2 Emissions Source (S02SRC)
Identifies the annual SO2 emissions data source.
Source: EPA/CAMD; EIA-923
27. Unit Unadjusted Annual CO2 Emissions Source (C02SRC)
Identifies the annual CO2 emissions data source.
Source: EPA/CAMD; EIA-923
28. Unit Unadjusted Annual Hg Emissions Source (HGSRC)
Identifies the annual Hg emissions data source.
Source: EPA/CAMD
29. Unit SO2 (Scrubber) First Control Device (S02CTLDV) -
The first reported SO2 control device. Values may be combined and separated by
commas.
Possible values are:
= blank
ACI = Activated carbon inj ection sy stem
CD = Circulatingdry scrubber
DA = Dual alkali
DL = Dry lime flue gas desulfurization unit
DSI = Dry sorbent (powder) injectiontype
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DESCRIPTION OF DATA ELEMENTS
EK
= Electrostatic precipitator, cold side, without flue gas conditioning
FBL
= Fluidized bed
JB
= Jet bubbling reactor (wet) scrubber
LI J
= Lime injection
MA
= Mechanically aided type (wet) scrubber
MO
= Magnesium oxide
0
= Other (EPA/CAMD)
OT
= Other equipment (EIA-860)
PA
= Pa eked type (wet) scrubber
SB
= Sodium based
SD
= Spray dryertype/dry FGD/semi-dry FGD
SP
= Spray type (wet) scrubber
TR
= Tray type (wet) scrubber
VE
= Venturitype (wet) scrubber
WL
= Wet lime flue gas desulfurizationunit
WLS
= Wet limestone
Source: EPA/CAMD, EIA-860
30. Unit NOx First Control Device (NOXCTLDV) -
The first reported NOx control device. Values may be combined and separated by
commas.
Possible values are:
= Blank
CM = Combustionmodification/fuelreburning
DLNB = Dry low NOx prem ixed technology
EW = Electrostatic precipitator, hot side, withoutflue gas conditioning
H20 = Water injection
LNB = Low NOx burner
LNBO =LowNOxburnerwithoverfireair
LNC1 = Low NOx burner technology with close-coupled overfire air
LNC2 = Low NOx burner technology with separated OFA
LNC3 = Low NOx burner technology with close-coupled and separated overfire air
LNCB = Low NOx burner technology forcell burners
NH3 = Ammonia injection
O/OT = Other
OFA = Overfire a ir
SCR = Selective catalytic reduction (EPA/CAMD)
SN = Selective noncatalytic reduction (EIA-860)
SNCR = Selective noncataly tic reduction (EPA/CAMD)
SR = Selective catalytic reduction (EIA-860)
STM = Steam injection
Source: EPA/CAMD, EIA-860
31. Unit Hg Activated Carbon Injected System Flag (HGCTLDV) -
The activated carbon injection mercury control flag.
Source: EIA-860
32. Unit Year On-Line (UNTYRONL) -
The four-digit year the unit came on-line.
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DESCRIPTION OF DATA ELEMENTS
Source: EPA/CAMD, EIA-860
5.2 The GEN (Generator) File
There are 17 variables in the second file, GEN, which contains generator level data. This file includes
generation from steam boilers and nuclear units in the EIA-923, plant prime movers in the EIA-923
that have only one generator in the EIA-860, and the EIA-923 plant prime movers where generation is
distributed to the generator level based on nameplate capacity.
1. eGRID2020 File Generator Sequence Number (SEQGEN20) -
The generator records in the 2020 generator data file are sorted by state abbreviation,
plant name, plant code, and generator ID, and are assigned a unique sequential
number beginning with 1. This sequence number is unlikely to be the same as the
sequence number in the eGRID2019 file for the same entity.
2. Data Year (YEAR) -
The current eGRID data year.
3. Plant State Abbreviation (PSTATABB) -
The state abbreviation in which the plant is located.
Source: EIA-860
4. Plant Name (PNAME) -
The name associated with each plant.
Source: EPA/CAMD; EIA-860
5. DOE/EIA ORIS Plant or Facility Code (ORISPL) -
This plant code was developed for power plants by the Office of Regulatory
Information Systems (ORIS), which was apart of the Federal Power Commission. It
is now assigned by EIA and is used as a unique plant identification code for many
EPA electric power databases. Note that some EIA ORISPL ID codes were changed
to reflect CAMD's Power Sector Emissions Data ORISPL ID codes. See Section 4.1
for a discussion of ORISPL ID changes made to eGRID2020. See Table C-5 in
Appendix C for a table of all ORISPL changes made between EIA and CAMD's
Power Sector Emissions Data.
Source: EPA/CAMD; EIA-860
6. Generator ID (GENID) -
The electrical generation unit (generator) at a plant. In the majority of cases, there is a
one-to-one correspondence with the boiler ID if it is a steam generator.
Sources: EIA-860
7. Number of Associated Boilers (NUMBLR) -
The number of EIA-860 boilers associated with each generator in the file.
Sources: EIA-860
8. Generator Status (GENSTAT) -
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DESCRIPTION OF DATA ELEMENTS
The reported generator status at the end of 2020.
Possible values are:
CN = Cancelled (previously reportedas "planned")
IP = Planned new generator canceled, indefinitely postponed, orno longerin
resource plan
L = Regulatory approvals pending (notunder construction)
OA = Out of service (returned or will be returned to service)
OP = Operating- in service
OS = Out of service (not expected to be returned to service)
OT = Other
P = Planned for installation but regulatory approvals notinitiated (not under
construction)
RE = Retired - no longer in service
SB = Stand-by (long-term storage)
T = Regulatory approvals received (notunder construction)
TS = Testing, construction complete, butnotyetin commercial operation
U = Underconstruction,lessthan50%constructed
V = Under construction, more than 50% constructed
Generators with one of these above generator status values are considered potentially
operating generators (including generators with status = 'RE', if the retirement date is
2020 or later).
Source: EIA-860
9. Generator Prime Mover Type (PRMVR) -
The reported generator's electric generator type.
Possible values are:
BA
= Battery energy storage
BT
= Binary cycle turbine
CA
= Combined cycle steam turbine
CC
= Combined cycle -totalunit
CE
= Compressed air energy storage
CP
= Concentrated solarpower energy storage
CS
= Combined cycle - single shaft
CT
= Combinedcycle combustion turbine
FC
= Fuel cell
FW
= Flywheel energy storage
GT
= Combustion (gas) turbine
HA
= Hydrokinetic turbine - axialflow
HY
= Hydroelectric turbine
IC
= Internal combustion engine (diesel)
OT
= Other turbine
PS
= Hydraulic turbine - reversible (pumped storage)
PV
= Photovoltaic
ST
= Steam turbine (boiler, nuclear, geothermal, and solar steam)
WS
= Wind turbine - offshore
WT
= Wind turbine - onshore
Source: EIA-860
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DESCRIPTION OF DATA ELEMENTS
10. Generator Primary Fuel (FUELG1)-
The potential primary fuel reported for the generator.
Possible values are:
AB
= Agricultural by -products
BFG
= Blastfurnace gas
BIT
= Bituminous coal
BLQ
= Black liquor
COG
= Coke ovengas
DFO
= Distillate fuel oil, diesel, No. 1, No. 2, andNo.4fueloils
GEO
= Geothermal
H
= Hydrogen
JF
= Jet fuel
KER
= Kerosene
LFG
= Landfill gas
LIG
= Lignite coal
MSW
= Municipal solid wa ste
MWH
= Electricity
NG
= Natural gas
NUC
= Nuclear
OBG
= Otherbiomass gas (digester gas, methane, and other biomass gases)
OBL
= Otherbiomass liquids
OBS
= Otherbiomass solids
OG
= Other gas
OTH
= Other unknown
PC
= Petroleum coke
PG
= Gaseous propane
PRG
= Process gas
PUR
= Purchased steam
RC
= Refined coal
RFO
= Residualfueloil
SGC
= Synthesis gas - coal-derived
SGP
= Synthesis gas - petroleum coke
SLW
= Sludge waste
SUB
= Subbituminouscoal
SUN
= Solar
TDF
= Tire-derived fuel
WAT
= Water
WC
= Waste coal
WDL
= Wood waste liquid (excludingblack liquor)
WDS
= Wood, wood waste solid
WH
= Waste heat
WND
= Wind
WO
= Waste oil
Source: EIA-860
11. Generator Nameplate Capacity (NAMEPCAP) -
The nameplate capacity, in MW, of the generator.
Source: EIA-860
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DESCRIPTION OF DATA ELEMENTS
12. Generator Capacity Factor (CFACT) -
This field is calculated at the generator level:
CFACT = (GENNTAN) / (NAMEPCAP * 8760).
The value should generally be between 0 and 1. However, according to reported data,
there are outliers where, a generator's capacity factor is greater than 1. The capacity
factor for plants with negative net generation is set to 0.
13. Generator Annual Net Generation (GENNTAN) -
The reported net generation in MWh.
Sources: EIA-923
14. Generator Ozone Season Net Generation (GENNTOZ) -
The generator five-month ozone season (May through September) net generation in
MWh, based on monthly generator generation data.
Sources: EIA-923
15. Generation Data Source (GENERSRC) -
The data source of the generator net generation data. The values are as follows:
Blank (no generatorleveldata)
Distributed from EIA-923 Generation and Fuel
EIA-923 Generator File
Data from EIA-923 Generator File overwritten with distributed data from EIA-923
Generation and Fuel
16. Generator Year On-Line (GENYRONL) -
The four-digit year the generator came on-line.
Source: EIA-860
17. Generator Planned or Actual Retirement Year (GENYRRET) -
The four-digit year the generator retired or is planned to retire.
Source: EIA-860
5.3 The PLNT (Plant) File
There are 140 variables in the Plant file (PLNT).
1. eGRID2020 File Plant Sequence Number (SEQPLT20) -
The plant records in the 2020 plant data file are sorted by state abbreviation and plant
name, and are assigned a unique sequential number beginning with 1. This sequence
number is unlikely to be the same as the sequence number in the eGRID2019 file for
the same entity.
2. Data Year (YEAR) -
The current eGRID data year.
3. Plant State Abbreviation (PSTATABB) -
The state abbreviation in which the plant is located.
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DESCRIPTION OF DATA ELEMENTS
Source: EIA-860
4. Plant Name (PNAME) -
The name associated with each plant.
Source: EPA/CAMD; EIA-860
5. DOE/EIA ORIS Plant or Facility Code (ORISPL) -
This plant code corresponds to PNAME and was originally developed for power
plants by the Office of Regulatory Information Systems (ORIS), which was apart of
the Federal Power Commission. It is now assigned by EI A and is used as a unique
plant identification code for many EPA electric power databases, too. Note that some
EIA ORISPL ID codes were changed to reflect CAMD's Power Sector Emissions
Data ORISPL ID codes. See Section 4.1 for a discussion of ORISPL ID changes
made to eGRID2020. See Table C-5 in Appendix C for a table of all ORISPL
changes made between EIA and CAMD's Power Sector Emissions Data.
Source: EPA/CAMD; EIA-860
6. Plant Transmission or Distribution System Owner Name (OPRNAME) -
The name associated with the owner of the transmission or distribution system
company to which the plant is interconnected
Source: EIA-860
7. Plant Transmission or Distribution System Owner ID (OPRCODE) -
The transmission or distribution system owner ID. Each transmission or distribution
system has a unique company code assigned by EIA, with some exceptions. Plants
with no operating company ID assigned by EIA are listed as -9999 in eGRID2020.
Source: EIA-860
8. Utility Name (UTLSRVNM)-
The name of the owner of the utility service territory (a utility company or EGC) [and
previously known as the utility service area] in which the plant is located.
Source: EIA-860
9. Utility ID (UTLSRVID) -
The unique ID code associated with the utility name.
Source: EIA-860
10. Plant-level Sector (SECTOR) -
The plant level sector name, assigned by the purpose, regulatory status, and CHP
status at the plant.
Possible values are:
CommercialCHP
CommercialNon-CHP
Electric Utility
Industrial CHP
IndustrialNon-CHP
Independent Power Producer (IPP) CHP
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DESCRIPTION OF DATA ELEMENTS
Independent Power Producer (IPP) Non-CHP
Source: EIA-860
11. Balancing Authority Name (BANAME) -
The name of the balancing authority for the plant. The balancing authority is
associated with the plant's eGRID subregion and NERC region.
Source: EIA-860, EIA-861
12. Balancing Authority Code (BACODE) -
The code of the balancing authority for the plant.
Source: EIA-860, EIA-861
13. NERC Region Acronym (NERC) -
The acronym for the NERC region in which the plant is located. The NERC region is
associated with the plant's BA and eGRID subregion. A representation of the eGRID
NERC region map is included in Appendix B.
Source: EIA-860
14. eGRID Subregion Acronym (SUBRGN) -
The acronym for the eGRID subregion in which the plant is located. The eGRID
subregion is associated with the plant's balancing authority and NERC region. A
representation of the eGRID subregion map is included in Appendix B.
Source: EPA
15. eGRID Subregion Name (SRNAME) -
The name of the eGRID subregion in which the plant is located.
Source: EPA
16. Plant Associated ISO/RTO Territory (ISORTO) -
The name, if applicable, of the Independent System Operator (ISO) or Regional
Transmission Organization (RTO) associated with the plant.
Possible values are CAISO, ERCOT, ISONE, MISO, NYISO, PJM, SPP, or blank.
Source: EIA-860
17. Plant FIPS State Code (FIPSST) -
The two-digit Federal Information Processing Standards (FIPS) state character code
of the state in which the plant is located. The codes are from the National Institute of
Standards and Technology (US Census, 2020.
Source: US Census
18. Plant FIPS County Code (FIPSCNTY) -
The three digit FIPS county character code of the county in which the plant is
located. The codes are from the National Institute of Standards and Technology (US
Census, 2020).
Source: US Census
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DESCRIPTION OF DATA ELEMENTS
19. Plant County Name (CNTYNAME) -
The name of the county in which the plant is located.
Source: EIA-860
20. Plant Latitude (LAT) -
The latitude, in degrees to four decimal places, associated with the plant.
Source: EIA-860
21. Plant Longitude (LON) -
The longitude, in degrees to four decimal places, associated with the plant.
Source: EIA-860
22. Number of Units (NUMUNT) -
The number of operating units within a plant.
Source: EIA-860
23. Number of Generators (NUMGEN) -
The number of potentially operating generators within a plant.
Source: EIA-860
24. Plant Primary Fuel (PLPRMFL) -
The plant's primary fuel based on maximum heat input of fuel consumed by the
plant. If the plant does not consume fuel, it is based on the maximum nameplate
capacity. Possible values are:
AB
= Agriculturalbyproduct
BFG
= Blastfurnace gas
BIT
= Bituminous coal
BLQ
= Black liquor
COG
= Coke ovengas
DFO
= Distillate fueloil, light fueloil, dieseloil
GEO
= Geothermal steam
H
= Hydrogen
JF
= Jet fuel
KER
= Kerosene
LFG
= Landfill gas
LIG
= Lignite coal
MSW
= Municipal solid wa ste
MWH
= Electricity used forenergy storage (megawatthour)
NG
= Natural gas
NUC
= Nuclear material
OBG
= Otherbiomass gas
OBL
= Other biom ass liquid
OBS
= Other biom ass solid
OG
= Other gas
OTH
= Other (unknown)
PC
= Petroleum coke
PG
= Gaseous propane
PRG
= Process gas
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DESCRIPTION OF DATA ELEMENTS
PUR
RC
RFO
SGC
SLW
SUB
SUN
TDF
WAT
WC
WDL
WDS
WH
WND
WO
= Purchased fuel (unknown)
= Refined coal
= Residualfueloil, heavy fueloil, petroleum
= Coal-derived synthetic gas
= Sludge waste
= Subbituminous coal
= Sun
= Tire-derived fuel
= Water
= Waste coal
= Wood, wood waste liquid
= Wood, wood waste solid
= Waste heat
= Wind
= Waste oil
Source: EPA/CAMD; EIA-860
25. Plant Primary Fuel Category (PLFUELCT) -
The fuel category for the primary fuel of the plant. This field is "COAL" if the
plant's primary fuel is derived from coal (fuel type = BIT, COG, LIG, RC, SGC,
SUB, WC), "OIL" if it is derived from oil (DFO, JF, KER, PC, RFO, WO), "GAS" if
it is derived from gas (NG, PG), "OFSL" if it is another fossil fuel (BFG, OG, TDF),
"NUCLEAR" if it is derived from nuclear (NUC), "HYDRO" if it is derived from
hydro power (WAT), "SOLAR" if it is derived from solar power, (SUN), "WIND" if
it is derived from wind power (WND), "GEOTHERMAL" if it is derived from
geothermal power (GEO), "OTHF" if it is derived from waste
heat/hydrogen/purchased/unknown (H, MWH, OTH, PRG, PUR, WH), and
"BIOMASS" if it is derived from biomass sources (AB, BLQ, LFG, MSW, OBG,
OBL, OBS, SLW, WDL, WDS).
26. Flag indicating if the plant burned or generated any amount of coal
(COALFLAG) -
A flag to indicate if the plant burned coal or if it has positive heat input and generated
electricity from coal. The plant will not be flagged if the plant has negative coal
generation and no coal heat input for 2020.
27. Plant Capacity Factor (CAPFAC) -
The plant capacity factor, expressed with four decimal places. It is calculated as
follows:
CAPFAC = (PLNGENAN / (NAMEPCAP * 8760))
Although the value should be between 0 and 1, there are outliers.
28. Plant Nameplate Capacity (NAMEPCAP) -
The nameplate capacity of the plant, in MW.
Source: EIA-860
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DESCRIPTION OF DATA ELEMENTS
29. Nonbaseload F actor (NBF ACTOR) -
The proportion of generation that is considered nonbaseload generation. A value of 0
means that all of the generation is baseload generation. See Section 3 for more
information.
Source: Calculated
30. Biogas/Biomass Plant Adjustment Flag (RMBMFLAG) -
A biogas (landfill gas, digester gas)/biomass adjustment flag used to indicate where
emissions are adjusted for plants using biogas or biomass fuels. A facility's emissions
reported in eGRID may be different from that reported in other EPA sources, such as
CAMD's Power Sector Emissions Data, due to this adjustment.
31. Combined Heat and Power (CHP) Plant Adjustment Flag (CHPFLAG) -
A flag to indicate if the plant is a CHP facility. A CHP facility's emissions and heat
input reported in eGRID may be different from that reported in other EPA sources,
such as CAMD's Power Sector Emissions Data, due to this adjustment.
Source: EPA/CAMD; EIA-860
32. CHP Plant Useful Thermal Output (USETHRMO) -
The useful thermal output, in MMBtu, estimated for a CHP facility.
Source: EIA-923 calculated
33. CHP Plant Power to Heat Ratio (PWRTOHT) -
The power to heat ratio for a CHP facility, which is the ratio of the heat value of
electricity generated (3413 * kWh output) to the facility's useful thermal output.
34. CHP Plant Electric Allocation Factor (ELCALLOC) -
The CHP plant's decimal fraction of the emissions that are attributed to electricity. It
is derived as the ratio of the electric heat output to the sum of the electric and steam
heat outputs, where the steam output is 75% of the useful thermal output. The electric
allocation factor is used to allocate emissions from a CHP facility to both electricity
generation and useful thermal output. For non-CHP plants, eGRID uses an electric
allocation factor of 1.0.
35. Plant Pumped Storage Flag (PSFLAG) -
Indicates if the plant has at least one pumped storage generator.
Source: EIA-860
36. Plant Annual Heat Input from Combustion (PLHTIAN) -
The total annual heat input from combustion, in MMBtu, for the plant. For CHP
plants, the value is adjusted by the electric allocation factor.
37. Plant Ozone Season Heat Input from Combustion (PLHTIOZ) -
The five-month ozone season (May through September) heat input from combustion,
in MWh, for the plant. For CHP plants, the value is adjusted by the electric allocation
factor.
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DESCRIPTION OF DATA ELEMENTS
38. Plant Total Annual Heat Input (PLHTIANT) -
The total annual heat input from combustion and noncombustion units, in MMBtu,
for the plant. For CHP plants, the value is adjusted by the electric allocation factor.
39. Plant Total Ozone Season Heat Input (PLHTIOZT) -
The five-month ozone season (May through September) heat input from combustion
and noncombustion units, in MWh, for the plant. For CHP plants, the value is
adjusted by the electric allocation factor.
40. Plant Annual Net Generation (PLNGENAN) -
The total reported annual net generation, in MWh, for the plant, summed from the
Unit file.
Source: EIA-923
41. Plant Ozone Season Net Generation (PLNGENOZ) -
The five-month ozone season (May through September) net generation for the plant.
Source: EIA-923
42. Plant Annual NOx Emissions (PLNOXAN) -
The total annual NOx emissions, in short tons, for the plant. Biogas components are
adjusted. For CHP plants, the value is adjusted by the electric allocation factor. This
adjusted emissions field is estimated by first making the biogas adjustment (if it
exists) and then applying the electric allocation factor (if the plant is a CHP).
43. Plant Ozone Season NOx Emissions (PLNOXOZ) -
The five-month ozone season (May through September) NOx emissions, in short tons,
for the plant. Biogas components are adjusted. For CHP plants, the value is adjusted
by the electric allocation factor. This adjusted emissions field is estimated by first
making the biogas adjustment (if it exists) and then applying the electric allocation
factor (if the plant is a CHP).
44. Plant Annual SO2 Emissions (PLS02AN) -
The total annual SO2 emissions, in short tons, for the plant. Landfill gas components
are adjusted. For CHP plants, the value is adjusted by the electric allocation factor.
This adjusted emissions field is estimated by first making the landfill gas adjustment
(if it exists) and then applying the electric allocation factor (if the plant is a CHP).
45. Plant Annual CO2 Emissions (PLC02AN) -
The total annual CO2 emissions, in short tons, for the plant. All CO2 emissions from
biomass fuels are adjusted to zero. For CHP plants, the value is adjusted by the
electric allocation factor. This adjusted emissions field is estimated by first making
the biomass adjustment (if it exists) and then applying the electric allocation factor (if
the plant is a CHP).
46. Plant Annual CH4 Emissions (PLCH4AN) -
The total annual CH4 emissions, in pounds, for the plant. Biogas biomass components
are adjusted. For CHP plants, the value is adjusted by the electric allocation factor.
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DESCRIPTION OF DATA ELEMENTS
This adjusted emissions field is estimated by first making the biomass adjustment (if
it exists) and then applying the electric allocation factor (if the plant is a CHP).
47. Plant Annual N2O Emissions (PLN20AN) -
The total annual N2O emissions, in pounds for the plant. Biogas biomass components
are adjusted. For CHP plants, the value is adjusted by the electric allocation factor.
This adjusted emissions field is estimated by first making the biomass adjustment (if
it exists) and then applying the electric allocation factor (if the plant is a CHP).
48. Plant Annual CO2 Equivalent Emissions (PLC02EQA) -
The annual CO2 equivalent emissions, in short tons, for the plant. This value is a
universal standard of measurement. The GWPs from the fourth IPCC assessment are
used for the calculation; the formula is as follows:
PLC02EQA = ((1* PLC02AN) + (25* PLCH4AN / 2000) + (298 * PLN20AN /
2000)).
49. Plant Annual Hg Emissions (PLHGAN) -
Not calculated for eGRID2020.
50. Plant Annual NOx Total Output Emission Rate (PLNOXRTA) -
This field, in lb/MWh, is calculated as follows:
PLNOXRTA = 2000 * (PLNOXAN / PLNGENAN).
51. Plant Ozone Season NOx Total Output Emission Rate (PLNOXRTO) -
This field, in lb/MWh, is calculated as follows:
PLNOXRTO = 2000 * (PLNOXOZ / PLNGENOZ).
52. Plant Annual SO2 Total Output Emission Rate (PLS02RTA) -
This field, in lb/MWh, is calculated as follows:
PLS02RTA = 2000 * (PLS02AN / PLNGENAN).
53. Plant Annual CO2 Total Output Emission Rate (PLC02RTA) -
This field, in lb/MWh, is calculated as follows:
PLC02RTA = 2000 * (PLC02AN / PLNGENAN).
54. Plant Annual CH4 Total Output Emission Rate (PLCH4RTA) -
This field, in lb/MWh, is calculated as follows:
PLCH4RTA = PLCH4AN / PLNGENAN.
55. Plant Annual N2O Total Output Emission Rate (PLN20RTA)-
This field, in lb/MWh, is calculated as follows:
PLN20RTA = PLN20AN / PLNGENAN
56. Plant Annual CO2 Equivalent Total Output Emission Rate (PLC2ERTA) -
This field, in lb/MWh, is calculated as follows:
PLC2ERTA= 2000 * (PLC02EQA/ PLNGENAN).
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61,
62,
63,
64,
65,
66,
67,
68,
DESCRIPTION OF DATA ELEMENTS
Plant Annual Hg Total Output Emission Rate (PLHGRTA) -
Not calculated for eGRID2020.
Plant Annual NOx Input Emission Rate (PLNOXRA) -
This field, in lb/MMBtu, is calculated as follows:
PLNOXRA = 2000 * (PLNOXAN / PLHTIAN).
Plant Ozone Season NOx Input Emission Rate (PLNOXRO) -
This field, in lb/MMBtu, is calculated as follows:
PLNOXRO = 2000 * (PLNOXOZ / PLHTTOZ).
Plant Annual SO2 Input Emission Rate (PLS02RA) -
This field, in lb/MMBtu, is calculated as follows:
PLS02RA = 2000 * (PLS02AN / PLHTIAN).
Plant Annual CO2 Input Emission Rate (PLC02RA) -
This field, in lb/MMBtu, is calculated as follows:
PLC02RA = 2000 * (PLC02AN / PLHTIAN).
Plant Annual CH4 Input Emission Rate (PLCH4RA) -
This field, in lb/MMBtu, is calculated as follows:
PLC02RA = 2000 * (PLCH4AN / PLHTIAN).
Plant Annual N2O Input Emission Rate (PLN20RA)-
This field, in lb/MMBtu, is calculated as follows:
PLC02RA = 2000 * (PLN20AN / PLHTIAN).
Plant Annual CO2 Equivalent Input Emission Rate (PLC2ERA) -
This field, in lb/MMBtu, is calculated as follows:
PLC02RA = 2000 * (PLC02EQA/ PLHTIAN).
Plant Annual Hg Input Emission Rate (PLHGRA) -
Not calculated for eGRID2020.
Plant Annual NOx Combustion Output Emission Rate (PLNOXCRT) -
This field, in lb/MWh, is calculated as follows:
PLNOXCRT = 2000 * (PLNOXAN / PLGENACY).
Plant Ozone Season NOx Combustion Output Emission Rate
(PLNOXCRO) -
This field, in lb/MWh, is calculated as follows:
PLNOXCRO = 2000 * (PLNOXOZ / ((PLGENACY * PLNGENOZ) /
PLNGENAN)).
Plant Annual SO2 Combustion Output Emission Rate (PLS02CRT) -
This field, in lb/MWh, is calculated as follows:
PLS02CRT = 2000 * (PLS02AN / PLGENACY).
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70,
71,
72,
73,
74,
75,
76,
77,
78,
79,
80,
81,
82,
DESCRIPTION OF DATA ELEMENTS
Plant Annual CO2 Combustion Output Emission Rate (PLC02CRT) -
This field, in lb/MWh, is calculated as follows:
PLC02CRT = 2000 * (PLC02AN / PLGENACY).
Plant Annual CH4 Combustion Output Emission Rate (PLCH4CRT) -
This field, in lb/MWh, is calculated as follows:
PLCH4CRT = PLCH4AN / PLGENACY.
Plant Annual N2O Combustion Output Emission Rate (PLN20CRT) -
This field, in lb/MWh, is calculated as follows:
PLN20CRT = PLN20AN / PLGENACY.
Plant Annual CO2 Equivalent Combustion Output Emission Rate
(PLC2ECRT) -
This field, in lb/MWh, is calculated as follows:
PLC2ECRT = 2000 * (PLC02EQA/ PLGENACY).
Plant Annual Hg Combustion Output Emission Rate (PLHGCRT)-
Not calculated for eGRID2020.
Plant Unadjusted Annual NOx Emissions (UNNOX) -
The total plant-level unadjusted annual NOx emissions, in short tons.
Plant Unadjusted Ozone Season NOx Emissions (UNNOXOZ) -
The unadjusted five-month ozone season (May through September) NOx emissions,
in short tons, for the plant.
Plant Unadjusted Annual SO2 Emissions (UNS02) -
The total plant-level unadjusted annual SO2 emissions, in short tons.
Plant Unadjusted Annual CO2 Emissions (UNC02) -
The total plant-level unadjusted annual CO2 emissions, in short tons.
Plant Unadjusted Annual CH4 Emissions (UNCH4) -
The total plant-level unadjusted annual CH4 emissions, in pounds.
Plant Unadjusted Annual N2O Emissions (UNN20) -
The total plant-level unadjusted annual N2O emissions, in pounds.
Plant Unadjusted Annual Hg Emissions (UNHG) -
Not calculated for eGRID2020.
Plant Unadjusted Annual Heat Input from Combustion (UNHTI) -
The total plant-level unadjusted annual heat input from combustion, in MMBtu.
Sources: EPA/CAMD, EIA-923
Plant Unadjusted Ozone Season Heat Input from Combustion (UNHTIOZ) -
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86,
87,
88,
89,
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91,
92,
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94,
DESCRIPTION OF DATA ELEMENTS
The five-month ozone season (May through September) heat input from combustion,
in MMBtu for the plant.
Sources: EPA/CAMD, EIA-923
Plant Unadjusted Total Annual Heat Input (UNHTIT) -
The total plant-level unadjusted annual heat input from combustion and
noncombustion units, in MMBtu.
Sources: EPA/CAMD, EIA-923
Plant Unadjusted Total Ozone Season Heat Input (UNHTIOZT) -
The five-month ozone season (May through September) heat input from combustion
and noncombustion units, in MMBtu for the plant.
Sources: EPA/CAMD, EIA-923
Plant Unadjusted Annual NOx Emissions Source (UNNOXSRC) -
The source of plant-level unadjusted annual NOx emissions.
Plant Unadjusted Ozone Season NOx Emissions Source (UNNOZSRC) -
The source of plant-level unadjusted ozone NOx emissions.
Plant Unadjusted Annual SO2 Emissions Source (UNS02SRC)-
The source of plant-level unadjusted annual SO2 emissions.
Plant Unadjusted Annual CO2 Emissions Source (UNC02SRC) -
The source of plant-level unadjusted annual CO2 emissions.
Plant Unadjusted Annual CH4 Emissions Source (UNCH4SRC) -
The source of plant-level unadjusted annual CH4 emissions.
Plant Unadjusted Annual N2O Emissions Source (UNN20SRC) -
The source of plant-level unadjusted annual N2O emissions.
Plant Unadjusted Annual Hg Emissions Source (UNHGSRC)-
Not calculated for eGRID2020.
Plant Unadjusted Annual Heat Input Source (UNHTISRC) -
The source of plant-level unadjusted annual heat input.
Plant Unadjusted Ozone Season Heat Input Source (UNHOZSRC) -
The source of plant-level unadjusted ozone season heat input.
Plant Annual NOx Biomass Emissions (BIONOX) -
The annual plant-level NOx biomass emissions, in short tons. This is the value the
total emissions are adjusted by for the biomass emissions adjustments. See Section
3.1.2.1 for more information.
Source: EIA-923
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DESCRIPTION OF DATA ELEMENTS
95. Plant Ozone Season NOx Biomass Emissions (BIONOXOZ) -
The five-month ozone season (May through September) plant-level NOx biomass
emissions, in short tons. This is the value the total emissions are adjusted by for the
biomass emissions adjustments. See Section 3.1.2.1 for more information.
Source: EIA-923
96. Plant Annual SO2 Biomass Emissions (BI0S02) -
The annual plant-level SO2 biomass emissions, in short tons. This is the value the
total emissions are adjusted by for the biomass emissions adjustments. See Section
3.1.2.1 for more information.
Source: EIA-923
97. Plant Annual CO2 Biomass Emissions (BI0C02) -
The annual plant-level CO2 biomass emissions, in short tons. This is the value the
total emissions are adjusted by for the biomass emissions adjustments. See Section
3.1.2.1 for more information.
Source: EIA-923
98. Plant Annual CH4 Biomass Emissions (BIOCH4) -
The annual plant-level CH4 biomass emissions, in pounds. This is the value the total
emissions are adjusted by for the biomass emissions adjustments. See Section 3.1.2.1
for more information.
Source: EIA-923
99. Plant Annual N2O Biomass Emissions (BI0N20) -
The annual plant-level N2O biomass emissions, in pounds. This is the value the total
emissions are adjusted by for the biomass emissions adjustments. See Section 3.1.2.1
for more information.
Source: EIA-923
100. Plant Combustion Annual Heat Input CHP Adjustment Value (CHPCHTI) -
The annual plant-level heat input adjustment value for CHP plants, in MMBtu. See
Section 3.1.2.2 for more information.
101. Plant Combustion Ozone Season Heat Input CHP Adjustment Value
(CHP CHTIOZ) -
The five-month ozone season (May through September) plant-level heat input
adjustment value for CHP plants, in MMBtu. See Section 3.1.2.2 for more
information.
102. Plant Annual NOx Emissions CHP Adjustment Value (CHPNOX) -
The annual plant-level NOx emissions adjustment value for CHP plants, in short tons.
See Section 3.1.2.2 for more information.
103. Plant Ozone season NOx Emissions CHP Adjustment Value (CHPNOXOZ) -
The five-month ozone season (May through September) plant-level NOx emissions
adjustment value for CHP plants, in short tons. See Section 3.1.2.2 for more
information.
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DESCRIPTION OF DATA ELEMENTS
104. Plant Annual SO2 Emissions CHP Adjustment Value (CHPS02) -
The annual plant-level SO2 emissions adjustment value for CHP plants, in short tons.
See Section 3.1.2.2 for more information.
105. Plant Annual CO2 Emissions CHP Adjustment Value (CHPC02) -
The annual plant-level CO2 emissions adjustment value for CHP plants, in short tons.
See Section 3.1.2.2 for more information.
106. Plant Annual CH4 Emissions CHP Adjustment Value (CHPCH4) -
The annual plant-level CH4 emissions adjustment value for CHP plants, in pounds.
See Section 3.1.2.2 for more information.
107. Plant Annual N2O Emissions CHP Adjustment Value (CHPN20) -
The annual plant-level N2O emissions adjustment value for CHP plants, in pounds.
See Section 3.1.2.2 for more information.
108. Plant Nominal Heat Rate (PLHTRT) -
The plant nominal heat rate, in Btu/kWh, for partial combustion plants. It is
calculated as follows:
PLHTRT = 1000 * (PLHTIAN / PLGENACY)
For CHP plants, the value is, in effect, adjusted by the electric allocation factor, since
the heat input has been adjusted.
109. Plant Annual Coal Net Generation (PLGENACL) -
The plant annual net generation, in MWh, for coal. Fuel codes that are included in
coal are BIT, COG, SUB, LIG, WC, and SC.
110. Plant Annual Oil Net Generation (PLGENAOL) -
The plant annual net generation, in MWh, for oil. Fuel codes included in oil are DFO,
JF, KER, OO, PC, RFO, RG, and WO.
111. Plant Annual Gas Net Generation (PLGENAGS) -
The plant annual net generation, in MWh, for natural gas. Fuel codes included in gas
are NG andPG.
112. Plant Annual Nuclear Net Generation (PLGENANQ -
The plant annual net generation, in MWh, for nuclear. The fuel code is NUC.
113. Plant Annual Hydro Net Generation (PLGENAHY) -
The plant annual net generation, in MWh, for hydro. The fuel code is WAT.
114. Plant Annual Biomass Net Generation (PLGENABM) -
The annual net generation, in MWh, for biomass. Biomass is a fuel derived from
organic matter such as wood and paper products, agricultural waste, or methane (e.g.,
from landfills). The renewable portion of solid waste, fuel code MSB, is included as
biomass, as are AB, BLQ, DG, LFG, ME, OBL, OBS, PP, SLW, WDL, and WDS.
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DESCRIPTION OF DATA ELEMENTS
115. Plant Annual Wind Net Generation (PLGENAWI) -
The plant annual net generation, in MWh, for wind. The fuel code is WND.
116. Plant Annual Solar Net Generation (PLGENASO) -
The plant annual net generation, in MWh, for solar. The fuel code is SUN.
117. Plant Annual Geo thermal Net Generation (PLGENAGT) -
The plant annual net generation, in MWh, for geothermal. The fuel code is GEO.
118. Plant Annual Other Fossil Net Generation (PLGENAOF) -
The plant annual net generation, in MWh, for other fossil fuel that cannot be
categorized as coal, oil, or gas. Other fossil fuel codes include BFG, COG, HY, LB,
MH, MSF, OG, PRG, and TDF.
119. Plant Annual Other Unknown/ Purchased Fuel Net Generation (PLGENAOP) -
The plant annual net generation, in MWh, for other unknown/pur chased. Fuel codes
include OTH, PUR, or WH.
120. Plant Annual Total Nonrenewables Net Generation (PLGENATN) -
The annual total nonrenewables net generation, in MWh, for the plant.
Nonrenewables are exhaustible energy resources such as coal, oil, gas, other fossil,
nuclear power, and other unknown/pur chased fuel. This field is the sum of
PLGENACL, PLGENAOL, PLGENAGS, PLGENAOF, PLGENANC, and
PLGENAOP.
121. Plant Annual Total Renewables Net Generation (PLGENATR) -
The annual total renewables net generation, in MWh, for the plant. Renewables are
inexhaustible energy resources such as biomass, wind, solar, geothermal, and hydro.
This field is the sum of PLGENABM, PLGENAWI, PLGENASO, PLGENAGT, and
PLGENAHY.
122. Plant Annual Total Nonhydro Renewables Net Generation (PLGENATH) -
The annual total nonhydro renewables net generation, in MWh, for the plant. This
field is the sum of PLGENABM, PLGENAWI, PLGENASO, and PLGENAGT.
123. Plant Annual Total Combustion Net Generation (PLGENACY) -
The annual total combustion net generation, in MWh, for the plant. This field is the
sum of PLGENACL, PLGENAOL, PLGENAGS, PLGENAOF, PLGENABM, and
PLGENAOP.
124. Plant Annual Total Noncombustion Net Generation (PLGENACN) -
The annual total noncombustion net generation, in MWh, for the plant. This field is
the sum of PLGENANC, PLGENAHY, PLGENAWI, PLGENASO, and
PLGENAGT.
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127,
128
129
130
131
132
133
134
135,
DESCRIPTION OF DATA ELEMENTS
Plant Coal Generation Percent (PLCLPR) -
The coal resource mix expressed as a percent of plant annual net generation.
PLCLPR = 100 * (PLGENACL / PLNGENAN).
Plant Oil Generation Percent (PLOLPR) -
The oil resource mix expressed as a percent of plant annual net generation.
PLOLPR = 100 * (PLGENAOL / PLNGENAN).
Plant Gas Generation Percent (PLGSPR) -
The gas resource mix expressed as a percent of plant annual net generation.
PLGSPR = 100 * (PLGENAGS / PLNGENAN).
Plant Nuclear Generation Percent (PLNCPR) -
The nuclear resource mix expressed as a percent of plant annual net generation.
PLNCPR = 100 * (PLGENANC / PLNGENAN).
Plant Hydro Generation Percent (PLHYPR) -
The hydro resource mix expressed as a percent of plant annual net generation.
PLHYPR = 100 * (PLGENAHY/ PLNGENAN).
Plant Biomass Generation Percent (PLBMPR) -
The biomass resource mix expressed as a percent of plant annual net generation.
PLBMPR = 100 * (PLGENABM/ PLNGENAN).
Plant Wind Generation Percent (PLWIPR) -
The wind resource mix expressed as a percent of plant annual net generation.
PLWIPR = 100 * (PLGENAWI / PLNGENAN).
Plant Solar Generation Percent (PLSOPR)-
The solar resource mix expressed as a percent of plant annual net generation.
PLSOPR= 100 * (PLGENASO / PLNGENAN).
Plant Geothermal Generation Percent (PLGTPR) -
The geothermal resource mix expressed as a percent of plant annual net generation.
PLGTPR = 100 * (PLGENAGT/ PLNGENAN).
Plant Other Fossil Generation Percent (PLOFPR) -
The other fossil resource mix expressed as a percent of plant annual net generation.
PLOFPR = 100 * (PLGENAOF / PLNGENAN).
Plant Other Unknown/Purchased Fuel Generation Percent (PLOPPR) -
The other unknown/pur chased fuel/waste heat resource mix expressed as a percent of
plant annual net generation.
PLOPPR = 100 * (PLGENAOP / PLNGENAN).
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DESCRIPTION OF DATA ELEMENTS
136. Plant Total Nonrenewables Generation Percent (PLTNPR) -
The total nonrenewables resource mix expressed as a percent of plant annual net
generation.
PLTNPR = 100 * (PLGENATN / PLNGENAN).
137. Plant Total Renewables Generation Percent (PLTRPR) -
The total renewables resource mix expressed as a percent of plant annual net
generation.
PLTRPR = 100 * (PLGENATR/ PLNGENAN).
138. Plant Total Nonhydro Renewables Generation Percent (PLTHPR) -
The total nonhydro renewables resource mix expressed as a percent of plant annual
net generation.
PLTHPR = 100 * (PLGENATH / PLNGENAN).
139. Plant Total Combustion Generation Percent (PLCYPR) -
The total combustion resource mix expressed as a percent of plant annual net
generation.
PLCYPR = 100 * (PLGENACY/ PLNGENAN).
140. Plant Total Noncombustion Generation Percent (PLCNPR) -
The total noncombustion resource mix expressed as a percent of plant annual net
generation.
PLCNPR = 100 * (PLGENACN/ PLNGENAN).
5.4 The ST (State) File
There are 164 variables in the fourth file, ST, which contains state level data. All size, heat input,
generation, and emission values are derived by aggregating from the plant level based on the state in
which the plant is located. Aggregated variable names generally begin with "ST." Variables that are
either identical to those in the plant file or different from those in the plant file by the first two letters
of their names (e. g., STHTI AN instead of PLHTIAN) are not re-defined here.
1.
Data Year (YEAR) -
2.
State Abbreviation (PSTATABB) -
3.
FIPS State Code (FIPSST) -
4.
State Nameplate Capacity (STNAMEPCAP) -
5.
State Annual Heat Input from Combustion (STHTIAN) -
6.
State Ozone Season Heat Input from Combustion (STHTIOZ) -
7.
State Total Annual Heat Input (STHTIANT) -
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8. State Total Ozone Season Heat Input (STHTIOZT) -
9. State Annual Net Generation (STNGENAN) -
10. State Ozone Season Net Generation (STNGENOZ) -
11. State Annual NOx Emissions (STNOXAN) -
12. State Ozone Season NOx Emissions (STNOXOZ) -
13. State Annual SO2 Emissions (STS02AN) -
14. State Annual CO2 Emissions (STC02AN) -
15. State Annual CH4 Emissions (STCH4AN) -
16. State Annual N2O Emissions (STN20AN) -
17. State Annual CO2 Equivalent Emissions (STC02EQA) -
18. State Annual Hg Emissions (STHGAN) -
19. State Annual NOx Total Output Emission Rate (STNOXRTA) -
This field, in lb/MWh, is calculated as follows:
STNOXRTA = 2000 * (STNOXAN / STNGENAN).
20. State Ozone Season NOx Total Output Emission Rate (STNOXRTO) -
This field, in lb/MWh, is calculated as follows:
STNOXRTO = 2000 * (STNOXOZ / STNGENOZ).
21. State Annual SO2 Total Output Emission Rate (STS02RTA) -
This field, in lb/MWh, is calculated as follows:
STS02RTA= 2000 * (STS02AN/ STNGENAN).
22. State Annual CO2 Total Output Emission Rate (STC02RTA) -
This field, in lb/MWh, is calculated as follows:
STC02RTA = 2000 * (STC02AN / STNGENAN).
23. State Annual CH4 Total Output Emission Rate (STCH4RTA) -
This field, in lb/MWh, is calculated as follows:
STHCH4RTA = STCH4AN / STNGENAN.
24. State Annual N2O Total Output Emission Rate (STN20RTA) -
This field, in lb/MWh, is calculated as follows:
STN20RTA = STN20AN / STNGENAN.
25. State Annual CO2 Equivalent Total Output Emission Rate (STC2ERTA) -
This field, in lb/MWh, is calculated as follows:
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26,
27,
28,
29,
30,
31,
32,
33,
34,
35,
36,
37,
DESCRIPTION OF DATA ELEMENTS
STC2ERTA= 2000 * (STC02EQA/ STNGENAN).
State Annual Hg Total Output Emission Rate (STHGRTA)-
Not calculated for eGRID2020.
State Annual NOx Input Emission Rate (STNOXRA) -
This field, in lb/MMBtu, is calculated as follows:
STNOXRA = 2000 * (STNOXAN / STHTI AN),
State Ozone Season NOx Input Emission Rate (STNOXRO) -
This field, in lb/MMBtu, is calculated as follows:
STNOXRO = 2000 * (STNOXOZ / STHTIOZ).
State Annual SO2 Input Emission Rate (STS02RA) -
This field, in lb/MMBtu, is calculated as follows:
STS02RA = 2000 * (STS02AN / STHTI AN).
State Annual CO2 Input Emission Rate (STC02RA)-
This field, in lb/MMBtu, is calculated as follows:
STC02RA = 2000 * (STC02AN / STHTI AN).
State Annual CH4 Input Emission Rate (STCH4RA) -
This field, in lb/MMBtu, is calculated as follows:
STCH4RA = 2000 * (STCH4AN / STHTI AN).
State Annual N2O Input Emission Rate (STN20RA) -
This field, in lb/MMBtu, is calculated as follows:
STN20RA = 2000 * (STN20AN / STHTI AN).
State Annual CO2 Equivalent Input Emission Rate (STC2ERA) -
This field, in lb/MMBtu, is calculated as follows:
STC2ERA = 2000 * (STC02EQA/ STHTI AN).
State Annual Hg Input Emission Rate (STHGRA) -
Not calculated for eGRID2020.
State Annual NOx Combustion Output Emission Rate (STNOXCRT) -
This field, in lb/MMBtu, is calculated as follows:
STNOXCRT =2000 * (STNOXAN / STGENACY).
State Ozone Season NOx Combustion Output Emission Rate (STNOXCRO) -
This field, in lb/MMBtu, is calculated as follows:
STNOXCRO = 2000 * (STNOXOZ / ((STGENACY*STNGENOZ)/STNGENAN)).
State Annual SO2 Combustion Output Emission Rate (STS02CRT) -
This field, in lb/MMBtu, is calculated as follows:
STS02CRT = 2000 * (STS02AN / STGENACY).
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DESCRIPTION OF DATA ELEMENTS
38. State Annual CO2 Combustion Output Emission Rate (STC02CRT) -
This field, in lb/MMBtu, is calculated as follows:
STC02CRT = 2000 * (STC02AN / STGENACY).
39. State Annual CH4 Combustion Output Emission Rate (STCH4CRT) -
This field, in lb/MMBtu, is calculated as follows:
STCH4CRT = STCH4AN / STGENACY.
40. State Annual N2O Combustion Output Emission Rate (STN20CRT) -
This field, in lb/MMBtu, is calculated as follows:
STN20CRT = STN20AN / STGENACY.
41. State Annual CO2 Equivalent Combustion Output Emission Rate
(STC2ECRT) -
This field, in lb/MMBtu, is calculated as follows:
STC2ECRT = 2000 * (STC02EQA/ STGENACY).
42. State Annual Hg Combustion Output Emission Rate (STHGCRT) -
Not calculated for eGRID2020.
43. State Annual NOx Coal Output Emission Rate (STCNOXRT) -
The sum of the annual NOx emissions from all plants in the state that have coal as the
primary fuel (PLPRMFL) divided by the sum of the annual combustion net
generation from the same set of plants, and multiplied by a unit conversion factor, in
lb/MWh.
44. State Annual NOx Oil Output Emission Rate (STONOXRT) -
The sum of the annual NOx emissions from all plants in the state that have oil as the
primary fuel (PLPRMFL) divided by the sum of the annual combustion net
generation from the same set of plants, and multiplied by a unit conversion factor, in
lb/MWh.
45. State Annual NOx Gas Output Emission Rate (STGNOXRT) -
The sum of the annual NOx emissions from all plants in the state that have natural gas
as the primary fuel (PLPRMFL) divided by the sum of the annual combustion net
generation from the same set of plants, and multiplied by a unit conversion factor, in
lb/MWh.
46. State Annual NOx Fossil Fuel Output Emission Rate (STFSNXRT) -
The sum of the annual NOx emissions from all plants in the state that have any fossil
fuel (coal, oil, gas, or other fossil) as the primary fuel (PLPRMFL) divided by the
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DESCRIPTION OF DATA ELEMENTS
sum of the annual combustion net generation from the same set of plants, and
multiplied by a unit conversion factor, in lb/MWh.
47. - State Ozone Season NOx Coal, Oil, Gas, and Fossil Fuel Output Emission
50. Rates -
The descriptions of the ozone season NOx fields, in lb/MWh, contain the same
information as annual NOx fields #43 through #46, respectively. The state ozone
season combustion net generation, used in the denominator of the equations, is
calculated as the ratio of the state annual to ozone season net generation for that fuel
times the state annual combustion net generation.
51. - State Annual SO2 Coal, Oil, Gas, and Fossil Fuel Output Emission
54. Rates -
The descriptions of the annual SO2 fields, in lb/MWh, contain the same information
as annual NOx fields #43 through #46, respectively.
55. - State Annual CO2 Coal, Oil, Gas, and Fossil Fuel Output Emission
58. Rates -
The descriptions of annual CO2 fields, in lb/MWh, contain the same information as
annual NOx fields #43 through #46, respectively.
59. - State Annual CH4 Coal, Oil, Gas, and Fossil Fuel Output Emission
62. Rates -
The descriptions of annual CH4 fields, in lb/MWh, contain the same information as
annual NOx fields #43 through #46, respectively.
63. - State Annual N2O Coal, Oil, Gas, and Fossil Fuel Output Emission
66. Rates -
The descriptions of annual N2O fields, in lb/MWh, contain the same information as
annual NOx fields #43 through #46, respectively.
67. - State Annual CO2 Equivalent Coal, Oil, Gas, and Fossil Fuel Output Emission
70. Rates -
The descriptions of annual CO2 equivalent fields, in lb/MWh, contain the same
information as annual NOx fields #43 through #46, respectively.
71. - State Annual Hg Coal, Oil, Gas, and Other Fossil Fuel Output Emission
72. Rates -
Not calculated.
73. - State Annual NOx, Ozone Season NOx, Annual SO2, Annual CO2, Annual CH4,
102. Annual N2O, Annual CO2 Equivalent Coal, Oil, Gas, and Fossil Fuel Input
Emission Rates; and Annual Hg Coal and Fossil Fuel Input Emission Rates -
The descriptions of these fields, primary fuel-specific input emission rates, contain
the same information that fields #43 through #46 do for primary fuel-specific output
emission rates - except that the calculations include heat input, rather than net
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103
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
DESCRIPTION OF DATA ELEMENTS
generation. These values are calculated in the same manner as the input emission
rates, using heat input in place of generation.
State Annual NOx, Ozone Season NOx, Annual SO2, Annual CO2, Annual CH4,
Annual N2O, Annual CO2 Equivalent, and Annual Hg Nonbaseload Output
Emission Rate -
These fields, in lb/MWh, are calculated as the sum of the annual nonbaseload NOx,
ozone season nonbaseload NOx, annual nonbaseload SO2, annual nonbaseload CO2,
annual nonbaseload CH4, annual nonbaseload N2O, and annual nonbaseload CO2
equivalent emissions divided by the sum of annual nonbaseload net generation in the
state and then multiplied by a unit conversion factor. These fields are intended to
provide a more refined estimate of avoided emissions than the fossil-fuel average
output emission rate. The nonbaseload emissions and generation include only
emissions and generation from combustion sources and exclude emissions and
generation from plants that have high capacity factors. The remaining emissions and
generation are weighted by a factor which is a function of capacity factor. For more
information, see Section 3.1.3 on emission rate estimates.
State Annual Coal Net Generation (STGENACL) -
State Annual Oil Net Generation (STGENAOL)-
State Annual Gas Net Generation (STGENAGS) -
State Annual Nuclear Net Generation (STGENANC) -
State Annual Hydro Net Generation (STGENAHY)-
State Annual Biomass Net Generation (STGENABM) -
State Annual Wind Net Generation (STGENAWI) -
State Annual Solar Net Generation (STGENASO) -
State Annual Geothermal Net Generation (STGENAGT) -
State Annual Other Fossil Net Generation (STGENAOF) -
State Annual Other Unknown/Purchased Fuel Net Generation (STGENAOP)-
State Annual Total Nonrenewables Net Generation (STGENATN)-
State Annual Total Renewables Net Generation (STGENATR) -
State Annual Total Nonhydro Renewables Net Generation (STGENATH)-
State Annual Total Combustion Net Generation (STGENACY) -
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DESCRIPTION OF DATA ELEMENTS
126. State Annual Total Noncombustion Net Generation (STGENACN) -
127. State Coal Generation Percent (STCLPR) -
128. State Oil Generation Percent (STOLPR) -
129. State Gas Generation Percent (STGSPR) -
130. State Nuclear Generation Percent (STNCPR) -
131. State Hydro Generation Percent (STHYPR) -
132. State Biomass Generation Percent (STBMPR) -
133. State Wind Generation Percent (STWIPR) -
134. State Solar Generation Percent (STSOPR) -
135. State Geothermal Generation Percent (STGTPR) -
136. State Other Fossil Generation Percent (STOFPR) -
137. State Other Unknown/Purchased Fuel Generation Percent (STOPPR) -
138. State Total Nonrenewables Generation Percent (STTNPR) -
139. State Total Renewables Generation Percent (STTRPR) -
140. State Total Nonhydro Renewables Generation Percent (STTHPR) -
141. State Total Combustion Generation Percent (STCYPR) -
142. State Total Noncombustion Generation Percent (STCNPR) -
143. State Annual Nonbaseload Coal Net Generation (STNBGNCL) -
144. State Annual Nonbaseload Oil Net Generation (STNBGNOL) -
145. State Annual Nonbaseload Gas Net Generation (STNBGNGS) -
146. State Annual Nonbaseload Nuclear Net Generation (STNBGNNC) -
147. State Annual Nonbaseload Hydro Net Generation (STNBGNHY) -
148. State Annual Nonbaseload Biomass Net Generation (STNBGNBM) -
149. State Annual Nonbaseload Wind Net Generation (STNBGNWT) -
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DESCRIPTION OF DATA ELEMENTS
150. State Annual Nonbaseload Solar Net Generation (STNBGNSO) -
151. State Annual Nonbaseload Geothermal Net Generation (STNBGNGT) -
152. State Annual Nonbaseload Other Fossil Net Generation (STNBGNOF) -
153. State Annual Nonbaseload Other Unknown/Purchased Fuel Net Generation
(STNBGNOP) -
154. State Nonbaseload Coal Generation Percent (STNBCLPR) -
155. State Nonbaseload Oil Generation Percent (STNBOLPR) -
156. State Nonbaseload Gas Generation Percent (STNBGSPR) -
157. State Nonbaseload Nuclear Generation Percent (STNBNCPR) -
158. State Nonbaseload Hydro Generation Percent (STNBHYPR) -
159. State Nonbaseload Biomass Generation Percent (STNBBMPR) -
160. State Nonbaseload Wind Generation Percent (STNBWIPR) -
161. State Nonbaseload Solar Generation Percent (STNBSOPR) -
162. State Nonbaseload Geothermal Generation Percent (STNBGTPR) -
163. State Nonbaseload Other Fossil Generation Percent (STNBOFPR) -
164. State Nonbaseload Other Unknown/Purchased Fuel Generation Percent
(STNBOPPR) -
5.5 The BA (Balancing Authority) File
There are 164 variables in the fifth file, BA, which contains location (operator)-based balancing
authority data. All generation and emission values are derived by aggregating from the plant level
based on the associated balancing authority.
All variables have been described in previous file variable descriptions. Aggregated variable names
generally begin with "BA."
5.6 The SRL (eGRID Subregion) File
There are 164 variables in the sixth file, SRL, which contains location (operator)-based eGRID
subregions. All generation and emission values are derived by aggregating from the plant level based
on the associated eGRID subregion.
All other variables in the eGRID Subregion file have been described in previous file variable
descriptions. Aggregated variable names generally begin with "SR."
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DESCRIPTION OF DATA ELEMENTS
5.7 The NRL (NERC Region) File
There are 164 variables in the seventh file, NRL, which contains location (operator)-basedNERC
region data. All generation and emission values are derived by aggregating from the plant level based
on the associated NERC region.
The only variable in this file that has not been described in a previous file variable description is
NERCNAME, the NERC region name associated with the NERC region acronym (see Section 3.4.1).
Aggregated variable names generally begin with "NR."
5.8 The US (U.S.) File
There are 162 variables in the eighth file, US, which contains data for the entire United States. All
generation and emission values are derived by aggregating from the plant level. All variables have
been described in previous file variable descriptions. Aggregated variable names generally begin with
"US."
5.9 The Regional Grid Gross Loss File
There are five variables in the GGL file, reported in eGRID at the regional level based on the
aforementioned aggregated state level data:
1. Data Year (YEAR) -
The current eGRID data year.
2. REGION
One of the three interconnect power grids in the U. S.: Eastern, Western, or ERCOT,
plus the states of Alaska and Hawaii, and the entire U. S.
3. Estimated Losses (ESTLOSS)
The total amount of electricity, in MWh, in the region that is generated but is not sold
for resale or wholesale, furnished without charge, or used by the generator or utility;
i.e., electricity that is lost in transmission and distribution.
Source: EI A State Electricity Profiles, Supply and disposition of electricity, 1990-
2020.
4. Total Disposition without Exports (TOTDISP)
The total amount of electricity, in MWh, in the region that is sold directly to
customers, sold for resale, furnished without charge, consumed by the respondent
without charge, and lost; i.e., all electricity generated, without exports.
Source: EIA State Electricity Profiles, Supply and disposition of electricity, 1990-
2020.
5. Direct Use (DIRCTUSE)
The total amount of electricity, in MWh, used by plants and/or utilities in the region
that is not sold for wholesale or resale; direct use electricity is not transmitted
through the grid and therefore does not have the potential to be lost.
Source: EIA State Electricity Profiles, Supply and disposition of electricity, 1990-
2020.
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DESCRIPTION OF DATA ELEMENTS
6. Grid Gross Loss (GGRSLOSS)
The estimated grid gross loss as a percent. The formula used is
[ESTLOSS/(TOTDISP - DIRCTUSE)]*100
The grid gross loss values can be used when applying eGRID GHG factors (eGRID subregion annual
GHG total output emission rates) to consumption. Specifically, to account for indirect emissions
associated with consumption of electricity (both from generation and from transmission and
distribution line losses) divide the product of the electricity consumption and the generation based
eGRID total output emission rates by (one minus the grid gross loss as a decimal). See the equation
below:
GHGemis cons= GHGemis rate * Consumption/ (l-ggl%/100)/2000
Where;
GHG emis cons = a specified GHG emission associated with a certain amount of electricity
consumption (generation and line losses) in short tons,
GHG emis rate = eGRID subregion annual total output emission rate in lb/MWh for a
specified GHG,
Consumption = the given electricity consumption in MWh (kWh/1000), and
ggl% = the estimated regional grid gross loss as a percent.
If reporting the indirect emissions for the electricity generation (scope 2 emissions) separately from
the indirect emissions as a result of transmission and distribution line losses (scope 3 emissions), then
the scope 2 emissions are simply the consumption in MWh multiplied by the eGRID subregion
annual total output emission rate in lb/MWh, and the scope 3 emissions are calculated in the
following equation:
GHG emis 11 = GHG emis rate * Consumption * (ggl%/100) / (l-ggl%/100)/2000
Where;
GHG emis 11 = a specified GHG emission associated with the line losses of a certain amount
of electricity consumption in short tons,
GHG emis rate = eGRID subregion annual total output emission rate in lb/MWh for a
specified GHG,
Consumption = the given electricity consumption in MWh (= kWh/1000), and
ggl% = the estimated regional grid gross loss as a percent.
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^*ERENCES
6. References
CARB, 2007: California Air Resources Board "Regulation for the Mandatory Reporting of
Greenhouse Gas Emissions (AB 32 requirements)" Table 5 in Appendix A, December 2007.
http://www. arb. ca. gov/regact/2007/ghg2007/frofinoal.pdf
Carbon Visuals, 2016: "Visualizing the carbon footprint of all US power stations,"
http://www.carbonvisuals. com/projects/2015/6/23/visualising-the-carbon-footprint-of-all-us-
power-stations?rq=eGRID
Cooley et al., 2019: "EPA's Emissions & Generation Resource Integrated Database (eGRID):
Improvements and Applications" presented at the 17th Annual Community Modeling and
Analysis System Conference. https://www. cmascenter.org/conference/2018/agenda.cfm
Diem, Salhotra and Quiroz, 2013: Diem, A., M. Salhotra, and C. Quiroz, "Using EPA's eGRID to
Estimate GHG Emissions Reductions from Energy Efficiency" International Energy Program
Evaluation Conference, Chicago IL, August 2013.
Diem and Quiroz, 2013: Diem, A. and C. Quiroz, "Using eGRID Data for Carbon Footprinting
Electricity Purchases," Energy, Utility, and Environment Conference, Phoenix, Arizona, January
2013.
Diem and Quiroz, 2012: Diem, A., and C. Quiroz, "How to use eGRID for Carbon Footprinting
Electricity Purchases in Greenhouse Gas Emission Inventories" presented at the U. S.
Environmental Protection Agency 2012 International Emission Inventory Conference, Tampa,
Florida, August 2012.
https://www3.epa.gov/ttnchiel/conference/ei20/session3/adiem.pdf
Dorn et al., 2019a: "EPA's Emissions & Generation Resource Integrated Database (eGRID): Updates
and Improvements," presented at the 18th Annual Community Modeling and Analysis System
Conference. https://www. cmascenter. org/conference/20191 agenda, cfm
Dorn et al., 2019b: "Adding Particulate Matter to EPA's eGRID Database," presented at the 2019
International Emissions Inventory Conference, https://www.epa. gov/sites/production/files/2019-
08/documents/825am dorn.pdf
Dorn et al., 2015: "EPA's Emissions & Generation Resource Integrated Database (eGRID):
Improvements and Applications," presented at the Community Modeling and Analysis System
Conference. https://www. cmascenter. org/conference/2015/agenda, cfm
DOE, 2021: U. S. Department of Energy, Energy Efficiency and Renewable Energy, Combined Heat
and Power Installation Database, https://doe.icfwebservices. com/chp
DVRPC, 2010: Delaware Valley Regional Planning Commission, Regional Greenhouse Gas
Emissions Inventory, revised December 2010.
http://www.dvrpc.org/reports/09038A.pdf
EIA, 2021a: Energy Information Administration, "2020 Annual Electric Generator Report," Form
EI A-860, Washington, DC, 2021.
https://www, eia. gov/electricity/data/eia860/
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^*ERENCES
EIA, 2021b: Energy Information Administration, "Preliminary Monthly Electric Generator Inventory,
December 2020," Form EIA-860M, Washington, DC, 2021.
https://www. eia. gov/electricity/data/eia860m/
EIA, 2021c: Energy Information Administration, "2020 Power Plant Operations Report," FormEIA-
923, Washington, DC, 2021.
https://www. eia. gov/electricity/data/eia923/
EIA, 2021d: Energy Information Administration, "2020 Annual Electric Power Industry Report,"
Form EIA-861, Washington, DC, 2021.
https://www. eia. gov/electricity/data/eia861/
EIA, 2021e: Energy Information Administration, "2020 State Electricity Profiles."
http ://www. eia. gov/electricity/state/
EIA, 2021f: Energy Information Administration, "Electric Power Annual," Tables A-l and A-2,
Washington, DC, 2021. https://www. eia. gov/electricity/annual/
EPA, 2021: EPA Center for Corporate Climate Leadership, https://www.epa.gov/climateleadership
EPA, 2017: Inventory of U.S. Greenhouse Gas Emissions and Sinks: 1990-2015.
https://www.epa.gov/ghgemissions/inventorv-us-greenhouse-gas-emissions-and-sinks-1990-2015
EPA, 2016: LFG Energy Project Development Handbook. Landfill Methane Outreach Program.
https://www.epa.gov/sites/production/files/2016-ll/documents/pdh full.pdf
EPA, 1995: U.S. Environmental Protection Agency, "Compilation of Air Pollutant Emission Factors,
Volume I: Stationary Point and Area Source, AP-42, Fifth Edition." https://www.epa. gov/air-
emissions-factors-and-quantification/ap-42-compilation-air-emission-factors
EPA, 2009: U.S. Environmental Protection Agency, Final Mandatory Reporting of Greenhouse Gases
Rule (Table C-l, Default CO2 Emission Factors and High Heat Values for Various Types of Fuel
and Table C-2, Default CH4 and N2O Emission Factors for Various Types of Fuel), Washington,
D C., October 30, 2009.
https://www.epa.gov/sites/production/files/2015-06/documents/ghg-mrr-finalrule.pdf
FERC, 2019: United States Federal Energy Regulatory Commission, "FERC Approves Petition for
FRCC RE Dissolution Actions." https://www.nerc.com/news/Pages/FERC-Approves-Petition-
for-FRCC-RE-Dissolution-Actions-.aspx
GEA, 2007: AlyssaKagel, Diana Bates, and Karl Gawell. Table 3, Air Emissions Summary, in "A
Guide to Geothermal Energy and the Environment", Geothermal Energy Association,
Washington, D.C., April 2007.
https://www. osti. gov/servlets/purl/897425-q5NDer/
GEA, 2016: Geothermal Energy Association [now Geothermal Rising], geothermal plant type from
annual power production reports, http://geo-energv.org/reports.aspx.
Greenhouse Gas Protocol, 2016: The Greenhouse Gas Protocol, http://www.ghgprotocol.org/
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^*ERENCES
Hoer et al., 2019: "Adding Particulate Matter to EPA's eGRID Database," presented at the Air and
Waste Management Association's 112th Annual Conference & Exhibition.
https://www.awma.org/files/ACE%202019/ACEFinalProgram2019-FINAL-6-5-2019.pdf
Huetteman et al., 2021: "Using eGRID for Environmental Footprinting of Electricity Purchases,"
https://www. epa. gov/egrid/egrid-environmental-footprinting
IPCC, 2007a: The Intergovernmental Panel on Climate Change (IPCC), "2006IPCC Guidelines for
National Greenhouse Gas Inventories", volume 2 (Energy), April 2007.
http://www.ipcc-
nggip.iges.or.jp/public/2006gl/pdl72 Volume2/V2 2 Ch2 Stationary Combustion.pdf
IPCC, 2007b: The Intergovernmental Panel on Climate Change (IPCC), "Climate Change 2007: The
Physical Science Basis," 2007.
https://www.ipcc.ch/site/assets/uploads/2018/05/ar4 wgl full report-l.pdf
Johnson, 2016a: Travis Johnson, "How Part 75 Data is Used in GHG Reporting and EE/RE
Quantification," EPRI Continuous Emissions Monitoring User Group Conference, Detroit, MI,
May 2016.
Johnson, 2016b: Travis Johnson, "Emissions & Generation Resource integrated Database (eGRID),"
Energy, Utility, and Environment Conference, San Diego, CA, February 2016.
Johnson, Schreifels, and Quiroz, 2015: Johnson, T., J. Schreifels, and C. Quiroz, "eGRID Updates."
Energy, Utility, and Environment Conference, San Diego, CA, February 2015.
Jones and Kammen, 2013: "Data & Calculations for "Quantifying Carbon Footprint Reduction
Opportunities for U.S. Households" Cool Climate Network Maps
https://docs.google.eom/file/d/0BwI9ptFQUlQiM2IzNWE0YTQtNiY4NS00MzM5LWFkZDUt
O WNkY 2NkNTMxOTM4
http: //cool climate, berkeley. edu/ maps
Maryland, 2010: Maryland Department of the Environment, Technical Support Document for
Amendments to COMAR 26.09 MD CO2 Budget Training Program, Baltimore, MD, October 25,
2010.
http://www.mde.state.mdus/programs/Air/ClimateChange/RGGI/Documents/TSD MD CQ2 B
udgetTradingProgram Amendment.pdf
NERC, 2020: North American Electric Reliability Corporation, "ERO Enterprise Regional Entities,"
https://www.nerc.com/AboutNERC/keyplavers/Pages/default.aspx
TCR, 2019: The Climate Registry, "General Reporting Protocol Version 3.0,"
https://www.theclimateregistrv.org/tools-resources/reporting-protocols/general-reporting-
protocol/
UCS, 2012: Union of Concerned Scientists, "State of Charge: Electric Vehicles' Global Warming
Emissions and Fuel-Cost Savings Across the United States, April 2012."
http://www.ucsusa.org/clean vehicles/technologies and fuels/hybrid fuelcell and electric vehi
cles/emissions-and-charging-costs-electric-
cars.html?utm source=SP&utm medium=head&utm campaign=EV%2BReport
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^*ERENCES
US Census, 2020: United States Census Bureau, "2020 Population Estimates FIPS Codes,"
https://www. census, gov/geographies/reference-files/2020/demo/popest/2020-fips.htmll
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APPENDIX A
Appendix A. eGRID File Structure-Variable Descriptions for
eGRID2020
The structure of the nine files - including descriptions of the variables, unit of measurement, and
original source(s) of data - are delineated below in the file structure. NOTE: Italics indicates new
field; bold indicates methodological change. Units in the following tables represent the units in the
English unit eGRID2020 workbook.
Table A-1. eGRID File Structure, eGRID2020 UNIT File
Field
Name
Description
Unit
Source(s)
1
SEQUNT20
eGRID2020 file unit sequence number
assigned
2
YEAR
Data year
3
PSTATABB
Plant state abbreviation
EIA-860
4
PNAME
Plant name
EPA/CAMD
5
ORISPL
DOE/EIA ORIS plant orfacility code
EPA/CAMD, EIA-860
6
UNITID
Unit ID
EPA/CAMD, EIA-923
7
PRMVR
Prime Mover
EPA/CAMD, EIA-860
8
UNTOPST
Unit operational status
EPA/CAMD, EIA-860
9
CAMDFLAG
CAMD Program flag
EPA/CAMD
10
PRGCODE
Program code(s)
EPA/CAMD
11
BOTFIRTY
Boilerbottom and firing type
EPA/CAMD, EIA-860
12
NUMGEN
Numberofassociated generators
EIA-860
13
FUELU1
Unit primary fuel
EPA/CAMD, EIA-923, EIA-860
14
HRSOP
Unit operating hours
hours
EPA/CAMD
15
HTIAN
Unit unadjusted annual heat input
MMBtu
EPA/CAMD, EIA-923
16
HTIOZ
Unit unadjusted ozone season heat input
MMBtu
EPA/CAMD, EIA-923
17
NOXAN
Unit unadjusted annual NOxemissions
tons
EPA/CAMD, EIA-923
18
NOXOZ
Unit unadjusted ozone season NOx emissions
tons
EPA/CAMD, EIA-923
19
S02AN
Unit unadjusted annual S02emissions
tons
EPA/CAMD
20
C02AN
Unit unadjusted annual C02emissions
tons
EPA/CAMD
21
HGAN
Unit unadjusted annual mercury emissions
lbs
EPA/CAMD
22
HTIANSRC
Unit unadjusted annual heat input source
EPA/CAMD, EIA-923
23
HTIOZSRC
Unit unadjusted ozone season heat input source
EPA/CAMD, EIA-923
24
NOXANSRC
Unit unadjusted annual NOx emissions source
EPA/CAMD, EIA-923
25
NOXOZSRC
Unit unadjusted ozone season NOx emissions
source
EPA/CAMD, EIA-923
26
S02SRC
Unit unadjusted annual S02emissionssource
EPA/CAMD, EIA-923
27
C02SRC
Unit unadjusted annual C02emissionssource
EPA/CAMD, EIA-923
28
HGSRC
Unit unadjusted annual mercury emissions source
EPA/CAMD
29
S02CTLDV
Unit S02 (scrubber) first control device
EPA/CAMD, EIA-860
30
NOXCTLDV
Unit NOx first control device
EPA/CAMD; EIA-860
31
HGCTLDV
Unit Hg activated carbon injection system flag
EIA-860
32
UNTYRONL
Unit yearon-line
EPA/CAMD, EIA-860
Technical Guide for eGRID2020
I P9- 78
-------�
Field
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
APPENDIX A
Table A-2. eGRID File Structure, eGRID2020 GEN Generator File
Name
Description
Unit
Source(s)
SEQGEN20
eGRID2020 file generatorsequence number
assigned
YEAR
Data year
PSTATABB
Plant state abbreviation
EIA-860
PNAME
Plant name
EPA/CAMD; EIA-860
ORISPL
DOE/EIA ORIS plant orfacility code
EPA/CAMD; EIA-860
GENID
Generator ID
EIA-860
NUMBLR
Numberof associated boilers
EIA-860
GENSTAT
Generatorstatus
EIA-860
PRMVR
Generator prime movertype
EIA-860
FUELG1
Generator primary fuel
EIA-860
NAMEPCAP
Generator nameplate capacity
MW
EIA-860
CFACT
Generatorcapacity factor
calculated
GENNTAN
Generatorannual net generation
MWh
EIA-923
GENNTOZ
Generatorozone season net generation
MWh
EIA-923
GENERSRC
Generation data source
assigned
GENYRONL
Generator year on-line
EIA-860
GENYRRET
Generator year retired
EIA-860
Technical Guide for eGRI D2020
I pg- 79
-------�
APPENDIX A
Table A-3. eGRID File Structure, eGRID2020 PLNT Plant File
Field
Name
Description
Unit
Source(s)
1
SEQPLT20
eGRID 2020 file plant sequence number
assigned
2
YEAR
Data year
3
PSTATABB
Plant state abbreviation
EIA-860
4
PNAME
Plant name
EPA/CAMD; EIA-860
5
ORISPL
DOE/EIA ORIS plant orfacility code
EPA/CAMD; EIA-860
6
OPRNAME
Plant operatorname
EIA-860
7
OPRCODE
Plant operatorlD
EIA-860
8
UTLSRVNM
Utility service territory name
EIA-860
9
UTLSRVID
Utility service territory ID
EIA-860
10
SECTOR
Plant-level sector
EIA-860
11
BANAME
Balancing authority name
EIA-860; EIA-861
12
BACODE
Balancing authority ID code
EIA-860; EIA-861
13
NERC
NERC region acronym
EIA-860
14
SUBRGN
eGRIDsubregion acronym
EPA
15
SRNAME
eGRIDsubregion name
EPA
16
ISORTO
Plant associated ISO/RTO Territory
EIA-860
17
FIPSST
Plant FIPS state code
US Census
18
FIPSCNTY
Plant FIPS county code
US Census
19
CNTYNAME
Plant county name
EIA-860
20
LAT
Plant latitude
EIA-860
21
LON
Plant longitude
EIA-860
22
NUMUNT
Numberof units
EIA-860
23
NUMGEN
Number of generators
EIA-860
24
PLPRMFL
Plant primary fuel
EPA/CAMD; EIA-923
25
PLFUELCT
Plant primary fuel category
assigned
26
COALFLAG
Flag indicating if the plant burned orgenerated
anyamountofcoal
assigned
27
CAPFAC
Plant capacity factor
calculated
28
NAMEPCAP
Plant nameplate capacity
MW
EIA-860
29
NBFACTOR
Plant nonbaseload factor
calculated
30
RMBMFLAG
Biogas/biomass plant adjustment flag
assigned
31
CHPFLAG
Combined heatand power(CHP)plant
adjustment flag
EPA/CAMD; EIA-860
32
USETHRMO
CHP plantusefulthermaloutput
MMBtu
EIA-923 calculated
33
PWRTOHT
CHP plant powerto heat ratio
calculated
34
ELCALLOC
CHP plant electric allocation factor
calculated
35
PSFLAG
Plant pumped storage flag
EIA-860
36
PLHTIAN
Plant annual heat inputforcombustion units
MMBtu
EPA/CAMD; EIA-923
37
PLHTIOZ
Plant ozone season heat input forcombustion
units
MMBtu
EPA/CAMD; EIA-923
38
PLHTIANT
Plant annual heat inputforall units
MMBtu
EPA/CAMD; EIA-923
39
PLHTIOZT
Plant ozone season heat input forall units
MMBtu
EPA/CAMD; EIA-923
40
PLNGENAN
Plant annual net generation
MWh
EIA-923, EPA/CAMD
41
PLNGENOZ
Plant ozone season net generation
MWh
EIA-923, EPA/CAMD
42
PLNOXAN
Plant annual NOx emissions
tons
EPA/CAMD; calculated
43
PLNOXOZ
Plant ozone season NOx emissions
tons
EPA/CAMD; calculated
44
PLS02AN
Plant annual S02emissions
tons
EPA/CAMD; calculated
45
PLC02AN
Plant annual C02emissions
tons
EPA/CAMD; calculated
46
PLCH4AN
Plant annual CH4 emissions
lbs
calculated
47
PLN20AN
Plant annual N20 emissions
lbs
calculated
Technical Guide for eGRI D2020
I pg- 80
-------�
APPENDIX A
Field
Name
Description
Unit
Source(s)
48
PLC02EQA
Plant annual C02 equivalent emissions ((1 *
PLC02AN) + (25 * PLCH4AN/2000) + (298 *
PLN20A N/2000))
tons
calculated
49
PLHGAN
Plant annual Hg emissions
lbs
not calculated
50
PLNOXRTA
Plant annual NOx total output emission rate
Ib/MWh
calculated
51
PLNOXRTO
Plant ozone season NOx total output emission
rate
Ib/MWh
calculated
52
PLS02RTA
Plant annual S02 total output emission rate
Ib/MWh
calculated
53
PLC02RTA
Plant annual C02 total output emission rate
Ib/MWh
calculated
54
PLCH4RTA
Plant annual CH4total output emission rate
Ib/MWh
calculated
55
PLN20RTA
Plant annual N20 total output emission rate
Ib/MWh
calculated
56
PLC2ERTA
Plant annual C02equivalent total output
emission rate
Ib/MWh
calculated
57
PLHGRTA
Plant annual Hg total outputemission rate
Ib/MWh
not calculated
58
PLNOXRA
Plant annual NOx input emission rate
Ib/MMBtu
calculated
59
PLNOXRO
Plant ozone season NOx input emission rate
Ib/MMBtu
calculated
60
PLS02RA
Plant annual S02 input emission rate
Ib/MMBtu
calculated
61
PLC02RA
Plant annual C02 input emission rate
Ib/MMBtu
calculated
62
PLCH4RA
Plant annual CH4 input emission rate
Ib/MMBtu
calculated
63
PLN20RA
Plant annual N20 input emission rate
Ib/MMBtu
calculated
64
PLC2ERA
Plant annual C02equivalent input emission rate
Ib/MMBtu
calculated
65
PLHGRA
Plant annual Hg input emission rate
Ib/MMBtu
not calculated
66
PLNOXCRT
Plant annual NOx combustion output emission
rate
Ib/MWh
calculated
67
PLNOXCRO
Plant ozone season NOx combustion output
emission rate
Ib/MWh
calculated
68
PLS02CRT
Plant annual S02 combustion output emission
rate
Ib/MWh
calculated
69
PLC02CRT
Plant annual C02 combustion outputemission
rate
Ib/MWh
calculated
70
PLCH4CRT
Plant annual CH4 combustion output emission
rate
Ib/MWh
calculated
71
PLN20CRT
Plant annual N20 combustion outputemission
rate
Ib/MWh
calculated
72
PLC2ECRT
Plant annual C02 equivalent combustion output
emission rate
Ib/MWh
calculated
73
PLHGCRT
Plant annual Hg combustion output emission
rate
Ib/MWh
not calculated
74
UNNOX
Plant unadjusted annual NOx emissions
tons
EPA/CAMD, EIA-923
75
UNNOXOZ
Plant unadjusted ozone season NOx emissions
tons
EPA/CAMD, EIA-923
76
UNS02
Plant unadjusted annual S02emissions
tons
EPA/CAMD, EIA-923
77
UNC02
Plant unadjusted annual C02emissions
tons
EPA/CAMD, EIA-923
78
UNCH4
Plant unadjusted annual CH4emissions
lbs
EPA/CAMD, EIA-923
79
UNN20
Plant unadjusted annual N20 emissions
lbs
EPA/CAMD, EIA-923
80
UNHG
Plant unadjusted annual Hg emissions
lbs
not calculated
81
UNHTI
Plant unadjusted annual heat input for
combustion units
MMBtu
EPA/CAMD, EIA-923
82
UNHTIOZ
Plant unadjusted ozone season heat input for
combustion units
MMBtu
EPA/CAMD, EIA-923
83
UNHTIT
Plant unadjusted annual heat input forall units
MMBtu
EPA/CAMD, EIA-923
84
UNHTIOZT
Plant unadjusted ozone season heat input forall
units
MMBtu
EPA/CAMD, EIA-923
85
UNNOXSRC
Plant unadjusted annual NOx emissions source
EPA/CAMD, EIA-923
86
UNNOZSRC
Plant unadjusted ozone season NOx emissions
source
EPA/CAMD, EIA-923
87
UNS02SRC
Plant unadjusted annual S02 emissions source
EPA/CAMD, EIA-923
88
UNC02SRC
Plant unadjusted annual C02 emissions source
EPA/CAMD, EIA-923
Technical Guide for eGRI D2020
I pg- 81
-------�
APPENDIX A
Field
Name
Description
Unit
Source(s)
89
UNCH4SRC
Plant unadjusted annual CH4 emissions source
EPA/CAMD, EIA-923
90
UNN20SRC
Plant unadjusted annual N20 emissions source
EPA/CAMD, EIA-923
91
UNHGSRC
Plant unadjusted annual Hg emissions source
calculated
92
UNHTISRC
Plant unadjusted annual heat input source
EPA/CAMD, EIA-923
93
UNHOZSRC
Plant unadjusted ozone season heat input
source
EPA/CAMD, EIA-923
94
BIONOX
Plant annual NOx bio mass emissions
tons
EIA-923
95
BIONOXOZ
Plant ozone season NOx bio mass emissions
tons
EIA-923
96
BIOS02
Plant annual S02 bio mass emissions
tons
EIA-923
97
BIOC02
Plant annual C02 bio mass emissions
tons
EIA-923
98
BIOCH4
Plant annual CH4 bio mass emissions
lbs
EIA-923
99
BION20
Plant annual N20 bio mass emissions
lbs
EIA-923
100
CHPCHTI
Plant combustion heat input CHP adjustment
value
MMBtu
calculated
101
CHPCHTIOZ
Plant combustion ozone season heat inputCHP
adjustment value
MMBtu
calculated
102
CHPNOX
Plant annual NOx emissions CHP adjustment
value
tons
calculated
103
CHPNOXOZ
Plant ozone season NOx emissions CHP
adjustment value
tons
calculated
104
CHPS02
Plant annual S02 emissions CHP adjustment
value
tons
calculated
105
CHPC02
Plant annual C02 emissions CHP adjustment
value
lbs
calculated
106
CHPCH4
Plant annual CH4 emissions CHP adjustment
value
lbs
calculated
107
CHPN20
Plant annual N20 emissions CHP adjustment
value
lbs
calculated
108
PLHTRT
Plant nominal heat rate
Btu/kWh
calculated
109
PLGENACL
Plant annual coal net generation
MWh
EIA-923
110
PLGENAOL
Plant annual oil net generation
MWh
EIA-923
111
PLGENAGS
Plant annual gas net generation
MWh
EIA-923
112
PLGENANC
Plant annual nuclearnet generation
MWh
EIA-923
113
PLGENAHY
Plant annual hydro net generation
MWh
EIA-923
114
PLGENABM
Plant annual bio mass net generation
MWh
EIA-923
115
PLGENAWI
Plant annual wind net generation
MWh
EIA-923
116
PLGENASO
Plant annual solar net generation
MWh
EIA-923
117
PLGENAGT
Plant annual geothermal net generation
MWh
EIA-923
118
PLGENAOF
Plant annual otherfossil net generation
MWh
EIA-923
119
PLGENAOP
Plant annual other unknown/purchased fuel net
generation
MWh
EIA-923
120
PLGENATN
Plant annual total nonrenewables net generatbn
MWh
EIA-923
121
PLGENATR
Plant annual total renewables net generation
MWh
EIA-923
122
PLGENATH
Plant annual total nonhydro renewables net
generation
MWh
EIA-923
123
PLGENACY
Plant annual total combustion net generation
MWh
EIA-923
124
PLGENACN
Plant annualtotal noncombustion net generatbn
MWh
EIA-923
125
PLCLPR
Plant coal generation percent (resource mix)
%
calculated
126
PLOLPR
Plant oil generation percent (resource mix)
%
calculated
127
PLGSPR
Plant gas generation percent (resource mix)
%
calculated
128
PLNCPR
Plant nucleargeneration percent (resource mix)
%
calculated
129
PLHYPR
Plant hydro generation percent (resource mix)
%
calculated
130
PLBMPR
Plant bio mass generation percent (resource
mix)
%
calculated
131
PLWIPR
Plant wind generation percent (resource mix)
%
calculated
132
PLSOPR
Plant solargeneration percent(resource mix)
%
calculated
Technical Guide for eGRI D2020
I pg- 82
-------�
APPENDIX A
Field
Name
Description
Unit
Source(s)
133
PLGTPR
Plant geothermal generation percent (resource
mix)
%
calculated
134
PLOFPR
Plant otherfossil generation percent (resource
mix)
%
calculated
135
PLOPPR
Plant otherunknown/purchased fuel generation
percent (resource mix)
%
calculated
136
PLTNPR
Plant total nonrenewables generation percent
(resource mix)
%
calculated
137
PLTRPR
Plant total renewables generation percent
(resource mix)
%
calculated
138
PLTHPR
Plant total nonhydro renewables generation
percent (resource mix)
%
calculated
139
PLCYPR
Plant total combustion generation percent
(resource mix)
%
calculated
140
PLCNPR
Plant total noncombustion generation percent
(resource mix)
%
calculated
Technical Guide for eGRI D2020
I pg- 83
-------�
Field
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
APPENDIX A
Table A-4. eGRID File Structure, eGRID2020 ST State File
Name
Description
YEAR
Data year
PSTATABB
State abbreviation
FIPSST
FIPS state code
STNAMEPCAP
State nameplate capacity
STHTIAN
ate annual heatinput from combustion
STHTIOZ
ate ozone season heat input from combustion
STHTIANT
ate total annual heat input
STHTIOZT
ate total ozone season heatinput
STNGENAN
ate annual net generation
STNGENOZ
ate ozone season net generation
STNOXAN
ate annual NOxemissions
STNOXOZ
ate ozone season NOx emissions
STS02AN
ate annual S02emissions
STC02AN
ate annual C02emissions
STCH4AN
ate annual CH4emissions
STN20AN
ate annual N20 emissions
STC02EQA
ate annual C02equivalent emissions
STHGAN
ate annual Hg emissions
STNOXRTA
ate annual NOxtotal outputemission rate
STNOXRTO
ate ozone season NOx total output emission rate
STS02RTA
ate annual S02total output emission rate
STC02RTA
ate annual C02total output emission rate
STCH4RTA
ate annual Cl-U total output emission rate
STN20RTA
ate annual N20 total output emission rate
STC2ERTA
ate annual C02equivalent total output emission rate
STHGRTA
ate annual Hg total output emission rate
STNOXRA
ate annual NOx input emission rate
STNOXRO
ate ozone season NOx input emission rate
STS02RA
ate annual S02 input emission rate
STC02RA
ate annual C02 input emission rate
STCH4RA
ate annual CH4 input emission rate
STN20RA
ate annual N20 input emission rate
STC2ERA
ate annual C02equivalent input emission rate
STHGRA
ate annual Hg input emission rate
STNOXCRT
ate annual NOx combustion output emission rate
STNOXCRO
ate ozone season NOx combustion output emission rate
STS02CRT
ate annual S02combustion outputemission rate
STC02CRT
ate annual C02combustion output emission rate
STCH4CRT
ate annual CH4 combustion outputemission rate
STN20CRT
ate annual N20 combustion output emission rate
STC2ECRT
ate annual C02equivalent combustion output emission rate
STHGCRT
ate annual Hg combustion output emission rate
STCNOXRT
ate annual NOx coal output emission rate
STONOXRT
ate annual NOxoiloutputemission rate
STGNOXRT
ate annual NOxgasoutputemission rate
STFSNXRT
ate annual NOx other fossil fuel outputemission rate
STCNXORT
ate ozone season NOx coal output emission rate
STONXORT
ate ozone season NOx oil output emission rate
STGNXORT
ate ozone season NOx gas output emission rate
STFSNORT
State ozone season NOxotherfossil fuel output emission rate
Technical Guide for eGRI D2020
I pg- 84
-------�
APPENDIX A
Field
Name
Description
Unit
51
STCS02RT
State annual S02coal output emission rate
Ib/MWh
52
ST0S02RT
State annual S02oil output emission rate
Ib/MWh
53
STGS02RT
State annual S02gasoutputemission rate
Ib/MWh
54
STFSS2RT
State annual S02otherfossilfuel outputemission rate
Ib/MWh
55
STCC02RT
State annual C02coal output emission rate
Ib/MWh
56
ST0C02RT
State annual C02oil output emission rate
Ib/MWh
57
STGC02RT
State annual C02gas output emission rate
Ib/MWh
58
STFSC2RT
State annual C02otherfossilfuel outputemission rate
Ib/MWh
59
STCCH4RT
State annual CH4 coal output emission rate
Ib/MWh
60
ST0CH4RT
State annual CH4 oil output emission rate
Ib/MWh
61
STGCH4RT
State annual CH4 gasoutputemission rate
Ib/MWh
62
STFCH4RT
State annual CH4 fossil fuel output emission rate
Ib/MWh
63
STCN20RT
State annual N20 coal output emission rate
Ib/MWh
64
ST0N20RT
State annual N20 oil output emission rate
Ib/MWh
65
STGN20RT
State annual N20 gas output emission rate
Ib/MWh
66
STFN20RT
State annual N20 fossil fuel output emission rate
Ib/MWh
67
STCC2ERT
State annual C02 equivalent coal output emission rate
Ib/MWh
68
ST0C2ERT
State annual C02 equivalent oil output emission rate
Ib/MWh
69
STGC2ERT
State annual C02 equivalent gasoutputemission rate
Ib/MWh
70
STFSC2ERT
State annual C02 equivalent fossil fuel output emission rate
Ib/MWh
71
STCHGRT
State annual Hg coal outputemission rate
not
calculated
72
STFSHGRT
State annual Hg otherfossil fuel outputemission rate
not
calculated
73
STCNOXR
State annual NOxcoal input emission rate
Ib/MMBtu
74
STONOXR
State annual NOxoil input emission rate
Ib/MMBtu
75
STGNOXR
State annual NOxgas input emission rate
Ib/MMBtu
76
STFSNXR
State annual NOx other fossil fuel input emission rate
Ib/MMBtu
77
STCNXOR
State ozone season NOx coal input emission rate
Ib/MMBtu
78
STONXOR
State ozone season NOx oil input emission rate
Ib/MMBtu
79
STGNXOR
State ozone season NOx gas input emission rate
Ib/MMBtu
80
STFSNOR
State ozone season NOx otherfossil fuel input emission rate
Ib/MMBtu
81
STCS02R
State annual S02coal input emission rate
Ib/MMBtu
82
STOS02R
State annual S02oil input emission rate
Ib/MMBtu
83
STGS02R
State annual S02gas input emission rate
Ib/MMBtu
84
STFSS2R
State annual S02otherfossilfuel input emission rate
Ib/MMBtu
85
STCC02R
State annual C02coal input emission rate
Ib/MMBtu
86
STOC02R
State annual C02oil input emission rate
Ib/MMBtu
87
STGC02R
State annual C02gas input emission rate
Ib/MMBtu
88
STFSC2R
State annual C02otherfossilfuel input emission rate
Ib/MMBtu
89
STCCH4R
State annual CH4 coal input emission rate
Ib/MMBtu
90
STOCH4R
State annual CH4 oil input emission rate
Ib/MMBtu
91
STGCH4R
State annual CH4 gas input emission rate
Ib/MMBtu
92
STFCH4R
State annual CH4 fossil fuel input emission rate
Ib/MMBtu
93
STCN20R
State annual N20 coal input emission rate
Ib/MMBtu
94
STON20R
State annual N20 oil input emission rate
Ib/MMBtu
95
STGN20R
State annual N20 gas input emission rate
Ib/MMBtu
96
STFN20R
State annual N20 fossil fuel input emission rate
Ib/MMBtu
97
STCC2ER
State annual C02 equivalent coal inputemission rate
Ib/MMBtu
98
STOC2ER
State annual C02 equivalent oil input emission rate
Ib/MMBtu
99
STGC2ER
State annual C02 equivalent gas input emission rate
Ib/MMBtu
100
STFSC2ER
State annual C02 equivalent fossil fuel input emission rate
Ib/MMBtu
101
STCHGR
State annual Hg coal input emission rate
not
calculated
Technical Guide for eGRI D2020
I pg- 85
-------�
APPENDIX A
Field
Name
Description
Unit
102
STFSHGR
State annual Hg otherfossil fuel input emission rate
not
calculated
103
STNBNOX
State annual NOx nonbaseload output emission rate
Ib/MWh
104
STNBNXO
State ozone season NOx nonbaseload output emission rate
Ib/MWh
105
STNBS02
State annual S02nonbaseload output emission rate
Ib/MWh
106
STNBC02
State annual C02 nonbaseload output emission rate
Ib/MWh
107
STNBCH4
State annual CH4 nonbaseload output emission rate
Ib/MWh
108
STNBN20
State annual N20 nonbaseload output emission rate
Ib/MWh
109
STNBC2E
State annual C02equivalent nonbaseload output emission rate
Ib/MWh
110
STNBHG
State annual Hg nonbaseload outputemission rate
not
calculated
111
STGENACL
State annual coal net generation
MWh
112
STGENAOL
State annual oil net generation
MWh
113
STGENAGS
State annual gas net generation
MWh
114
STGENANC
State annual nuclearnet generation
MWh
115
STGENAHY
State annual hydro net generation
MWh
116
STGENABM
State annual bio mass net generation
MWh
117
STGENAWI
State annual wind net generation
MWh
118
STGENASO
State annual solar net generation
MWh
119
STGENAGT
State annual geothermal net generation
MWh
120
STGENAOF
State annual otherfossil net generation
MWh
121
STGENAOP
State annual other unknown/purchased fuel net generation
MWh
122
STGENATN
State annual total nonrenewables net generation
MWh
123
STGENATR
State annual total renewables netgeneration
MWh
124
STGENATH
State annual total nonhydro renewables net generation
MWh
125
STGENACY
State annual total combustion netgeneration
MWh
126
STGENACN
State annual total noncombustion net generation
MWh
127
STCLPR
State coal generation percent (resource mix)
%
128
STOLPR
State oil generation percent (resource mix)
%
129
STGSPR
State gas generation percent (resource mix)
%
130
STNCPR
State nucleargeneration percent (resource mix)
%
131
STHYPR
State hydro generation percent (resource mix)
%
132
STBMPR
State bio mass generation percent (resource mix)
%
133
STWIPR
State wind generation percent (resource mix)
%
134
STSOPR
State solargeneration percent (resource mix)
%
135
STGTPR
State geothermal generation percent(resource mix)
%
136
STOFPR
State otherfossil generation percent (resource mix)
%
137
STOPPR
State other unknown/purchased fuel generation percent (resource mix)
%
138
STTNPR
State total nonrenewables generation percent (resource mix)
%
139
STTRPR
State total renewables generation percent (resource mix)
%
140
STTHPR
State total nonhydro renewables generation percent (resource mix)
%
141
STCYPR
State total combustion generation percent (resource mix)
%
142
STCNPR
State total noncombustion generation percent (resource mix)
%
143
STNBGNCL
State annual total nonbaseload coal generation
MWh
144
STNBGNOL
State annual total nonbaseload oil generation
MWh
145
STNBGNGS
State annual total nonbaseload gas generation
MWh
146
STNBGNNC
State annual total nonbaseload nucleargeneration
MWh
147
STNBGNHY
State annual total nonbaseload hydro generation
MWh
148
STNBGNBM
State annual total nonbaseload bio mass generation
MWh
149
STNBGNWI
State annual total nonbaseload wind generation
MWh
150
STNBGNSO
State annual total nonbaseload solargeneration
MWh
151
STNBGNGT
State annual total nonbaseload geothermal generation
MWh
152
STNBGNOF
State annual total nonbaseload otherfossil generation
MWh
153
STNBGNOP
State annual total nonbaseload otherunknown/purchased fuel generation
MWh
Technical Guide for eGRI D2020
I pg- 86
-------�
APPENDIX A
Field
Name
Description
Unit
154
STNBCLPR
State nonbaseload coal generation percent (resource mix)
%
155
STNBOLPR
State nonbaseload oil generation percent (resource mix)
%
156
STNBGSPR
State nonbaseload gas generation percent (resource mix)
%
157
STNBNCPR
State nonbaseload nucleargeneration percent (resource mix)
%
158
STNBHYPR
State nonbaseload hydro generation percent (resource mix)
%
159
STNBBMPR
State nonbaseload bio mass generation percent (resource mix)
%
160
STNBWIPR
State nonbaseload wind generation percent (resource mix)
%
161
STNBSOPR
State nonbaseload solargeneration percent (resource mix)
%
162
STNBGTPR
State nonbaseload geothermal generation percent (resource mix)
%
163
STNBOFPR
State nonbaseload otherfossil generation percent (resource mix)
%
164
STNBOPPR
State nonbaseload other unknown/purchased fuel generation percent (resource
mix)
%
Technical Guide for eGRI D2020
I pg- 87
-------�
APPENDIX A
Table A-5. eGRID File Structure, eGRID2020 BA File, Balancing Authority (BA) File
Field
Name
Description
Unit
1
YEAR
Data year
2
BANAME
BA name
3
BACODE
BA code
4
BANAMEPCAP
BA nameplate capacity
MW
5
BAHTIAN
BA annual heat input from combustion
MMBtu
6
BAHTIOZ
BA ozone season heat input from combustion
MMBtu
7
BAHTIANT
BA total annual heat input
MMBtu
8
BAHTIOZT
BA total ozone season heatinput
MMBtu
9
BANGENAN
BA annual net generation
MWh
10
BANGENOZ
BA ozone season net generation
MWh
11
BANOXAN
BA annual NOxemissions
tons
12
BANOXOZ
BA ozone season NOx emissions
tons
13
BAS02AN
BA annual S02emissions
tons
14
BAC02AN
BA annual C02emissions
tons
15
BACH4AN
BA annual CH4 emissions
lbs
16
BAN20AN
BA annual N20 emissions
lbs
17
BAC02EQA
BA annual C02equivalent emissions
tons
18
BAHGAN
BA annual Hg emissions
lbs
19
BANOXRTA
BA annual NOx total output emission rate
Ib/MWh
20
BANOXRTO
BA ozone season NOx total output emission rate
Ib/MWh
21
BAS02RTA
BA annual S02total output emission rate
Ib/MWh
22
BAC02RTA
BA annual C02total output emission rate
Ib/MWh
23
BACH4RTA
BA annual CH4 total output emission rate
Ib/MWh
24
BAN20RTA
BA annual N20 total output emission rate
Ib/MWh
25
BAC2ERTA
BA annual C02equivalent total output emission rate
Ib/MWh
26
BAHGRTA
BA annual Hg total output emission rate
Ib/MWh
27
BANOXRA
BA annual NOx input emission rate
Ib/MMBtu
28
BANOXRO
BA ozone season NOx input emission rate
Ib/MMBtu
29
BAS02RA
BA annual S02 input emission rate
Ib/MMBtu
30
BAC02RA
BA annual C02 input emission rate
Ib/MMBtu
31
BACH4RA
BA annual CH4 input emission rate
Ib/MMBtu
32
BAN20RA
BA annual N20 input emission rate
Ib/MMBtu
33
BAC2ERA
BA annual C02equivalent input emission rate
Ib/MMBtu
34
BAHGRA
BA annual Hg input emission rate
Ib/MMBtu
35
BANOXCRT
BAannual NOx combustion output emission rate
Ib/MWh
36
BANOXCRO
BA ozone season NOx combustion output emission rate
Ib/MWh
37
BAS02CRT
BA annual S02combustion outputemission rate
Ib/MWh
38
BAC02CRT
BA annual C02combustion outputemission rate
Ib/MWh
39
BACH4CRT
BA annual CH4 combustion outputemission rate
Ib/MWh
40
BAN20CRT
BA annual N20 combustion output emission rate
Ib/MWh
41
BAC2ECRT
BA annual C02equivalent combustion outputemission rate
Ib/MWh
42
BAHGCRT
BA annual Hg combustion output emission rate
Ib/MWh
43
BACNOXRT
BAannual NOx coal output emission rate
Ib/MWh
44
BAONOXRT
BAannual NOxoiloutputemission rate
Ib/MWh
45
BAGNOXRT
BAannual NOxgasoutputemission rate
Ib/MWh
46
BAFSNXRT
BAannual NOx fossil fuel output emission rate
Ib/MWh
47
BACNXORT
BA ozone season NOx coal output emission rate
Ib/MWh
48
BAONXORT
BA ozone season NOx oil output emission rate
Ib/MWh
49
BAGNXORT
BA ozone season NOx gas output emission rate
Ib/MWh
50
BAFSNORT
BA ozone season NOx fossil fuel output emission rate
Ib/MWh
51
BACS02RT
BA annual S02coal output emission rate
Ib/MWh
52
BAOS02RT
BA annual S02oil output emission rate
Ib/MWh
Technical Guide for eGRI D2020
I pg- 88
-------�
Field
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
Name
Description
BAGS02RT
BA annua
S02gas output emission rate
BAFSS2RT
BA annua
S02fossii fuel output emission rate
BACC02RT
BA annua
C02coal output emission rate
BAOC02RT
BA annua
C02oil output emission rate
BAGC02RT
BA annua
C02gas output emission rate
BAFSC2RT
BA annua
C02fossil fuel output emission rate
BACCH4RT
BA annua
CH4 coal output emission rate
BAOCH4RT
BA annua
CH4 oil output emission rate
BAGCH4RT
BA annua
CH4 gas output emission rate
BAFCH4RT
BA annua
CH4 fossil fuel output emission rate
BACN20RT
BA annua
N20 coal output emission rate
BAON20RT
BA annua
N20 oil output emission rate
BAGN20RT
BA annua
N20 gas output emission rate
BAFN20RT
BA annua
N20 fossil fuel output emission rate
BACC2ERT
BA annua
C02 equivalent coal output emission rate
BAOC2ERT
BA annua
C02 equivalent oil output emission rate
BAGC2ERT
BA annua
CQ2 equivalent gasoutputemission rate
BAFSC2ERT
BA annua
C02 equivalent fossil fuel output emission rate
BACHGRT
BA annua
Hg coal output emission rate
BAFSHGRT
BA annua
Hg fossil fuel output emission rate
BACNOXR
BA annua
NOxcoal input emission rate
BAONOXR
BA annua
NOxoil input emission rate
BAGNOXR
BA annua
NOxgas input emission rate
BAFSNXR
BA annua
NOx fossil fuel input emission rate
BACNXOR
BA ozone season NOxcoal input emission rate
BAONXOR
BA ozone season NOxoil input emission rate
BAGNXOR
BA ozone season NOxgas input emission rate
BAFSNOR
BA ozone season NOx fossil fuel input emission rate
BACS02R
BA annua
S02coal input emission rate
BA0S02R
BA annua
S02oil input emission rate
BAGS02R
BA annua
S02gas input emission rate
BAFSS2R
BA annua
S02fossil fuel input emission rate
BACC02R
BA annua
C02coal input emission rate
BA0C02R
BA annua
C02oil input emission rate
BAGC02R
BA annua
C02gas input emission rate
BAFSC2R
BA annua
C02fossil fuel input emission rate
BACCH4R
BA annua
CH4 coal input emission rate
BAOCH4R
BA annua
CH4 oil input emission rate
BAGCH4R
BA annua
CH4 gas input emission rate
BAFCH4R
BA annua
CH4 fossil fuel input emission rate
BACN20R
BA annua
N20 coal input emission rate
BA0N20R
BA annua
N20 oil input emission rate
BAGN20R
BA annua
N20 gas input emission rate
BAFN20R
BA annua
N20 fossil fuel input emission rate
BACC2ER
BA annua
C02 equivalent coal inputemission rate
BAOC2ER
BA annua
C02 equivalent oil input emission rate
BAGC2ER
BA annua
C02 equivalent gas input emission rate
BAFSC2ER
BA annua
C02 equivalent fossil fuel input emission rate
BACHGR
BA annua
Hg coal input emission rate
BAFSHGR
BA annua
Hg fossil fuel input emission rate
BANBNOX
BA annua
NOx nonbaseload output emission rate
BANBNXO
BA ozone
season NOx nonbaseload output emission rate
BANBS02
BA annua
S02 nonbaseload output emission rate
BANBC02
BA annua
C02 nonbaseload output emission rate
Technical Guide for eGRI D2020
-------�
APPENDIX A
Field
Name
Description
Unit
107
BANBCH4
BA annual CH4 nonbaseload output emission rate
Ib/MWh
108
BANBN20
BA annual N20 nonbaseload output emission rate
Ib/MWh
109
BANBC2E
BA annual C02equivalent nonbaseload outputemission rate
Ib/MWh
110
BANBHG
BA annual Hg nonbaseload outputemission rate
Ib/MWh
111
BAGENACL
BA annual coal net generation
MWh
112
BAGENAOL
BA annual oil net generation
MWh
113
BAGENAGS
BA annual gas net generation
MWh
114
BAGENANC
BA annual nuclear net generation
MWh
115
BAGENAHY
BA annual hydro net generation
MWh
116
BAGENABM
BA annual bio mass net generation
MWh
117
BAGENAWI
BAannualwind net generation
MWh
118
BAGENASO
BA annual solar net generation
MWh
119
BAGENAGT
BA annual geothermal net generation
MWh
120
BAGENAOF
BA annual otherfossil net generation
MWh
121
BAGENAOP
BA annual otherunknown/purchased fuel net generation
MWh
122
BAGENATN
BA annual total nonrenewables net generation
MWh
123
BAGENATR
BA annual total renewablesnetgeneration
MWh
124
BAGENATH
BA annual total nonhydro renewables net generation
MWh
125
BAGENACY
BA annual total combustion netgeneration
MWh
126
BAGENACN
BA annual total noncombustion net generation
MWh
127
BACLPR
BA coal generation percent (resource mix)
%
128
BAOLPR
BAoil generation percent(resource mix)
%
129
BAGSPR
BA gas generation percent(resource mix)
%
130
BANCPR
BA nucleargeneration percent (resource mix)
%
131
BAHYPR
BA hydro generation percent(resource mix)
%
132
BABMPR
BA bio mass generation percent (resource mix)
%
133
BAWIPR
BA wind generation percent (resource mix)
%
134
BASOPR
BA solar generation percent (resource mix)
%
135
BAGTPR
BA geothermal generation percent (resource mix)
%
136
BAOFPR
BA otherfossil generation percent (resource mix)
%
137
BAOPPR
BA other unknown/purchased fuel generation percent (resource mix)
%
138
BATNPR
BA total nonrenewables generation percent (resource mix)
%
139
BATRPR
BA total renewables generation percent (resource mix)
%
140
BATHPR
BA total nonhydro renewables generation percent (resource mix)
%
141
BACYPR
BA total combustion generation percent (resource mix)
%
142
BACNPR
BA total noncombustion generation percent (resource mix)
%
143
BANBGNCL
BA annual total nonbaseload coal generation
MWh
144
BANBGNOL
BA annual total nonbaseload oil generation
MWh
145
BANBGNGS
BA annual total nonbaseload gas generation
MWh
146
BANBGNNC
BA annual total nonbaseload nucleargeneration
MWh
147
BANBGNHY
BA annual total nonbaseload hydro generation
MWh
148
BANBGNBM
BA annual total nonbaseload bio mass generation
MWh
149
BANBGNWI
BA annual total nonbaseload wind generation
MWh
150
BANBGNSO
BA annual total nonbaseload solargeneration
MWh
151
BANBGNGT
BA annual total nonbaseload geothermal generation
MWh
152
BANBGNOF
BA annual total nonbaseload otherfossil generation
MWh
153
BANBGNOP
BA annual total nonbaseload otherunknown/purchased fuel generation
MWh
154
BANBCLPR
BA nonbaseload coal generation percent (resource mix)
%
155
BANBOLPR
BA nonbaseloadoilgenerationpercent(resource mix)
%
156
BANBGSPR
BA nonbaseloadgasgenerationpercent(resource mix)
%
157
BANBNCPR
BA nonbaseload nucleargeneration percent (resource mix)
%
158
BANBHYPR
BA nonbaseload hydro generation percent(resource mix)
%
159
BANBBMPR
BA nonbaseload bio mass generation percent (resource mix)
%
Technical Guide for eGRI D2020
I pg- 90
-------�
APPENDIX A
Field
Name
Description
Unit
160
BANBWIPR
BA nonbaseloadwind generation percent (resource mix)
%
161
BANBSOPR
BA nonbaseloadsolargeneration percent (resource mix)
%
162
BANBGTPR
BA nonbaseloadgeothermal generation percent (resource mix)
%
163
BANBOFPR
BA nonbaseloadotherfossilgeneration percent (resource mix)
%
164
BANBOPPR
BA nonbaseload other unknown/purchased fuel generation percent (resource
mix)
%
Technical Guide for eGRI D2020
I pg- 91
-------�
APPENDIX A
Table A-6. eGRID File Structure, eGRID2020 SRL File, eGRID Subregion File
Field
Name
Description
Unit
1
YEAR
Data year
2
SUBRGN
eGRID subregion acronym
3
SRNAME
eGRIDsubregion name
4
SRNAMEPCAP
eGRID subregion nameplate capacity
MW
5
SRHTIAN
eGRIDsubregion annual heat input from combustion
MMBtu
6
SRHTIOZ
eGRIDsubregion ozone season heat input from combustion
MMBtu
7
SRHTIANT
eGRIDsubregion totalannual heat input
MMBtu
8
SRHTIOZT
eGRIDsubregion total ozone season heat input
MMBtu
9
SRNGENAN
eGRID subregion annual net generation
MWh
10
SRNGENOZ
eGRIDsubregion ozone season net generation
MWh
11
SRNOXAN
eGRIDsubregion annual NOxemissions
tons
12
SRNOXOZ
eGRIDsubregion ozone season NOxemissions
tons
13
SRS02AN
eGRIDsubregion annualS02emissions
tons
14
SRC02AN
eGRIDsubregion annualC02emissions
tons
15
SRCH4AN
eGRIDsubregion annualCH4 emissions
lbs
16
SRN20AN
eGRIDsubregion annual N20 emissions
lbs
17
SRC02EQA
eGRIDsubregion annual C02equivalent emissions
tons
18
SRHGAN
eGRIDsubregion annual Hg emissions
lbs
19
SRNOXRTA
eGRIDsubregion annual NOx total output emission rate
Ib/MWh
20
SRNOXRTO
eGRIDsubregion ozone season NOx total output emission rate
Ib/MWh
21
SRS02RTA
eGRIDsubregion annual S02 total output emission rate
Ib/MWh
22
SRC02RTA
eGRIDsubregion annual C02 total output emission rate
Ib/MWh
23
SRCH4RTA
eGRIDsubregion annual CH4 total output emission rate
Ib/MWh
24
SRN20RTA
eGRIDsubregion annual N20 total output emission rate
Ib/MWh
25
SRC2ERTA
eGRID subregion annual C02 equivalent total output emission rate
Ib/MWh
26
SRHGRTA
eGRIDsubregion annual Hg total output emission rate
Ib/MWh
27
SRNOXRA
eGRIDsubregion annual NOx input emission rate
Ib/MMBtu
28
SRNOXRO
eGRIDsubregion ozone season NOx input emission rate
Ib/MMBtu
29
SRS02RA
eGRIDsubregion annual S02 input emission rate
Ib/MMBtu
30
SRC02RA
eGRIDsubregion annual C02 input emission rate
Ib/MMBtu
31
SRCH4RA
eGRIDsubregion annual CH4input emission rate
Ib/MMBtu
32
SRN20RA
eGRIDsubregion annual N20 input emission rate
Ib/MMBtu
33
SRC2ERA
eGRIDsubregion annual C02equivalent input emission rate
Ib/MMBtu
34
SRHGRA
eGRIDsubregion annual Hg input emission rate
Ib/MMBtu
35
SRNOXCRT
eGRIDsubregion annual NOxcombustion outputemission rate
Ib/MWh
36
SRNOXCRO
eGRIDsubregion ozone season NOxcombustion outputemission rate
Ib/MWh
37
SRS02CRT
eGRIDsubregion annual S02combustion outputemission rate
Ib/MWh
38
SRC02CRT
eGRIDsubregion annual C02combustion output emission rate
Ib/MWh
39
SRCH4CRT
eGRIDsubregion annual CH4 combustion outputemission rate
Ib/MWh
40
SRN20CRT
eGRIDsubregion annual N20 combustion output emission rate
Ib/MWh
41
SRC2ECRT
eGRIDsubregion annual C02equiva lent combustion outputemission rate
Ib/MWh
42
SRHGCRT
eGRIDsubregion annual Hg combustion output emission rate
Ib/MWh
43
SRCNOXRT
eGRIDsubregion annual NOx coal output emission rate
Ib/MWh
44
SRONOXRT
eGRIDsubregion annual NOx oil outputemission rate
Ib/MWh
45
SRGNOXRT
eGRIDsubregion annual NOxgasoutputemission rate
Ib/MWh
46
SRFSNXRT
eGRIDsubregion annual NOx fossil fuel outputemission rate
Ib/MWh
47
SRCNXORT
eGRIDsubregion ozone season NOxcoal output emission rate
Ib/MWh
48
SRONXORT
eGRIDsubregion ozone season NOxoil outputemission rate
Ib/MWh
49
SRGNXORT
eGRIDsubregion ozone season NOx gas output emission rate
Ib/MWh
50
SRFSNORT
eGRIDsubregion ozone season NOx fossil fuel output emission rate
Ib/MWh
51
SRCS02RT
eGRIDsubregion annualS02coaloutputemission rate
Ib/MWh
52
SROS02RT
eGRIDsubregion annualS02oiloutputemission rate
Ib/MWh
Technical Guide for eGRI D2020
I pg- 92
-------�
Field
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
Name
Description
SRGS02RT
eGRIDsubregion annua
S02 gas output emission rate
SRFSS2RT
eGRIDsubregion annua
S02 fossil fuel output emission rate
SRCC02RT
eGRIDsubregion annua
C02 coal output emission rate
SROC02RT
eGRIDsubregion annua
C02 oil output emission rate
SRGC02RT
eGRIDsubregion annua
C02 gas output emission rate
SRFSC2RT
eGRIDsubregion annua
C02 fossil fuel output emission rate
SRCCH4RT
eGRIDsubregion annua
CH4 coal output emission rate
SROCH4RT
eGRIDsubregion annua
CH4 oil output emission rate
SRGCH4RT
eGRIDsubregion annua
CH4 gas output emission rate
SRFCH4RT
eGRIDsubregion annua
CH4 fossil fuel output emission rate
SRCN20RT
eGRIDsubregion annua
N20 coal output emission rate
SRON20RT
eGRIDsubregion annua
N20 oil output emission rate
SRON20RT
eGRIDsubregion annua
N20 gas output emission rate
SRFN20RT
eGRIDsubregion annua
N20 fossil output emission rate
SRCC2ERT
eGRIDsubregion annua
C02equivalent coaloutputemission rate
SROC2ERT
eGRIDsubregion annua
C02 equivalent oil output emission rate
SRGC2ERT
eGRIDsubregion annua
C02 equivalent gas output emission rate
SRFSC2ERT
eGRIDsubregion annua
C02 equivalent fossil fuel output emission rate
SRCHGRT
eGRIDsubregion annua
Hg coal outputemission rate
SRFSHGRT
eGRIDsubregion annua
Hg fossil fuel output emission rate
SRCNOXR
eGRIDsubregion annua
NOx coal input emission rate
SRONOXR
eGRIDsubregion annua
NOx oil input emission rate
SRGNOXR
eGRIDsubregion annua
NOx gas input emission rate
SRFSNXR
eGRIDsubregion annua
NOx fossil fuel input emission rate
SRCNXOR
eGRIDsubregion ozone season NOxcoal input emission rate
SRONXOR
eGRIDsubregion ozone season NOxoil input emission rate
SRGNXOR
eGRIDsubregion ozone season NOx gas input emission rate
SRFSNOR
eGRIDsubregion ozone season NOx fossil fuel input emission rate
SRCS02R
eGRIDsubregion annua
S02 coal input emission rate
SR0S02R
eGRIDsubregion annua
S02 oil input emission rate
SRGS02R
eGRIDsubregion annua
S02 gas input emission rate
SRFSS2R
eGRIDsubregion annua
S02 fossil fuel input emission rate
SRCC02R
eGRIDsubregion annua
C02 coal input emission rate
SR0C02R
eGRIDsubregion annua
C02 oil input emission rate
SRGC02R
eGRIDsubregion annua
C02 gas input emission rate
SRFSC2R
eGRIDsubregion annua
C02 fossil fuel input emission rate
SRCCH4R
eGRIDsubregion annua
ChUcoal input emission rate
SROCH4R
eGRIDsubregion annua
ChUoil input emission rate
SRGCH4R
eGRIDsubregion annua
CH4 gas input emission rate
SRFCH4R
eGRIDsubregion annua
CH4 fossil input emission rate
SRCN20R
eGRIDsubregion annua
N20 coal input emission rate
SR0N20R
eGRIDsubregion annua
N20 oil input emission rate
SRGN20R
eGRIDsubregion annua
N20 gas input emission rate
SRFN20R
eGRIDsubregion annua
N20 fossil input emission rate
SRCC2ER
eGRIDsubregion annua
C02 equivalent coal input emission rate
SROC2ER
eGRIDsubregion annua
C02 equivalent oil input emission rate
SRGC2ER
eGRIDsubregion annua
C02 equivalent gas input emission rate
SRFSC2ER
eGRIDsubregion annua
C02 equivalent fossil fuel input emission rate
SRCHGR
eGRIDsubregion annua
Hg coal input emission rate
SRFSHGR
eGRIDsubregion annua
Hg fossil fuel input emission rate
SRNBNOX
eGRIDsubregion annua
NOx nonbaseload output emission rate
SRNBNXO
eGRIDsubregion ozone
season NOx nonbaseload output emission rate
SRNBS02
eGRIDsubregion annua
S02 nonbaseload outputemission rate
SRNBC02
eGRIDsubregion annua
C02 nonbaseload output emission rate
Technical Guide for eGRI D2020
-------�
APPENDIX A
Field
Name
Description
Unit
107
SRNBCH4
eGRIDsubregion annual CH4 nonbaseload outputemission rate
Ib/MWh
108
SRNBN20
eGRIDsubregion annual N20 nonbaseload output emission rate
Ib/MWh
109
SRNBC2E
eGRIDsubregion annual C02e nonbaseload output emission rate
Ib/MWh
110
SRNBHG
eGRIDsubregion annual Hg nonbaseload output emission rate
Ib/MWh
111
SRGENACL
eGRIDsubregion annual coal net generation
MWh
112
SRGENAOL
eGRIDsubregion annual oil net generation
MWh
113
SRGENAGS
eGRIDsubregion annual gas net generation
MWh
114
SRGENANC
eGRIDsubregion annual nuclear net generation
MWh
115
SRGENAHY
eGRIDsubregion annual hydro net generation
MWh
116
SRGENABM
eGRIDsubregion annual bio mass net generation
MWh
117
SRGENAWI
eGRIDsubregion annualwind net generation
MWh
118
SRGENASO
eGRIDsubregion annual solar net generation
MWh
119
SRGENAGT
eGRIDsubregion annual geothermal net generation
MWh
120
SRGENAOF
eGRIDsubregion annual other fossil net generation
MWh
121
SRGENAOP
eGRID subregion annual other unknown/purchased fuel net generation
MWh
122
SRGENATN
eGRIDsubregion annual total nonrenewables net generation
MWh
123
SRGENATR
eGRIDsubregion annual total renewables net generation
MWh
124
SRGENATH
eGRIDsubregion annual total nonhydro renewables net generation
MWh
125
SRGENACY
eGRIDsubregion annualtotalcombustion netgeneration
MWh
126
SRGENACN
eGRIDsubregion annualtotal noncombustionnet generation
MWh
127
SRCLPR
eGRIDsubregion coal generation percent (resource mix)
%
128
SROLPR
eGRIDsubregion oil generation percent (resource mix)
%
129
SRGSPR
eGRIDsubregion gasgenerationpercent(resource mix)
%
130
SRNCPR
eGRIDsubregion nucleargeneration percent (resource mix)
%
131
SRHYPR
eGRIDsubregion hydro generation percent (resource mix)
%
132
SRBMPR
eGRIDsubregion biomass gene ration percent (resource mix)
%
133
SRWIPR
eGRIDsubregion wind generation percent (resource mix)
%
134
SRSOPR
eGRIDsubregion solargeneration percent (resource mix)
%
135
SRGTPR
eGRIDsubregion geothermal generation percent (resource mix)
%
136
SROFPR
eGRIDsubregion otherfossil generation percent (resource mix)
%
137
SROPPR
eGRIDsubregion other unknown/purchased fuel generation percent (resource
mix)
%
138
SRTNPR
eGRIDsubregion total nonrenewables generation percent (resource mix)
%
139
SRTRPR
eGRIDsubregion total renewables generation percent (resource mix)
%
140
SRTHPR
eGRIDsubregion total nonhydro renewables generation percent (resource mix)
%
141
SRCYPR
eGRIDsubregion total combustion generation percent (resource mix)
%
142
SRCNPR
eGRID subregion total noncombustion generation percent (resource mix)
%
143
SRNBGNCL
eGRIDsubregion annualtotal nonbaseload coal generation
MWh
144
SRNBGNOL
eGRIDsubregion annualtotal nonbaseload oil generation
MWh
145
SRNBGNGS
eGRIDsubregion annualtotal nonbaseload gasgeneration
MWh
146
SRNBGNNC
eGRIDsubregion annualtotal nonbaseload nucleargeneration
MWh
147
SRNBGNHY
eGRIDsubregion annualtotal nonbaseload hydro generation
MWh
148
SRNBGNBM
eGRIDsubregion annualtotal nonbaseload biomass generation
MWh
149
SRNBGNWI
eGRIDsubregion annualtotal nonbaseload wind generation
MWh
150
SRNBGNSO
eGRIDsubregion annualtotal nonbaseload solargeneration
MWh
151
SRNBGNGT
eGRIDsubregion annualtotal nonbaseload geothermal generation
MWh
152
SRNBGNOF
eGRIDsubregion annualtotal nonbaseload otherfossil generation
MWh
153
SRNBGNOP
eGRIDsubregion annualtotal nonbaseload other unknown/purchased fuel
generation
MWh
154
SRNBCLPR
eGRID subregion nonbaseload coal generation percent (resource mix)
%
155
SRNBOLPR
eGRID subregion nonbaseload oil generation percent (resource mix)
%
156
SRNBGSPR
eGRIDsubregion nonbaseload gas generation percent (resource mix)
%
157
SRNBNCPR
eGRIDsubregion nonbaseload nucleargeneration percent (resource mix)
%
158
SRNBHYPR
eGRIDsubregion nonbaseload hydro generation percent(resource mix)
%
Technical Guide for eGRI D2020
I pg- 94
-------�
APPENDIX A
Field
Name
Description
Unit
159
SRNBBMPR
eGRIDsubregion nonbaseloadbiomass generation percent (resource mix)
%
160
SRNBWIPR
eGRIDsubregion nonbaseioadwind generation percent (resource mix)
%
161
SRNBSOPR
eGRIDsubregion nonbaseloadsolargeneration percent (resource mix)
%
162
SRNBGTPR
eGRIDsubregion nonbaseloadgeothermal generation percent (resource mix)
%
163
SRNBOFPR
eGRIDsubregion nonbaseload other fossil generation percent (resource mix)
%
164
SRNBOPPR
eGRIDsubregion nonbaseload other unknown/purchased fuel generation percent
(resource mix)
%
Technical Guide for eGRI D2020
I pg- 95
-------�
Field
~
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
APPENDIX A
Table A-7. eGRID File Structure, eGRID2020 NRL File, NERC Region File
Name
Description
Unit
YEAR
Data year
NERC
NERC region acronym
NERCNAME
NERC region name
NRNAMEPCAP
NERC region namepiate capacity
MW
NRHTIAN
NERC region annual heat inputfrom combustion
MMBtu
NRHTIOZ
NERC region ozone season heat input from combustion
MMBtu
NRHTIANT
NERC total region annual heat input
MMBtu
NRHTIOZT
NERC total region ozone season heat input
MMBtu
NRNGENAN
NERC reg
on annual net generation
MWh
NRNGENOZ
NERC reg
on ozone season net generation
MWh
NRNOXAN
NERC reg
on annual NOxemissions
tons
NRNOXOZ
NERC reg
on ozone season NOxemissions
tons
NRS02AN
NERC reg
on annual S02emissions
tons
NRC02AN
NERC reg
on annual C02emissions
tons
NRCH4AN
NERC reg
on annual ChUemissions
lbs
NRN20AN
NERC reg
on annual N20 emissions
lbs
NRC02EQA
NERC reg
on annual C02equivalentemissions
tons
NRHGAN
NERC reg
on annual Hg emissions
lbs
NRNOXRTA
NERC reg
on annual NOx total output emission rate
Ib/MWh
NRNOXRTO
NERC reg
on ozone season NOx total output emission rate
Ib/MWh
NRS02RTA
NERC reg
on annual S02total output emission rate
Ib/MWh
NRC02RTA
NERC reg
on annual C02total output emission rate
Ib/MWh
NRCH4RTA
NERC reg
on annual CH4 total output emission rate
Ib/MWh
NRN20RTA
NERC reg
on annual N2Q total output emission rate
Ib/MWh
NRC2ERTA
NERC reg
on annual C02equivalent total output emission rate
Ib/MWh
NRHGRTA
NERC reg
on annual Hg total output emission rate
Ib/MWh
NRNOXRA
NERC reg
on annual NOx input emission rate
Ib/MMBtu
NRNOXRO
NERC reg
on ozone season NOx input emission rate
Ib/MMBtu
NRS02RA
NERC reg
on annual S02 input emission rate
Ib/MMBtu
NRC02RA
NERC reg
on annual C02 input emission rate
Ib/MMBtu
NRCH4RA
NERC reg
on annual CH4 input emission rate
Ib/MMBtu
NRN20RA
NERC reg
on annual N20 input emission rate
Ib/MMBtu
NRC2ERA
NERC reg
on annual C02equivalent input emission rate
Ib/MMBtu
NRHGRA
NERC reg
on annual Hg input emission rate
Ib/MMBtu
NRNOXCRT
NERC reg
on annual NOx combustion output emission rate
Ib/MWh
NRNOXCRO
NERC reg
on ozone season NOxcombustion outputemission rate
Ib/MWh
NRS02CRT
NERC reg
on annual S02combustion output emission rate
Ib/MWh
NRC02CRT
NERC reg
on annual C02combustion outputemission rate
Ib/MWh
NRCH4CRT
NERC reg
on annual CH4 combustion output emission rate
Ib/MWh
NRN20CRT
NERC reg
on annual N20 combustion outputemission rate
Ib/MWh
NRC2ECRT
NERC reg
on annual C02 equivalent combustion output emission rate
Ib/MWh
NRHGCRT
NERC reg
on annual Hg combustion output emission rate
Ib/MWh
NRCNOXRT
NERC reg
on annual NOx coal output emission rate
Ib/MWh
NRONOXRT
NERC reg
on annual NOx oil output emission rate
Ib/MWh
NRGNOXRT
NERC reg
on annual NOxgasoutputemission rate
Ib/MWh
NRFSNXRT
NERC reg
on annual NOx fossil fuel output emission rate
Ib/MWh
NRCNXORT
NERC reg
on ozone season NOx coal outputemission rate
Ib/MWh
NRONXORT
NERC reg
on ozone season NOx oil output emission rate
Ib/MWh
NRGNXORT
NERC reg
on ozone season NOxgasoutputemission rate
Ib/MWh
NRFSNORT
NERC reg
on ozone season NOx fossil fuel output emission rate
Ib/MWh
NRCS02RT
NERC reg
on annual S02coal output emission rate
Ib/MWh
NR0S02RT
NERC reg
on annual S02oil output emission rate
Ib/MWh
Technical Guide for eGRI D2020
I pg- 96
-------�
APPENDIX A
Field
Name
Description
Unit
53
NRGS02RT
NERC reg
on annual S02gas output emission rate
Ib/MWh
54
NRFSS2RT
NERC reg
on annual S02fossil fuel output emission rate
Ib/MWh
55
NRCC02RT
NERC reg
on annual C02coal output emission rate
Ib/MWh
56
NR0C02RT
NERC reg
on annual C02oil output emission rate
Ib/MWh
57
NRGC02RT
NERC reg
on annual C02gas output emission rate
Ib/MWh
58
NRFSC2RT
NERC reg
on annual C02fossil fuel output emission rate
Ib/MWh
59
NRCCH4RT
NERC reg
on annual CH4 coal output emission rate
Ib/MWh
60
NR0CH4RT
NERC reg
on annual ChUoil output emission rate
Ib/MWh
61
NRGCH4RT
NERC reg
on annual ChUgasoutput emission rate
Ib/MWh
62
NRFCH4RT
NERC reg
on annual CH4 fossil fuel output emission rate
Ib/MWh
63
NRCN20RT
NERC reg
on annual N20 coal output emission rate
Ib/MWh
64
NR0N20RT
NERC reg
on annual N20 oil output emission rate
Ib/MWh
65
NRGN20RT
NERC reg
on annual N20 gas output emission rate
Ib/MWh
66
NRFN20RT
NERC reg
on annual N20 fossil fuel output emission rate
Ib/MWh
67
NRCC2ERT
NERC reg
on annual C02equivalent coal output emission rate
Ib/MWh
68
NR0C2ERT
NERC reg
on annual C02equivalent oil output emission rate
Ib/MWh
69
NRGC2ERT
NERC reg
on annual C02equivalent gasoutput emission rate
Ib/MWh
70
NRFSC2ERT
NERC reg
on annual C02equivalent fossil fuel outputemission rate
Ib/MWh
71
NRCHGRT
NERC reg
on annual Hg coal output emission rate
Ib/MWh
72
NRFSHGRT
NERC reg
on annual Hg fossil fuel output emission rate
Ib/MWh
73
NRCNOXR
NERC reg
on annual NOxcoal input emission rate
Ib/MMBtu
74
NRONOXR
NERC reg
on annual NOxoil input emission rate
Ib/MMBtu
75
NRGNOXR
NERC reg
on annual NOxgas input emission rate
Ib/MMBtu
76
NRFSNXR
NERC reg
on annual NOx fossil fuel input emission rate
Ib/MMBtu
77
NRCNXOR
NERC reg
on ozone season NOxcoal input emission rate
Ib/MMBtu
78
NRONXOR
NERC reg
on ozone season NOxoil input emission rate
Ib/MMBtu
79
NRGNXOR
NERC reg
on ozone season NOxgas input emission rate
Ib/MMBtu
80
NRFSNOR
NERC reg
on ozone season NOx fossil fuel input emission rate
Ib/MMBtu
81
NRCS02R
NERC reg
on annual S02coal input emission rate
Ib/MMBtu
82
NROS02R
NERC reg
on annual S02oil input emission rate
Ib/MMBtu
83
NRGS02R
NERC reg
on annual S02gas input emission rate
Ib/MMBtu
84
NRFSS2R
NERC reg
on annual S02fossil fuel input emission rate
Ib/MMBtu
85
NRCC02R
NERC reg
on annual C02coal input emission rate
Ib/MMBtu
86
NROC02R
NERC reg
on annual C02oil input emission rate
Ib/MMBtu
87
NRGC02R
NERC reg
on annual C02gas input emission rate
Ib/MMBtu
88
NRCCH4R
NERC reg
on annual ChUcoal input emission rate
Ib/MMBtu
89
NROCH4R
NERC reg
on annual ChUoil input emission rate
Ib/MMBtu
90
NRGCH4R
NERC reg
onannualChUgasinputemission rate
Ib/MMBtu
91
NRFCH4R
NERC reg
on annual CH4 fossil fuel input emission rate
Ib/MMBtu
92
NRCN20R
NERC reg
on annual N20 coal input emission rate
Ib/MMBtu
93
NRON20R
NERC reg
on annual N20 oil input emission rate
Ib/MMBtu
94
NRGN20R
NERC reg
on annual N20 gas input emission rate
Ib/MMBtu
95
NRFN20R
NERC reg
on annual N20 fossil fuel input emission rate
Ib/MMBtu
96
NRCC2ER
NERC reg
on annual C02equivalent coal input emission rate
Ib/MMBtu
97
NROC2ER
NERC reg
on annual C02equivalent oil input emission rate
Ib/MMBtu
98
NRGC2ER
NERC reg
on annual C02equivalent gas input emission rate
Ib/MMBtu
99
NRFSC2ER
NERC reg
on annual C02equivalent fossil fuel input emission rate
Ib/MMBtu
100
NRFSC2R
NERC reg
on annual C02fossil fuel input emission rate
Ib/MMBtu
101
NRCHGR
NERC reg
on annual Hg coal input emission rate
Ib/MMBtu
102
NRFSHGR
NERC reg
on annual Hg fossil fuel input emission rate
Ib/MMBtu
103
NRNBNOX
NERC reg
on annual NOx nonbaseload output emission rate
Ib/MWh
104
NRNBNXO
NERC reg
on ozone season NOx nonbaseload outputemission rate
Ib/MWh
105
NRNBS02
NERC reg
on annual S02 nonbaseload output emission rate
Ib/MWh
106
NRNBC02
NERC reg
on annual C02nonbaseload outputemission rate
Ib/MWh
Technical Guide for eGRI D2020
I pg- 97
-------�
APPENDIX A
Field
Name
Description
Unit
107
NRNBCH4
NERC reg
on annual CH4 nonbaseload output emission rate
Ib/MWh
108
NRNBN20
NERC reg
on annual N20 nonbase load output emission rate
Ib/MWh
109
NRNBC2E
NERC reg
on annual C02equivalent nonbaseload output emission rate
Ib/MWh
110
NRNBHG
NERC reg
on annual Hg nonbaseloadoutputemission rate
Ib/MWh
111
NRGENACL
NERC reg
on annual coal net generation
MWh
112
NRGENAOL
NERC reg
on annual oil net generation
MWh
113
NRGENAGS
NERC reg
on annual gas net generation
MWh
114
NRGENANC
NERC reg
on annual nuclear net generation
MWh
115
NRGENAHY
NERC reg
on annual hydro net generation
MWh
116
NRGENABM
NERC reg
on annual bio mass net generation
MWh
117
NRGENAWI
NERC reg
on annual wind net generation
MWh
118
NRGENASO
NERC reg
on annual solar net generation
MWh
119
NRGENAGT
NERC reg
on annual geothermal net generation
MWh
120
NRGENAOF
NERC reg
on annual otherfossil net generation
MWh
121
NRGENAOP
NERC reg
on annual otherunknown/purchased fuel net generation
MWh
122
NRGENATN
NERC reg
on annual total nonrenewables net generation
MWh
123
NRGENATR
NERC reg
on annual total renewables net generation
MWh
124
NRGENATH
NERC reg
on annual total nonhydro renewables netgeneration
MWh
125
NRGENACY
NERC reg
on annual total combustion net generation
MWh
126
NRGENACN
NERC reg
on annual total noncombustion net generation
MWh
127
NRCLPR
NERC reg
on coal generation percent (resource mix)
%
128
NROLPR
NERC reg
on oil generation percent (resource mix)
%
129
NRGSPR
NERC reg
on gas generation percent (resource mix)
%
130
NRNCPR
NERC reg
on nucleargeneration percent (resource mix)
%
131
NRHYPR
NERC reg
on hydro generation percent (resource mix)
%
132
NRBMPR
NERC reg
on biomass generation percent (resource mix)
%
133
NRWIPR
NERC reg
on wind generation percent(resource mix)
%
134
NRSOPR
NERC reg
on solargeneration percent (resource mix)
%
135
NRGTPR
NERC reg
on geothermal generation percent (resource mix)
%
136
NROFPR
NERC reg
on otherfossil generation percent (resource mix)
%
137
NROPPR
NERC reg
on otherunknown/purchased fuel generation percent (resource mix)
%
138
NRTNPR
NERC reg
on total nonrenewables generation percent(resource mix)
%
139
NRTRPR
NERC reg
on total renewables generation percent (resource mix)
%
140
NRTHPR
NERC reg
on total nonhydro renewables generation percent (resource mix)
%
141
NRCYPR
NERC reg
on total combustion generation percent (resource mix)
%
142
NRCNPR
NERC reg
on total noncombustion generation percent(resource mix)
%
143
NRNBGNCL
NERC reg
on annual total nonbase load coal generation
MWh
144
NRNBGNOL
NERC reg
on annual total nonbase load oil generation
MWh
145
NRNBGNGS
NERC reg
on annual total nonbaseload gas generation
MWh
146
NRNBGNNC
NERC reg
on annual total nonbaseload nucleargeneration
MWh
147
NRNBGNHY
NERC reg
on annual total nonbaseload hydro generation
MWh
148
NRNBGNBM
NERC reg
on annual total nonbase load bio mass generation
MWh
149
NRNBGNWI
NERC reg
on annual total nonbase load wind generation
MWh
150
NRNBGNSO
NERC reg
on annual total nonbase load solar generation
MWh
151
NRNBGNGT
NERC reg
on annual total nonbaseload geothermal generation
MWh
152
NRNBGNOF
NERC reg
on annual total nonbase load other fossil generation
MWh
153
NRNBGNOP
NERC reg
on annual total nonbaseload other unknown/purchased fuel generation
MWh
154
NRNBCLPR
NERC reg
on nonbaseload coal generation percent (resource mix)
%
155
NRNBOLPR
NERC reg
on nonbaseload oil generation percent (resource mix)
%
156
NRNBGSPR
NERC reg
on nonbaseload gas generation percent (resource mix)
%
157
NRNBNCPR
NERC reg
on nonbaseload nucleargeneration percent (resource mix)
%
158
NRNBHYPR
NERC reg
on nonbaseload hydro generation percent (resource mix)
%
159
NRNBBMPR
NERC reg
on nonbaseload biomass generation percent (resource mix)
%
160
NRNBWIPR
NERC reg
on nonbaseload wind generation percent(resource mix)
%
Technical Guide for eGRI D2020
I pg- 98
-------�
APPENDIX A
Field
Name
Description
Unit
161
NRNBSOPR
NERC region nonbaseload solargeneration percent (resource mix)
%
162
NRNBGTPR
NERC region nonbaseload geothermai generation percent (resource mix)
%
163
NRNBOFPR
NERC region nonbaseload other fossil generation percent (resource mix)
%
164
NRNBOPPR
NERC region nonbaseload otherunknown/purchased fuel generation percent
(resource mix)
%
Technical Guide for eGRI D2020
I pg- 99
-------�
Field
~
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
APPENDIX A
Table A-8. eGRID File Structure, eGRID2020 U.S. File, United States File
Name
Description
Unit
YEAR
Data year
USNAMEPCAP
U.S. nameplate capacity
MW
USHTIAN
U.S. annual heat input from combustion
MMBtu
USHTIOZ
U.S. ozone season heat input from combustion
MMBtu
USHTIANT
U.S. total annual heat input
MMBtu
USHTIOZT
U.S. total ozone season heatinput
MMBtu
USNGENAN
U.S. annual net generation
MWh
USNGENOZ
U.S. ozone season net generation
MWh
USNOXAN
U.S. annual NOxemissions
tons
USNOXOZ
U.S. ozone season NOxemissions
tons
USS02AN
U.S. annual S02emissions
tons
USC02AN
U.S. annual C02emissions
tons
USCH4AN
U.S. annual CH4 emissions
lbs
USN20AN
U.S. annual N20 emissions
lbs
USC02EQA
U.S. annual C02equivalent emissions
tons
USHGAN
U.S. annual Hg emissions
lbs
USNOXRTA
U.S. annual NOxtotal outputemission rate
Ib/MWh
USNOXRTO
U.S. ozone season NOx total outputemission rate
Ib/MWh
USS02RTA
U.S. annual S02total outputemission rate
Ib/MWh
USC02RTA
U.S. annual C02total outputemission rate
Ib/MWh
USCH4RTA
U.S. annual CH4 total outputemission rate
Ib/MWh
USN20RTA
U.S. annual N20 total outputemission rate
Ib/MWh
USC2ERTA
U.S. annual C02equivalent total output emission rate
Ib/MWh
USHGRTA
U.S. annual Hg total output emission rate
Ib/MWh
USNOXRA
U.S. annual NOx input emission rate
Ib/MMBtu
USNOXRO
U.S. ozone season NOx input emission rate
Ib/MMBtu
USS02RA
U.S. annual S02input emission rate
Ib/MMBtu
USC02RA
U.S. annual C02input emission rate
Ib/MMBtu
USCH4RA
U.S. annual CH4 input emission rate
Ib/MMBtu
USN20RA
U.S. annual N20 input emission rate
Ib/MMBtu
USC2ERA
U.S. annual C02equivalent input emission rate
Ib/MMBtu
USHGRA
U.S. annual Hg input emission rate
Ib/MMBtu
USNOXCRT
U.S. annual NOxcombustion outputemission rate
Ib/MWh
USNOXCRO
U.S. ozone season NOxcombustion output emission rate
Ib/MWh
USS02CRT
U.S. annual S02combustion outputemission rate
Ib/MWh
USC02CRT
U.S. annual C02combustion output emission rate
Ib/MWh
USCH4CRT
U.S. annual CH4 combustion outputemission rate
Ib/MWh
USN20CRT
U.S. annual N20 combustion outputemission rate
Ib/MWh
USC2ECRT
U.S. annual C02equivalent combustion outputemission rate
Ib/MWh
USHGCRT
U.S. annual Hg combustion outputemission rate
Ib/MWh
USCNOXRT
U.S. annual NOx coal output emission rate
Ib/MWh
USONOXRT
U.S. annual NOx oil output emission rate
Ib/MWh
USGNOXRT
U.S. annual NOxgasoutputemission rate
Ib/MWh
USFSNXRT
U.S. annual NOx fossil fuel output emission rate
Ib/MWh
USCNXORT
U.S. ozone season NOx coal output emission rate
Ib/MWh
USONXORT
U.S. ozone season NOx oil output emission rate
Ib/MWh
USGNXORT
U.S. ozone season NOxgasoutputemission rate
Ib/MWh
USFSNORT
U.S. ozone season NOx fossil fuel output emission rate
Ib/MWh
USCS02RT
U.S. annual S02coal output emission rate
Ib/MWh
USOS02RT
U.S. annual S02oil outputemission rate
Ib/MWh
USGS02RT
U.S. annual S02gas output emission rate
Ib/MWh
Technical Guide for eGRI D2020
| pg. 100
-------�
Field
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
Name
Description
USFSS2RT
U.S. annua
S02fossil fuel output emission rate
USCC02RT
U.S. annua
C02coai output emission rate
USOC02RT
U.S. annua
C02oil output emission rate
USGC02RT
U.S. annua
C02gas output emission rate
USFSC2RT
U.S. annua
C02fossil fuel output emission rate
USCCH4RT
U.S. annua
CH4 coal output emission rate
USOCH4RT
U.S. annua
CH4 oil output emission rate
USGCH4RT
U.S. annua
CH4 gas output emission rate
USFCH4RT
U.S. annua
CH4 fossil fuel output emission rate
USCN20RT
U.S. annua
N20 coal output emission rate
USON20RT
U.S. annua
N20 oil output emission rate
USGN20RT
U.S. annua
N20 gas output emission rate
USFN20RT
U.S. annua
N20 fossil fuel output emission rate
USCC2ERT
U.S. annua
C02equivalent coal output emission rate
USOC2ERT
U.S. annua
C02equivalent oil output emission rate
USGC2ERT
U.S. annua
C02equivalent gasoutputemission rate
USFSC2ERT
U.S. annua
C02equivalent fossil fuel output emission rate
USCHGRT
U.S. annua
Hg coal output emission rate
USFSHGRT
U.S. annua
Hg fossil fuel output emission rate
USCNOXR
U.S. annua
NOxCoal input emission rate
USONOXR
U.S. annua
NOxOil input emission rate
USGNOXR
U.S. annua
NOxgas input emission rate
USFSNXR
U.S. annua
NOx fossil fuel input emission rate
USCNXOR
U.S. ozone season NOxcoal input emission rate
USONXOR
U.S. ozone season NOxoil input emission rate
USGNXOR
U.S. ozone season NOxgas input emission rate
USFSNOR
U.S. ozone season NOx fossil fuel input emission rate
USCS02R
U.S. annua
S02coal input emission rate
US0S02R
U.S. annua
S02oil input emission rate
USGS02R
U.S. annua
S02gas input emission rate
USFSS2R
U.S. annua
S02fossil fuel input emission rate
USCC02R
U.S. annua
C02coal input emission rate
US0C02R
U.S. annua
C02oil input emission rate
USGC02R
U.S. annua
C02gas input emission rate
USFSC2R
U.S. annua
C02fossil fuel input emission rate
USCCH4R
U.S. annua
CH4 coal input emission rate
USOCH4R
U.S. annua
CH4 oil input emission rate
USGCH4R
U.S. annua
CH4 gas input emission rate
USFCH4R
U.S. annua
CH4 fossil fuel input emission rate
USCN20R
U.S. annua
N20 coal input emission rate
US0N20R
U.S. annua
N20 oil input emission rate
USGN20R
U.S. annua
N20 gas input emission rate
USFN20R
U.S. annua
N20 fossil fuel input emission rate
USCC2ER
U.S. annua
C02equivalent coal input emission rate
USOC2ER
U.S. annua
C02equivalent oil input emission rate
USGC2ER
U.S. annua
C02equivalent gas input emission rate
USFSC2ER
U.S. annua
C02equivalent fossil fuel input emission rate
USCHGR
U.S. annua
Hg coal input emission rate
USFSHGR
U.S. annua
Hg fossil fuel input emission rate
USNBNOX
U.S. annua
NOx nonbaseload output emission rate
USNBNXO
U.S. ozone season NOx nonbase load output emission rate
USNBS02
U.S. annual S02nonbaseload output emission rate
Technical Guide for eGRI D2020
-------�
APPENDIX A
Field
Name
Description
Unit
104
USNBC02
U.S. annual C02nonbaseload output emission rate
Ib/MWh
105
USNBCH4
U.S. annual CH4 nonbaseload output emission rate
Ib/MWh
106
USNBN20
U.S. annual N20 nonbaseload output emission rate
Ib/MWh
107
USNBC2E
U.S. annual C02equivalent nonbaseload output emission rate
Ib/MWh
108
USNBHG
U.S. annual Hg nonbaseload outputemission rate
Ib/MWh
109
USGENACL
U.S. annual coal net generation
MWh
110
USGENAOL
U.S. annual oil net generation
MWh
111
USGENAGS
U.S. annual gas net generation
MWh
112
USGENANC
U.S. annual nuclearnet generation
MWh
113
USGENAHY
U.S. annual hydro net generation
MWh
114
USGENABM
U.S. annual bio mass net generation
MWh
115
USGENAWI
U.S. annual wind net generation
MWh
116
USGENASO
U.S. annual solar net generation
MWh
117
USGENAGT
U.S. annual geothermal net generation
MWh
118
USGENAOF
U.S. annual other fossil net generation
MWh
119
USGENAOP
U.S. annual other unknown/purchased fuel net generation
MWh
120
USGENATN
U.S. annual total nonrenewables net generation
MWh
121
USGENATR
U.S. annual total renewablesnet generation
MWh
122
USGENATH
U.S. annual total nonhydro renewables net generation
MWh
123
USGENACY
U.S. annual total combustion net generation
MWh
124
USGENACN
U.S. annual total noncombustion net generation
MWh
125
USCLPR
U.S. coal generation percent (resource mix)
%
126
USOLPR
U.S. oil generation percent(resource mix)
%
127
USGSPR
U.S. gas generation percent (resource mix)
%
128
USNCPR
U.S. nucleargeneration percent (resource mix)
%
129
USHYPR
U.S. hydro generation percent(resource mix)
%
130
USBMPR
U.S. bio mass generation percent (resource mix)
%
131
USWIPR
U.S. wind generation percent (resource mix)
%
132
USSOPR
U.S. solar generation percent (resource mix)
%
133
USGTPR
U.S. geothermal generation percent(resource mix)
%
134
USOFPR
U.S. otherfossil generation percent (resource mix)
%
135
USOPPR
U.S. other unknown/purchased fuel generation percent (resource mix)
%
136
USTNPR
U.S. total nonrenewables generation percent (resource mix)
%
137
USTRPR
U.S. total renewables gene ration percent (resource mix)
%
138
USTHPR
U.S. total nonhydro renewables generation percent (resource mix)
%
139
USCYPR
U.S. total combustion generation percent (resource mix)
%
140
USCNPR
U.S. total noncombustion generation percent (resource mix)
%
141
USNBGNCL
U.S. annual total nonbaseload coal generation
MWh
142
USNBGNOL
U.S. annual total nonbaseload oil generation
MWh
143
USNBGNGS
U.S. annual total nonbaseload gas generation
MWh
144
USNBGNNC
U.S. annual total nonbaseload nucleargeneration
MWh
145
USNBGNHY
U.S. annual total nonbaseload hydro generation
MWh
146
USNBGNBM
U.S. annual total nonbaseload bio mass generation
MWh
147
USNBGNWI
U.S. annual total nonbaseload wind generation
MWh
148
USNBGNSO
U.S. annual total nonbaseload solargeneration
MWh
149
USNBGNGT
U.S. annual total nonbaseload geothermal generation
MWh
150
USNBGNOF
U.S. annual total nonbaseload otherfossil generation
MWh
151
USNBGNOP
U.S. annual total nonbaseload other unknown/purchased fuel generation
MWh
152
USNBCLPR
U.S. nonbaseload coal generation percent (resource mix)
%
153
USNBOLPR
U.S. nonbaseload oil generation percent(resource mix)
%
154
USNBGSPR
U.S. nonbaseload gas generation percent (resource mix)
%
155
USNBNCPR
U.S. nonbaseload nucleargeneration percent (resource mix)
%
Technical Guide for eGRI D2020
I pg-102
-------�
APPENDIX A
Field
Name
Description
Unit
156
USNBHYPR
U.S. nonbaseload hydro generation percent(resource mix)
%
157
USNBBMPR
U.S. nonbaseload bio mass generation percent (resource mix)
%
158
USNBWIPR
U.S. nonbaseload wind generation percent (resource mix)
%
159
USNBSOPR
U.S. nonbaseload solargeneration percent (resource mix)
%
160
USNBGTPR
U.S. nonbaseload geothermal generation percent(resource mix)
%
161
USNBOFPR
U.S. nonbaseload otherfossil generation percent (resource mix)
%
162
USNBOPPR
U.S. nonbaseload other unknown/purchased fuel generation percent (resource
mix)
%
Technical Guide for eGRI D2020
| pg. 103
-------�
APPENDIX A
Table A-9. eGRID File Structure, eGRID2020GGL File, Grid Gross Loss (%) File
Field
Name
Description
Unit
Source(s)
1
YEAR
Data year
2
REGION
One ofthe three interconnect powergridsin the U.S.
(plusAlaska, Hawaii, and the entire U.S.)
3
ESTLOSS
The total amount of electricity in the region that is
generated but is not sold for resale or wholesale,
furnished without charge, or used by the generator or
utility
MWh
EIA State Electricity Profiles,
Supply and disposition of
electricity, 1990-2020
4
TOTDISP
The total amount of electricity in the region that is so Id
directly to customers, sold forresale, furnished without
charge, consumed by the respondent without charge,
and lost, without exports included
MWh
EIA State Electricity Profiles,
Supply and disposition of
electricity, 1990-2020
5
DIRCTUSE
The total amount of electricity used by plants and/or
utilities in the region that is not sold for wholesale or
resale; direct use electricity is not transmitted through
the grid and therefore does not have the potential to
be lost
MWh
EIA State Electricity Profiles,
Supply and disposition of
electricity, 1990-2020
6
GGRSLOSS
The estimated regional grid gross loss as a percent
[Estimated losses/(Total disposition - Direct use)l*100
%
Technical Guide for eGRI D2020
| pg. 104
-------�
APPENDIX B
Appendix B. eGRID Subregion and NERC Region
Representational Maps
Figure EM. eGRID Subregion Representational Map
MROW
NWPP
MROE
NYUP
RFCM
RFCW
RMPA
SRMW
AZNM
SRMV
USEPA, eGRID, January 2022
Crosshatching indicates that an area falls within overlapping
eGRID subregions due to the presence of multiple eiectric
service providers. Visit Power Profiler to definitively determine
the eGRID subregion associated with your location and
electric service provider. ^
http ://www.epa .gov/energy/power-profi ler
NEWE
CAMX
FRCC
This is a representational map; many ofthe boundaries shown on this map are approximate because they are
based on companies, notonstrictgeographical boundaries.
Technical Guide for eGRI D2020
| pg. 105
-------�
APPENDIX B
Figure B-2. NERC Region Representational Map
Source: NERC, 2020
This is a representational map; many ofthe boundaries shown on this map are approximate because they are
based on companies, notonstrictgeographical boundaries.
Technical Guide for eGRI D2020
1 P9-106
-------�
APPENDIX C
Appendix C. Crosswalks and Additional Data Tables
This Appendix contains reference tables used in the development of eGRID2020. These include:
Emission factors used to estimate emissions (where they are not available from CAMD's
Power Sector Emissions Data);
Biomass fuels used in the plant file biomass emissions adjustment;
A crosswalk of plant ORISPL IDs that are different between CAMD's Power Sector
Emissions Data and EIA data;
Geothermal emission factors by geotype and pollutant; and
English to Metric conversion factors.
Emission Factors - NOx, C02, S02, CH4, and N20
For more information regarding the emission factors used and the methodology to estimate emissions,
please see Section 3.1. Emission factors that have changed in eGRID2020 are represented in bold in
the table.
Table C-1. eGRID Emission Factors for CO2, CH4, and N2O
Fuel Type
EIA Fuel
Type Code
CO2EF
(ton
C02/mmBtu)
ch4 ef
(lb
ChWmmBtu)
N20 EF
(lb
N20/mmBtu)
Source
Agricultural
Byproducts
AB
0.13026
0.07055
0.00926
(EPA, 2009)
Anthracite
ANT
0.11413
0.02425
0.00353
(EPA, 2009)
Blast Furnace
Gas
BFG
0.30239
0.00005
0.00022
(EPA, 2009)
Bituminous
BIT
0.10296
0.02425
0.00353
(EPA, 2009)
Sulphite lyes
(Black Liquor)
BLQ
0.11083
0.00698
0.00465
(IPCC, 2007a)
Coke Oven
Gas
COG
0.05164
0.00106
0.00022
(EPA, 2009)
Distillate Fuel
Oil (avg)
DFO
0.08166
0.00661
0.00132
(EPA, 2009)
Hydrogen
H
0.00000
0.00000
0.00000
No EF
Kerosene-
Type Jet Fuel
JF
0.07961
0.00661
0.00132
(EPA, 2009)
Kerosene
KER
0.08289
0.00661
0.00132
(EPA, 2009)
Landfill Gas
LFG
0.06350
0.00233
0.00023
(IPCC, 2007a)
Lignite
LIG
0.10622
0.02425
0.00353
(EPA, 2009)
Municipal
Solid Waste
(Biomass)
MSB
0.09998
0.07055
0.00926
(EPA, 2009)
Municipal
Solid Waste
(Non-Biomass)
MSN
0.09998
0.07055
0.00926
(EPA, 2009)
Municipal
Solid Waste
(Biomass)
MSW
0.09998
0.07055
0.00926
(EPA, 2009)
Technical Guide for eGRID2020
I P9-107
-------�
APPENDIX C
Fuel Type
EIA Fuel
Type Code
C02EF
(ton
C02/mmBtu)
ch4 ef
(lb
ChWmmBtu)
N20 EF
(lb
N20/mmBtu)
Source
Megawatt
hours
MWH
0.00000
0.00000
0.00000
No EF
Pipeline
(Weighted
U.S. Average)
NG
0.05844
0.00220
0.00022
(EPA, 2009)
Nuclear
NUC
0.00000
0.00000
0.00000
No EF
Other Biogas
OBG
0.06350
0.00233
0.00023
(IPCC, 2007a)
Other Liquid
Biofuels
OBL
0.09257
0.00698
0.00140
(IPCC, 2007a)
Other Primary
Solid Biomass
OBS
0.11630
0.06978
0.00930
(IPCC, 2007a)
Other Gas
OG
0.05844
0.00220
0.00022
Use NG EF
Petroleum
Coke
PC
0.11289
0.00661
0.00132
(EPA, 2009)
Propane
PG
0.06775
0.00661
0.00132
(EPA, 2009)
Process Gas
PRG
0.05844
0.00220
0.00022
Use NG EF
Purchased
Steam
PUR
0.00000
0.00000
0.00000
No EF
Refined Coal
RC
0.10529
0.02425
0.00353
(EPA, 2009)
Residual Fuel
Oil (avg)
RFO
0.08159
0.00661
0.00132
(EPA, 2009)
Synthetic Gas
- Petroleum
Coke
SGP
0.05844
0.00220
0.00022
Use NG EF
Sludge Waste
SLW
0.09257
0.00698
0.00140
Use OBL EF
Subbituminous
SUB
0.10695
0.02425
0.00353
(EPA, 2009)
Solar
SUN
0.00000
0.00000
0.00000
No EF
Tires
TDF
0.09477
0.07055
0.00926
(EPA, 2009)
Water
WAT
0.00000
0.00000
0.00000
No EF
Waste Coal
WC
0.10529
0.02425
0.00353
(EPA, 2009)
Wood, Wood
Waste Liquid
WDL
0.09257
0.00698
0.00140
Use OBL EF
Wood and
Wood
Residuals
WDS
0.10340
0.07055
0.00926
(EPA, 2009)
Waste Heat
WH
0.00000
0.00000
0.00000
No EF
Wind
WND
0.00000
0.00000
0.00000
No EF
Waste Oils
WO
0.08525
0.06978
0.00930
(IPCC, 2007a)
Table C-2. eGRID Emission Factors for Nitrogen Oxides (NOx)
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
AB
N/A
1.2
lb
ton
Technical Guide for eGRID2020
| pg. 108
-------�
APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
AB
STOKER
1.2
lb
ton
ST
BFG
N/A
0.0154
lb
mcf
ST
BFG
TANGENTIAL
0.0154
lb
mcf
ST
BFG
WALL
0.0154
lb
mcf
ST
BIT
CYCLONE
33
lb
ton
ST
BIT
DRY CYCLONE
33
lb
ton
ST
BIT
DRY FLUIDIZED
5
lb
ton
ST
BIT
DRY STOKER
11
lb
ton
ST
BIT
DRY TANGENTIAL
10
lb
ton
ST
BIT
DRY VERTICAL
12
lb
ton
ST
BIT
DRY WALL
12
lb
ton
ST
BIT
FLUIDIZED
5
lb
ton
ST
BIT
N/A
12
lb
ton
ST
BIT
OTHER
12
lb
ton
ST
BIT
STOKER
11
lb
ton
ST
BIT
TANGENTIAL
10
lb
ton
ST
BIT
WALL
12
lb
ton
ST
BIT
WET CYCLONE
33
lb
ton
ST
BIT
WET FLUIDIZED
5
lb
ton
ST
BIT
WETOTHER
31
lb
ton
ST
BIT
WET TANGENTIAL
14
lb
ton
ST
BIT
WET VERTICAL
31
lb
ton
ST
BIT
WET WALL
31
lb
ton
ST
BLQ
CYCLONE
1.5
lb
ton
ST
BLQ
DRY FLUIDIZED
1.5
lb
ton
ST
BLQ
DRY TANGENTIAL
1.5
lb
ton
ST
BLQ
DRY WALL
1.5
lb
ton
ST
BLQ
FLUIDIZED
1.5
lb
ton
ST
BLQ
N/A
1.5
lb
ton
ST
BLQ
OTHER
1.5
lb
ton
ST
BLQ
TANGENTIAL
1.5
lb
ton
ST
BLQ
WALL
1.5
lb
ton
ST
COG
CYCLONE
0.0154
lb
mcf
OT
COG
N/A
0.0154
lb
mcf
ST
COG
N/A
0.0154
lb
mcf
ST
COG
WALL
0.0154
lb
mcf
CT
DFO
CC
5.124
lb
barrels
GT
DFO
CT
5.124
lb
barrels
Technical Guide for eGRID2020
| pg. 109
-------�
APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
DFO
DRY TANGENTIAL
1.008
lb
barrels
ST
DFO
DRY WALL
1.008
lb
barrels
CT
DFO
N/A
5.124
lb
barrels
ST
DFO
N/A
1.008
lb
barrels
CA
DFO
N/A
5.124
lb
barrels
CS
DFO
N/A
5.124
lb
barrels
CT
DFO
N/A
5.124
lb
barrels
GT
DFO
N/A
5.124
lb
barrels
IC
DFO
N/A
18.6396
lb
barrels
ST
DFO
N/A
1.008
lb
barrels
ST
DFO
OTHER
1.008
lb
barrels
ST
DFO
TANGENTIAL
1.008
lb
barrels
ST
DFO
WALL
1.008
lb
barrels
ST
DFO
WET TANGENTIAL
1.008
lb
barrels
GT
JF
CT
4.9896
lb
barrels
GT
JF
N/A
4.9896
lb
barrels
IC
JF
N/A
18.144
lb
barrels
ST
JF
N/A
1.008
lb
barrels
GT
KER
CT
4.9896
lb
barrels
GT
KER
N/A
4.9896
lb
barrels
CA
LFG
N/A
0.087
lb
mcf
CS
LFG
N/A
0.087
lb
mcf
CT
LFG
N/A
0.087
lb
mcf
GT
LFG
N/A
0.087
lb
mcf
IC
LFG
N/A
0.725
lb
mcf
ST
LFG
N/A
0.042
lb
mcf
ST
LIG
DRY FLUIDIZED
3.6
lb
ton
ST
LIG
DRY TANGENTIAL
7.1
lb
ton
ST
LIG
DRY WALL
6.3
lb
ton
ST
LIG
FLUIDIZED
3.6
lb
ton
ST
LIG
N/A
6.3
lb
ton
ST
LIG
TANGENTIAL
7.1
lb
ton
ST
LIG
WET CYCLONE
15
lb
ton
ST
LIG
WET FLUIDIZED
3.6
lb
ton
ST
MSB
N/A
5
lb
ton
ST
MSW
N/A
5
lb
ton
ST
MSW
OTHER
5
lb
ton
CT
NG
CC
0.32
lb
MMBtu
Technical Guide for eGRID2020
| pg. 110
-------�
APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
CT
NG
CC
0.328
lb
mcf
GT
NG
CT
0.328
lb
mcf
ST
NG
CYCLONE
0.28
lb
mcf
ST
NG
DRY CYCLONE
0.28
lb
mcf
CA
NG
DRYDUCTBURNER
0.328
lb
mcf
ST
NG
DRYDUCTBURNER
0.17
lb
mcf
ST
NG
DRY STOKER
0.28
lb
mcf
ST
NG
DRY TANGENTIAL
0.17
lb
mcf
ST
NG
DRY VERTICAL
0.28
lb
mcf
CA
NG
DRY WALL
0.328
lb
mcf
ST
NG
DRY WALL
0.28
lb
mcf
CA
NG
DUCTBURNER
0.328
lb
mcf
CS
NG
DUCTBURNER
0.328
lb
mcf
CT
NG
DUCTBURNER
0.328
lb
mcf
ST
NG
DUCTBURNER
0.17
lb
mcf
ST
NG
FLUIDIZED
0.28
lb
mcf
CT
NG
N/A
0.328
lb
mcf
ST
NG
N/A
0.17
lb
mcf
CA
NG
N/A
0.32
lb
MMBtu
CS
NG
N/A
0.32
lb
MMBtu
CT
NG
N/A
0.32
lb
MMBtu
GT
NG
N/A
0.32
lb
MMBtu
IC
NG
N/A
2.768
lb
mcf
ST
NG
N/A
0.17
lb
mcf
ST
NG
OTHER
0.17
lb
mcf
ST
NG
STOKER
0.28
lb
mcf
GT
NG
TANGENTIAL
0.328
lb
mcf
ST
NG
TANGENTIAL
0.17
lb
mcf
ST
NG
WALL
0.28
lb
mcf
ST
NG
WET CYCLONE
0.28
lb
mcf
CA
OBG
N/A
0.3136
lb
mcf
CS
OBG
N/A
0.3136
lb
mcf
CT
OBG
N/A
0.3136
lb
mcf
GT
OBG
N/A
0.3136
lb
mcf
IC
OBG
N/A
2.64648
lb
mcf
ST
OBG
N/A
0.11283
lb
mcf
GT
OBL
N/A
4.7166
lb
barrels
IC
OBL
N/A
17.1486
lb
barrels
Technical Guide for eGRID2020
| pg. 111
-------�
APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
OBS
N/A
2
lb
ton
ST
OBS
STOKER
2
lb
ton
GT
OG
CT
0.26382
lb
mcf
ST
OG
CYCLONE
0.15282
lb
mcf
ST
OG
DRYDUCTBURNER
0.15282
lb
mcf
ST
OG
DRY TANGENTIAL
0.15282
lb
mcf
ST
OG
DRY WALL
0.15282
lb
mcf
CA
OG
DUCTBURNER
0.15282
lb
mcf
ST
OG
DUCTBURNER
0.15282
lb
mcf
ST
OG
N/A
0.15282
lb
mcf
CA
OG
N/A
0.15282
lb
mcf
GT
OG
N/A
0.26382
lb
mcf
IC
OG
N/A
2.22641
lb
mcf
ST
OG
N/A
0.15282
lb
mcf
ST
OG
OTHER
0.15282
lb
mcf
ST
OG
TANGENTIAL
0.15282
lb
mcf
CA
OG
WALL
0.15282
lb
mcf
ST
OG
WALL
0.15282
lb
mcf
CT
OTH
CC
0.328
lb
mcf
GT
OTH
CT
0.328
lb
mcf
ST
OTH
CYCLONE
0.28
lb
mcf
ST
OTH
DRY CYCLONE
0.28
lb
mcf
CA
OTH
DRYDUCTBURNER
0.328
lb
mcf
ST
OTH
DRYDUCTBURNER
0.17
lb
mcf
ST
OTH
DRY STOKER
0.28
lb
mcf
ST
OTH
DRY TANGENTIAL
0.17
lb
mcf
ST
OTH
DRY VERTICAL
0.28
lb
mcf
CA
OTH
DRY WALL
0.328
lb
mcf
ST
OTH
DRY WALL
0.28
lb
mcf
CA
OTH
DUCTBURNER
0.328
lb
mcf
CS
OTH
DUCTBURNER
0.328
lb
mcf
CT
OTH
DUCTBURNER
0.328
lb
mcf
ST
OTH
DUCTBURNER
0.17
lb
mcf
ST
OTH
FLUIDIZED
0.28
lb
mcf
CT
OTH
N/A
0.328
lb
mcf
ST
OTH
N/A
0.17
lb
mcf
CA
OTH
N/A
0.328
lb
mcf
CS
OTH
N/A
0.328
lb
mcf
Technical Guide for eGRID2020
I P9-112
-------�
APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
CT
OTH
N/A
0.328
lb
mcf
GT
OTH
N/A
0.328
lb
mcf
IC
OTH
N/A
2.768
lb
mcf
OT
OTH
N/A
0.328
lb
mcf
ST
OTH
OTHER
0.17
lb
mcf
ST
OTH
STOKER
0.28
lb
mcf
GT
OTH
TANGENTIAL
0.328
lb
mcf
GT
OTH
TANGENTIAL
0.328
lb
mcf
ST
OTH
TANGENTIAL
0.17
lb
mcf
ST
OTH
WALL
0.28
lb
mcf
ST
OTH
WET CYCLONE
0.28
lb
mcf
ST
PC
DRY FLUIDIZED
5
lb
ton
ST
PC
DRY WALL
21
lb
ton
ST
PC
FLUIDIZED
5
lb
ton
OT
PC
N/A
21
lb
ton
ST
PC
N/A
21
lb
ton
CA
PC
OTHER
21
lb
ton
ST
PC
OTHER
21
lb
ton
ST
PC
WET WALL
21
lb
ton
CT
PG
CC
0.80336
lb
mcf
GT
PG
N/A
0.80336
lb
mcf
ST
PG
TANGENTIAL
0.52226
lb
mcf
ST
PG
WALL
0.52226
lb
mcf
ST
PRG
DRY WALL
0.28
lb
mcf
ST
PRG
DUCTBURNER
0.17
lb
mcf
ST
PRG
N/A
0.17
lb
mcf
GT
PRG
N/A
0.17
lb
mcf
ST
PRG
N/A
0.17
lb
mcf
ST
PRG
OTHER
0.17
lb
mcf
ST
PRG
TANGENTIAL
0.17
lb
mcf
ST
PRG
WALL
0.28
lb
mcf
ST
RC
DRY TANGENTIAL
10
lb
ton
ST
RFO
DRY TANGENTIAL
1.344
lb
barrels
ST
RFO
DRY WALL
1.974
lb
barrels
CT
RFO
N/A
5.5314
lb
barrels
CA
RFO
N/A
5.5314
lb
barrels
CS
RFO
N/A
5.5314
lb
barrels
GT
RFO
N/A
5.5314
lb
barrels
Technical Guide for eGRID2020
I P9-113
-------�
APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
IC
RFO
N/A
20.118
lb
barrels
ST
RFO
N/A
1.974
lb
barrels
ST
RFO
TANGENTIAL
1.344
lb
barrels
ST
RFO
WALL
1.974
lb
barrels
ST
RFO
WET WALL
1.974
lb
barrels
ST
SGC
N/A
0.28
lb
mcf
CA
SGP
N/A
0.28
lb
mcf
CS
SGP
N/A
0.28
lb
mcf
CT
SGP
N/A
0.28
lb
mcf
ST
SUB
CYCLONE
17
lb
ton
ST
SUB
DRY FLUIDIZED
5
lb
ton
ST
SUB
DRY TANGENTIAL
7.2
lb
ton
ST
SUB
DRY WALL
7.4
lb
ton
ST
SUB
FLUIDIZED
5
lb
ton
ST
SUB
N/A
5
lb
ton
ST
SUB
STOKER
8.8
lb
ton
ST
SUB
TANGENTIAL
7.2
lb
ton
ST
SUB
WALL
ST
SUB
WET CYCLONE
17
lb
ton
ST
SUB
WET FLUIDIZED
5
lb
ton
ST
SUB
WET TANGENTIAL
7.2
lb
ton
ST
SUB
WET WALL
24
lb
ton
ST
TDF
STOKER
11
lb
ton
ST
WC
DRY FLUIDIZED
3.6
lb
ton
ST
WC
FLUIDIZED
3.6
lb
ton
ST
WC
N/A
3.6
lb
ton
ST
WDL
N/A
0.22806
lb
barrels
ST
WDS
DRY FLUIDIZED
2
lb
ton
ST
WDS
DRY STOKER
1.5
lb
ton
ST
WDS
DRY TANGENTIAL
2.51
lb
ton
ST
WDS
DRY WALL
2.51
lb
ton
ST
WDS
FLUIDIZED
2
lb
ton
OT
WDS
N/A
2
lb
ton
ST
WDS
N/A
2
lb
ton
OT
WDS
OTHER
2
lb
ton
ST
WDS
OTHER
2
lb
ton
ST
WDS
STOKER
1.5
lb
ton
ST
WDS
TANGENTIAL
2.51
lb
ton
Technical Guide for eGRID2020
| pg. 114
-------�
APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
WDS
WALL
2.51
lb
ton
ST
WDS
WETSTOKER
1.5
lb
ton
ST
WDS
WET TANGENTIAL
2.51
lb
ton
ST
WO
DRY WALL
0.798
lb
barrels
CA
WO
N/A
3.8724
lb
barrels
CS
WO
N/A
3.8724
lb
barrels
CT
WO
N/A
3.8724
lb
barrels
GT
WO
N/A
3.8724
lb
barrels
IC
WO
N/A
14.0784
lb
barrels
ST
WO
N/A
0.798
lb
barrels
Source: AP-42 (EPA, 1995). EIA Electric Power Annual (EIA, 2021f).
N/A = not applicable
Table C-3. Sulfur dioxide (SO2) emission factors
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
AB
N/A
0.025
lb
MMBtu
ST
AB
STOKER
0.025
lb
MMBtu
ST
BFG
N/A
0.0006
lb
Mcf
ST
BFG
TANGENTIAL
0.0006
lb
Mcf
ST
BFG
WALL
0.0006
lb
Mcf
ST
BIT
CYCLONE
38*S
lb
short tons
ST
BIT
DRY CYCLONE
38*S
lb
short tons
ST
BIT
DRY FLUIDIZED
38*S
lb
short tons
ST
BIT
DRY STOKER
38*S
lb
short tons
ST
BIT
DRY TANGENTIAL
38*S
lb
short tons
ST
BIT
DRY VERTICAL
38*S
lb
short tons
ST
BIT
DRY WALL
38*S
lb
short tons
ST
BIT
FLUIDIZED
38*S
lb
short tons
ST
BIT
N/A
38*S
lb
short tons
ST
BIT
OTHER
38*S
lb
short tons
ST
BIT
OTHER
1.971977*S
lb
MMBtu
ST
BIT
STOKER
38*S
lb
short tons
ST
BIT
TANGENTIAL
38*S
lb
short tons
ST
BIT
WALL
38*S
lb
short tons
ST
BIT
WALL
1.971977*S
lb
MMBtu
Technical Guide for eGRID2020
| pg. 115
-------�
APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
BIT
WETCYCLONE
38*S
lb
short tons
ST
BIT
WETFLUIDIZED
38*S
lb
short tons
ST
BIT
WETOTHER
38*S
lb
short tons
ST
BIT
WET TANGENTIAL
38*S
lb
short tons
ST
BIT
WET VERTICAL
38*S
lb
short tons
ST
BIT
WET WALL
38*S
lb
short tons
ST
BLQ
CYCLONE
7
lb
short tons
ST
BLQ
DRY FLUIDIZED
0.7
lb
short tons
ST
BLQ
DRY TANGENTIAL
7
lb
short tons
ST
BLQ
DRY WALL
7
lb
short tons
ST
BLQ
FLUIDIZED
0.7
lb
short tons
ST
BLQ
N/A
7
lb
short tons
ST
BLQ
OTHER
7
lb
short tons
ST
BLQ
TANGENTIAL
7
lb
short tons
ST
BLQ
WALL
7
lb
short tons
ST
COG
CYCLONE
0.0006
lb
Mcf
OT
COG
N/A
0.0006
lb
Mcf
ST
COG
N/A
0.0006
lb
Mcf
ST
COG
WALL
0.0006
lb
Mcf
CT
DFO
CC
1.01*S
lb
MMBtu
GT
DFO
CT
1.01*S
lb
MMBtu
ST
DFO
DRY TANGENTIAL
6.3*S
lb
barrels
ST
DFO
DRY WALL
6.3*S
lb
barrels
CT
DFO
N/A
1.01*S
lb
MMBtu
ST
DFO
N/A
5.964*S
lb
barrels
CA
DFO
N/A
1.01*S
lb
MMBtu
CS
DFO
N/A
1.01*S
lb
MMBtu
CT
DFO
N/A
1.01*S
lb
MMBtu
GT
DFO
N/A
1.01*S
lb
MMBtu
IC
DFO
N/A
0.29
lb
MMBtu
ST
DFO
N/A
5.964*S
lb
barrels
ST
DFO
OTHER
5.964*S
lb
barrels
ST
DFO
TANGENTIAL
6.3*S
lb
barrels
ST
DFO
WALL
6.3*S
lb
barrels
ST
DFO
WET TANGENTIAL
6.3*S
lb
barrels
GT
JF
CT
0.003021
lb
barrels
GT
JF
N/A
0.003021
lb
barrels
IC
JF
N/A
0.003021
lb
barrels
Technical Guide for eGRID2020
| pg. 116
-------�
APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
JF
N/A
0.003021
lb
barrels
GT
KER
CT
1.01*S
lb
MMBtu
GT
KER
N/A
1.01*S
lb
MMBtu
CA
LFG
N/A
0.045
lb
MMBtu
CS
LFG
N/A
0.045
lb
MMBtu
CT
LFG
N/A
0.045
lb
MMBtu
GT
LFG
N/A
0.045
lb
MMBtu
IC
LFG
N/A
0.045
lb
MMBtu
ST
LFG
N/A
0.0006
lb
MCf
ST
LIG
DRY FLUIDIZED
30*S
lb
short tons
ST
LIG
DRY TANGENTIAL
30*S
lb
short tons
ST
LIG
DRY WALL
30*S
lb
short tons
ST
LIG
FLUIDIZED
10*S
lb
short tons
ST
LIG
N/A
30*S
lb
short tons
ST
LIG
TANGENTIAL
30*S
lb
short tons
ST
LIG
WETCYCLONE
30*S
lb
short tons
ST
LIG
WET FLUIDIZED
10*S
lb
short tons
ST
MSB
N/A
1.7
lb
short tons
ST
MSW
N/A
1.7
lb
short tons
ST
MSW
OTHER
1.7
lb
short tons
CT
NG
CC
0.003196
lb
MMBtu
CT
NG
CC
0.0006
lb
Mcf
GT
NG
CT
0.0006
lb
Mcf
ST
NG
CYCLONE
0.0006
lb
Mcf
ST
NG
DRY CYCLONE
0.0006
lb
Mcf
CA
NG
DRY DUCTBURNER
0.0006
lb
Mcf
ST
NG
DRY DUCTBURNER
0.0006
lb
Mcf
ST
NG
DRY STOKER
0.0006
lb
Mcf
ST
NG
DRY TANGENTIAL
0.0006
lb
Mcf
ST
NG
DRY VERTICAL
0.0006
lb
Mcf
CA
NG
DRY WALL
0.0006
lb
Mcf
ST
NG
DRY WALL
0.0006
lb
Mcf
CA
NG
DUCTBURNER
0.0006
lb
Mcf
CS
NG
DUCTBURNER
0.0006
lb
Mcf
CT
NG
DUCTBURNER
0.0006
lb
Mcf
ST
NG
DUCTBURNER
0.0006
lb
Mcf
ST
NG
FLUIDIZED
0.0006
lb
Mcf
CT
NG
N/A
0.0006
lb
Mcf
Technical Guide for eGRID2020
I P9-117
-------�
APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
NG
N/A
0.0006
lb
Mcf
CA
NG
N/A
0.003196
lb
MMBtu
CS
NG
N/A
0.003196
lb
MMBtu
CT
NG
N/A
0.003196
lb
MMBtu
GT
NG
N/A
0.003196
lb
MMBtu
IC
NG
N/A
0.003196
lb
MMBtu
ST
NG
N/A
0.003196
lb
MMBtu
ST
NG
OTHER
0.0006
lb
Mcf
ST
NG
OTHER
0.003196
lb
MMBtu
ST
NG
STOKER
0.0006
lb
Mcf
GT
NG
TANGENTIAL
0.0006
lb
Mcf
ST
NG
TANGENTIAL
0.0006
lb
Mcf
ST
NG
WALL
0.003196
lb
MMBtu
ST
NG
WALL
0.0006
lb
Mcf
ST
NG
WETCYCLONE
0.0006
lb
Mcf
CA
OBG
N/A
0.0065
lb
MMBtu
CS
OBG
N/A
0.0065
lb
MMBtu
CT
OBG
N/A
0.0065
lb
MMBtu
GT
OBG
N/A
0.0065
lb
MMBtu
IC
OBG
N/A
0.0065
lb
MMBtu
ST
OBG
N/A
0.0006
lb
MCf
GT
OBL
N/A
0.0065
lb
MMBtu
IC
OBL
N/A
0.0065
lb
MMBtu
ST
OBS
N/A
0.025
lb
MMBtu
ST
OBS
STOKER
0.025
lb
MMBtu
GT
OG
CT
0.0006
lb
MCf
ST
OG
CYCLONE
0.0006
lb
Mcf
ST
OG
DRY DUCTBURNER
0.0006
lb
Mcf
ST
OG
DRY TANGENTIAL
0.0006
lb
Mcf
ST
OG
DRY WALL
0.0006
lb
Mcf
CA
OG
DUCTBURNER
0.0006
lb
Mcf
ST
OG
DUCTBURNER
0.0006
lb
Mcf
ST
OG
N/A
0.0006
lb
Mcf
CA
OG
N/A
0.0006
lb
Mcf
GT
OG
N/A
0.0006
lb
MCf
IC
OG
N/A
0.000588
lb
MMBtu
ST
OG
N/A
0.0006
lb
Mcf
ST
OG
OTHER
0.0006
lb
Mcf
Technical Guide for eGRID2020
| pg. 118
-------�
APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
OG
TANGENTIAL
0.0006
lb
Mcf
CA
OG
WALL
0.0006
lb
Mcf
ST
OG
WALL
0.003196
lb
MMBtu
ST
OG
WALL
0.0006
lb
Mcf
CT
OTH
CC
0.0006
lb
Mcf
GT
OTH
CT
0.0006
lb
Mcf
ST
OTH
CYCLONE
0.0006
lb
Mcf
ST
OTH
DRY CYCLONE
0.0006
lb
Mcf
CA
OTH
DRY DUCTBURNER
0.0006
lb
Mcf
ST
OTH
DRY DUCTBURNER
0.0006
lb
Mcf
ST
OTH
DRY STOKER
2.8
lb
ton
ST
OTH
DRY STOKER
0.0006
lb
Mcf
ST
OTH
DRY TANGENTIAL
2.8
lb
ton
ST
OTH
DRY TANGENTIAL
0.0006
lb
Mcf
ST
OTH
DRY VERTICAL
2.8
lb
ton
ST
OTH
DRY VERTICAL
0.0006
lb
Mcf
CA
OTH
DRY WALL
2.8
lb
ton
CA
OTH
DRY WALL
0.0006
lb
Mcf
ST
OTH
DRY WALL
2.8
lb
ton
ST
OTH
DRY WALL
0.0006
lb
Mcf
CA
OTH
DUCTBURNER
2.8
lb
ton
CA
OTH
DUCTBURNER
0.0006
lb
Mcf
CS
OTH
DUCTBURNER
2.8
lb
ton
CS
OTH
DUCTBURNER
0.0006
lb
Mcf
CT
OTH
DUCTBURNER
2.8
lb
ton
CT
OTH
DUCTBURNER
0.0006
lb
Mcf
ST
OTH
DUCTBURNER
2.8
lb
ton
ST
OTH
DUCTBURNER
0.0006
lb
Mcf
ST
OTH
FLUIDIZED
2.8
lb
ton
ST
OTH
FLUIDIZED
0.0006
lb
Mcf
CT
OTH
N/A
2.8
lb
ton
CT
OTH
N/A
0.0006
lb
Mcf
ST
OTH
N/A
2.8
lb
ton
ST
OTH
N/A
0.0006
lb
Mcf
CA
OTH
N/A
2.8
lb
ton
CA
OTH
N/A
0.0006
lb
Mcf
CS
OTH
N/A
2.8
lb
ton
CS
OTH
N/A
0.0006
lb
Mcf
Technical Guide for eGRID2020
| pg. 119
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APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
GT
OTH
N/A
2.8
lb
ton
GT
OTH
N/A
0.0006
lb
Mcf
IC
OTH
N/A
2.8
lb
ton
IC
OTH
N/A
0.0006
lb
Mcf
OT
OTH
N/A
2.8
lb
ton
OT
OTH
N/A
0.0006
lb
Mcf
ST
OTH
OTHER
2.8
lb
ton
ST
OTH
OTHER
0.0006
lb
Mcf
ST
OTH
STOKER
2.8
lb
ton
ST
OTH
STOKER
0.0006
lb
Mcf
GT
OTH
TANGENTIAL
2.8
lb
ton
GT
OTH
TANGENTIAL
0.0006
lb
Mcf
ST
OTH
TANGENTIAL
2.8
lb
ton
ST
OTH
TANGENTIAL
0.0006
lb
Mcf
ST
OTH
WALL
2.8
lb
ton
ST
OTH
WALL
0.0006
lb
Mcf
ST
OTH
WETCYCLONE
2.8
lb
ton
ST
OTH
WETCYCLONE
0.0006
lb
Mcf
ST
PC
DRY FLUIDIZED
0.362*S
lb
MMBtu
ST
PC
DRY WALL
0.362*S
lb
MMBtu
ST
PC
FLUIDIZED
0.362*S
lb
MMBtu
OT
PC
N/A
0.362*S
lb
MMBtu
ST
PC
N/A
0.362*S
lb
MMBtu
CA
PC
OTHER
0.362*S
lb
MMBtu
ST
PC
OTHER
0.362*S
lb
MMBtu
ST
PC
WET WALL
0.362*S
lb
MMBtu
CT
PG
CC
0.0006
lb
MCf
GT
PG
N/A
0.0006
lb
MCf
ST
PG
TANGENTIAL
0.0006
lb
MCf
ST
PG
WALL
0.0006
lb
MCf
ST
PRG
DRY WALL
0.0006
lb
Mcf
ST
PRG
DUCTBURNER
0.0006
lb
Mcf
ST
PRG
N/A
0.0006
lb
Mcf
GT
PRG
N/A
0.0006
lb
Mcf
ST
PRG
N/A
0.0006
lb
Mcf
ST
PRG
OTHER
0.0006
lb
Mcf
ST
PRG
TANGENTIAL
0.0006
lb
Mcf
ST
PRG
WALL
0.003196
lb
MMBtu
Technical Guide for eGRID2020
| pg. 120
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APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
PRG
WALL
0.0006
lb
Mcf
ST
RC
DRY TANGENTIAL
38*S
lb
short tons
ST
RFO
DRY TANGENTIAL
6.594*S
lb
barrels
ST
RFO
DRY WALL
6.594*S
lb
barrels
CT
RFO
N/A
1.01*S
lb
MMBtu
CA
RFO
N/A
1.01*S
lb
MMBtu
CS
RFO
N/A
1.01*S
lb
MMBtu
GT
RFO
N/A
1.01*S
lb
MMBtu
IC
RFO
N/A
0.29
lb
MMBtu
ST
RFO
N/A
6.594*S
lb
barrels
ST
RFO
TANGENTIAL
6.594*S
lb
barrels
ST
RFO
WALL
6.594*S
lb
barrels
ST
RFO
WET WALL
6.594*S
lb
barrels
ST
SGC
N/A
38*S
lb
short tons
CA
SGP
N/A
0.362*S
lb
MMBtu
CS
SGP
N/A
0.362*S
lb
MMBtu
CT
SGP
N/A
0.362*S
lb
MMBtu
SLW
2.8
lb
ton
ST
SUB
CYCLONE
35*S
lb
short tons
ST
SUB
DRY FLUIDIZED
35*S
lb
short tons
ST
SUB
DRY TANGENTIAL
35*S
lb
short tons
ST
SUB
DRY WALL
35*S
lb
short tons
ST
SUB
FLUIDIZED
35*S
lb
short tons
ST
SUB
N/A
35*S
lb
short tons
ST
SUB
STOKER
35*S
lb
short tons
ST
SUB
TANGENTIAL
35*S
lb
short tons
ST
SUB
WALL
35*S
lb
short tons
ST
SUB
WETCYCLONE
35*S
lb
short tons
ST
SUB
WET FLUIDIZED
35*S
lb
short tons
ST
SUB
WET TANGENTIAL
35*S
lb
short tons
ST
SUB
WET WALL
35*S
lb
short tons
ST
TDF
STOKER
38*S
lb
short tons
ST
WC
DRY FLUIDIZED
30*S
lb
short tons
ST
WC
FLUIDIZED
30*S
lb
short tons
ST
WC
N/A
30*S
lb
short tons
ST
WDL
N/A
0.025
lb
MMBtu
ST
WDS
DRY FLUIDIZED
0.025
lb
MMBtu
ST
WDS
DRY STOKER
0.025
lb
MMBtu
Technical Guide for eGRID2020
I P9-121
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APPENDIX C
Prime
Mover
Primary
Fuel
Tvpe
Boiler Firing Type (if
applicable)
Emission
Factor
Emission
Factor
Numerator
Emission
Factor
Denominator
ST
WDS
DRY TANGENTIAL
0.025
lb
MMBtu
ST
WDS
DRY WALL
0.025
lb
MMBtu
ST
WDS
FLUIDIZED
0.025
lb
MMBtu
OT
WDS
N/A
0.025
lb
MMBtu
ST
WDS
N/A
0.025
lb
MMBtu
OT
WDS
OTHER
0.025
lb
MMBtu
ST
WDS
OTHER
0.025
lb
MMBtu
ST
WDS
STOKER
0.025
lb
MMBtu
ST
WDS
TANGENTIAL
0.025
lb
MMBtu
ST
WDS
WALL
0.025
lb
MMBtu
ST
WDS
WETSTOKER
0.025
lb
MMBtu
ST
WDS
WET TANGENTIAL
0.025
lb
MMBtu
ST
WO
DRY WALL
6.174*S
lb
barrels
CA
WO
N/A
1.0-PS
lb
MMBtu
CS
WO
N/A
1.0-PS
lb
MMBtu
CT
WO
N/A
1.01*S
lb
MMBtu
GT
WO
N/A
1.01*S
lb
MMBtu
IC
WO
N/A
0.29
lb
MMBtu
ST
WO
N/A
6.174*S
lb
barrels
Source: AP-42 (EPA, 1995). EIA Electric Power Annual (EIA, 2021f).
N/A = not applicable
S = sulfur content of fuel (%)
Biomass fuels used in the Plant file biomass emission adjustments
For more information regarding the methodology for biomass adjustments to emissions, please see
Section 3.1.2.1.
Table C-4. Fuel types and pollutants included in the Plant file biomass emission
adjustments
Fuel Type
EIA Fuel
Type Code
C02
NOx
ch4
N20
Agricultural
Byproducts
AB
X
Sulphite lyes
(Black
Liquor)
BLQ
X
Digester Gas
DG
X
Landfill Gas
LFG
X
X
X
X
Technical Guide for eGRID2020
I P9-122
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APPENDIX C
Fuel Type
EIA Fuel
Type Code
co2
NOx
ch4
n2o
Municipal
Solid Waste-
biomass
component
MSB
X
Other Biogas
OBG
X
Other Liquid
Biofuels
OBL
X
Other
Primary Solid
Biomass
OBS
X
Sludge
Waste
SLW
X
Wood, Wood
Waste Liquid
WDL
X
Wood and
Wood
Residuals
WDS
X
Plant ORISPL ID Changes
For more information regarding the ORISPL ID changes, please see Section 4.1.
Table C-5. Crosswalk of Plant ID changes
EIA
Plant
ID
EIA Plant Name
E PA/CAM D
Plant ID
EPA/CAMD Plant
Name
Plant ID
used in
eGRID
Plant Name used
in eGRID
59002
Carlsbad Energy
Center
302
Cabrillo Power I
Encina Power
Station
302
Cabrillo Power I
Encina Power
Station
57901
El Segundo Power
330
El Segundo
330
El Segundo
57068
GenConn
Middletown LLC
562
Middletown
562
Middletown
7546
Ponca City
762
Ponca
762
Ponca
56565
J Lamar Stall Unit
1416
Arsenal Hill Power
Plant
1416
Arsenal Hill Power
Plant
7538
Wayne County
2709
H F Lee Steam
Electric Plant
2709
H F Lee Steam
Electric Plant
58215
Lee Combined
Cycle Plant
2709
H F Lee Steam
Electric Plant
2709
H F Lee Steam
Electric Plant
58697
LV Sutton
Combined Cycle
2713
LV Sutton
2713
LV Sutton
Technical Guide for eGRID2020
I P9-123
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APPENDIX C
7512
ArthurVon
Rosenberg
3612
V H Braunig
3612
V H Braunig
7799
West Marinette 34
4076
West Marinette
4076
West Marinette
7294
Central Energy
Plant
7254
Reedy Creek
7254
Reedy Creek
7268
491 E 48th Street
7258
48th Street
Peaking Station
7258
48th Street
Peaking Station
55545
Hidalgo Energy
Center
7762
Calpine Hidalgo
Energy Center
7762
Calpine Hidalgo
Energy Center
7709
Dahlberg
7765
Dahlberg (Jackson
County)
7765
Dahlberg (Jackson
County)
10397
ArcelorMittal
Indiana Harbor
West
10474
ArcelorMittal USA -
Indiana Harbor
East
10474
ArcelorMittal USA-
Indiana Harbor
East
54995
Indiana Harbor E 5
AC Station
10474
ArcelorMittal USA-
Indiana Harbor
East
10474
ArcelorMittal USA-
Indiana Harbor
East
7784
Allegany Cogen
10619
Alleghany Station
No.133
10619
Alleghany Station
No.133
1393
R S Nelson
50030
Nelson Industrial
Steam Company
50030
Nelson Industrial
Steam Company
10789
Sabine River
Works
55120
SRW Cogen
Limited Partnership
55120
SRW Cogen
Limited Partnership
59338
Sundevil Power
Holdings - Gila
River
55306
Gila River Power
Station
55306
Gila River Power
Station
59784
Gila River Power
Block 3
55306
Gila River Power
Station
55306
Gila River Power
Station
57664
Astoria Energy II
55375
Astoria Energy
55375
Astoria Energy
58557
Mesquite
Generating Station
Block 1
55481
Mesquite
Generating Station
55481
Mesquite
Generating Station
55874
Panoche Peaker
55508
CalPeak Power-
Panoche LLC
55508
CalPeak Power-
Panoche LLC
54538
Hartwell Energy
Facility
70454
Hartwell Energy
Facility
70454
Hartwell Energy
Facility
2847
Tait Electric
Generating Station
2847
Frank M Tait
Station
2847
Tait Electric
Generating Station
2847
Tait Electric
Generating Station
55248
Tait Electric
Generating Station
2847
Tait Electric
Generating Station
57788
US GSA Heating
and Transmission
880004
GSA Central
Heating
57788
US GSA Heating
and Transmission
61082
AES Puerto Rico
880102
AES Puerto Rico,
LP
61082
AES Puerto Rico
61149
Palo Seco Plant
880103
Palo Seco Steam
Power Plant
61149
Palo Seco Plant
61147
Costa Sur Plant
880104
Costa Sur Steam
Power Plant
61147
Costa Sur Plant
Technical Guide for eGRI D2020
I pg-124
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APPENDIX C
61146
Aguirre Plant
880105
Aguirre Steam
Power Plant
61146
Aguirre Plant
61148
Central San Juan
Plant
880106
San Juan Steam
Power Plant
61148
Central San Juan
Plant
Geothermal Geotype
Table C-6. Geothermal Emission Factors by Geotype and Pollutant
Geotype Code
Geotype
Description
NOx EF (Ib/MWh)
C02 EF (Ib/MWh)
SO2EF (Ib/MWh)
F
Flash
0
60
0.35
S
Steam
0.00104
88.8
0.000215
B
Binary
0
0
0
B/F
Binary/Flash
0
0
0
English to Metric Conversion Factors
Table C-7. Conversion Factors
English
Value
English
Unit
Metric
Value
Metric
Unit
1.10231
shortton
1
metric ton
2.2046
pound (lb)
1
Kilogram (kg)
0.9478
MMBtu
1
Gigajoule (GJ)
0.2778
GJ
1
Megawatt-hour
(MWh)
Technical Guide for eGRID2020
I P9-125
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APPENDIX D
Appendix D. Information on Prior Editions of eGRID
Previous releases of eGRID include the following:
eGRID 1996 was first released in December 1998.
eGRID 1997, with 1996 and 1997 data, was first released in December 1999.
eGRID 1998, with 1998 data, and with 1996 and 1997 data from eGRID97, was released in March
and September 2001.
eGRID2000, with preliminary 2000 data, was first released as Version 1.0 in December 2002 and
with 1996-2000 data as Version 2.0 in April 2003 and Version 2.01 in May 2003.
eGRID2004 Version 1.0, with the year 2004 plant spreadsheet file, was first released in
December 2006; Version 2.0, which includes one Excel workbook with an updated plant file, as
well as the boiler and generator files for year 2004, was released in early April 2007; and Version
2.1, with the complete set of files - boiler, generator, plant, state, electric generating company
(EGC) location (operator)- and owner-based, parent company location (operator)- and owner-
based, power control area, eGRID subregion, and North American Electric Reliability
Corporation (NERC) region - was released in late April 2007 and updated for typos in May 2007.
eGRID2005 Version 1.0 was released in October 2008 and Version 1.1 was released in January
2009, both with two Excel workbooks with year 2005 data (plant and aggregation) and one Excel
workbook with years 2004 and 2005 data (ImportExport).
eGRID2007 Version 1.0 was released on February 23, 2011 and Version 1.1 was released May
20, 2011, including three Excel workbooks with year 2007 data as well as data for years 2004 and
2005 (the same as those included in eGRID2007). Import-export data for years 2007, 2005, and
2004 are also included.
eGRID2009 Version 1.0 with year 2009 data was release on May 10, 2012. This edition also
includes year 2007, 2005, and 2004 data from the three previously released editions. Import-
export data for years 2009, 2007, 2005, and 2004 are also included.
eGRID2010 Version 1.0 with year 2010 data was released on February 24, 2014. This edition
also includes year 2009, 2007, 2005, and 2004 data from the three previously released editions.
Import-export data for years 2010, 2009,2007, 2005, and 2004 are also included.
eGRID2012 Version 1.0 with year 2012 data was released on October 8, 2015.
eGRID2014 Version 1.0 with year 2014 data was released on January 13, 2017 and Version 2.0
was released on February 27, 2017.
eGRID2016 Version 1.0 with year 2016 data was released on February 15, 2018.
eGRID2018 Version 1.0 with year 2018 data was released on January 28, 2020 and Version 2.0
was released on March 9, 2020.
eGRID2019 Version 1.0 with year 2019 data was released on February 23, 2021.
Technical Guide for eGRID2020
I P9-126
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APPENDIX D
Note that the naming convention for eGRID had been changed since the release of eGRID2012 so
that the year noted in the title reflects the data year rather than the release year.
Technical Guide for eGRI D2020
I Pi- 127
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