PURPOSE

Form EIA-860 collects data on the status of existing electric generating plants and associated equipment (including generators, boilers, cooling systems and air emission control systems) in the United States and Puerto Rico, and those scheduled for initial commercial operation within 5 or 10 years, as applicable. The data from this form appear in EIA publications and public databases. The data collected on this form are used to monitor the current status and trends of the electric power industry and to evaluate the future of the industry.

REQUIRED RESPONDENTS

Existing plants are required to respond to Form EIA-860 if:

• The plant’s total generator nameplate capacity is 1 Megawatt (MW) or greater and

• The plant’s generator(s), or the facility in which the generator(s) resides, are connected to the local or regional electric power grid and have the ability to draw power from or deliver power to the grid

If the existing plant is jointly-owned, only the operator of that plant should respond to Form EIA-860.

Proposed plants are required to respond to Form EIA-860 if:

• The plant’s proposed total generator(s) nameplate capacity will be 1 MW or greater; and

• The plant’s proposed generator(s), or the facility in which the proposed generator(s) resides, will be connected to the local or regional electric power grid and will be able to draw power from or deliver power to the grid; and

• The plant meets one of these two conditions:

• The plant will be primarily fueled by coal or nuclear energy and is expected to begin commercial operation within 10 years; or

• The plant will be primarily fueled by energy sources other than coal or nuclear energy and is expected to begin commercial operation within 5 years.

The five and ten year reporting horizons are calculated from January 1 of the reporting year. For example, reports made in 2014 should reflect plans through December 31, 2018 (five year horizon) and December 31, 2023 (ten year horizon).

If the proposed plant is jointly-owned, only the planned operator of that plant should respond to Form EIA-860.

Generators located in Alaska, Hawaii, and Puerto Rico are required to respond to Form EIA-860 if:

• The generators are connected to a local or regional transmission or distribution system that supplies power to the public.

For all plants:

• The total generator nameplate capacity is the sum of the maximum ratings in MW on the nameplates of all applicable generators at a specific site. For photovoltaic solar, the total generator nameplate capacity is the sum of the AC ratings of the array.

Note that energy storage systems that output electricity or otherwise store energy for the purpose of electricity output are considered to be generators.

RESPONSE DUE DATE

1. Submit the completed Form EIA-860 directly to EIA annually between the first business day of January and the last business day of February. For existing equipment the filing should reflect the status of that equipment as of December 31 of the reporting year. For proposed actions (e.g. planned retirements, planned additions, or planned modifications) the filing should reflect the most up to date information available to the respondent at the time the filing is made. Note: if EIA is late in opening its Internet Data Collection system the filing deadline will be extended day for day (respondents will be notified by email).

2. If subsequent to the submission date for the annual filing a respondent either (a) takes an action, not previously reported to EIA, to add, retire, or uprate/derate generating units or environmental control equipment; or (b) makes a decision, not previously reported to EIA, to add, retire, or uprate/derate generating units or environmental control equipment; then the respondent should notify EIA as soon as practical by an email to EIA-860@eia.gov. EIA staff will then assist the respondent in amending its filing or making a first-time filing.

METHODS OF FILING RESPONSE

If this is your first time submitting Form EIA-860, fill out all applicable portions of this form and submit it to: EIA-860@eia.gov. All subsequent filings can be done electronically using EIA’s secure e-filing system. This system uses security protocols to protect information against unauthorized access during transmission.

If you have any questions on filling out this form or have not registered with the e-file Single Sign-On (SSO) system, send an email requesting assistance to: EIA-860@eia.gov.

If you have registered with SSO, log on at https://signon.eia.doe.gov/ssoserver/login.

Please retain a completed copy of this form for your files.

CONTACTS

If you have a question about the data requested on this form, email EIA-860@eia.gov (preferred) or contact one of the survey managers listed below.

GENERAL INSTRUCTIONS

1. Verify all EIA-provided information. If incorrect, revise the incorrect entry and provide the correct information. Provide any missing information. If filing a paper copy of this form, typed or legible handwritten entries are acceptable.

2. Check all data for consistency with the same or related data that appear in more than one schedule of this form or in other forms or reports submitted to EIA. Use SCHEDULE 7 to explain inconsistencies or anomalies with data or to provide any further details that are pertinent to the data.

3. For planned power plants and/or planned equipment, use planning data to complete the form.

4. Number formats:

   1. Report in whole numbers (i.e., no decimal points), except where explicitly instructed to report otherwise.

   2. Indicate negative amounts by using a minus sign before the number.

   3. Report date information as a two-digit month and four-digit year, e.g., “11 - 1980.”

5. The reporting year is the calendar year that you are filing the survey for. For example, if you are reporting data as of December 31, 2013, then the reporting year is 2013.

6. Furnish the requested information to reflect the status of your current or planned operations as of the end of the reporting year. If your company no longer operated a specific power plant as of December 31, report the name of the operator as of December 31 along with related contact information (including contact person’s name, telephone number, and email address, if known) in SCHEDULE 7. Do not complete the form for that power plant.

7. The blank hardcopy form can be downloaded from www.eia.gov/cneaf/electricity/page/forms.html.

8. For definitions of terms, refer to the U.S. Energy Information Administration glossary at www.eia.gov/glossary/index.html.

ITEM-BY-ITEM INSTRUCTIONS

SCHEDULE 1. IDENTIFICATION

1. Survey Contact: Provide the name, title, address, telephone number, cell phone number, and email address for the person that will be the primary contact for this form.

2. Supervisor of Survey Contact: Provide the name, title, address, telephone number, cell phone number and email address of the primary contact’s supervisor.

3. Entity Name and Address: Provide the name and address of the entity that is reporting for the plants reported on this form.

4. Entity Relationship: Indicate the relationship between the reporting entity and the power plants reported on this form. Select all that apply: owner, operator, asset manager or other. If you select “Other,” provide details in SCHEDULE 7.

5. Entity Type: Select the category that best describes the entity that owns and/or operates the plants reported on this form from the list below:

Cooperative	Municipally-Owned Utility
Federally-Owned Utility	Political Subdivision
Investor-Owned Utility (IOU)	State-Owned Utility
Independent Power Producer (IPP)	Industrial Commercial

SCHEDULE 2. POWER PLANT DATA

Complete one section for each power plant. A plant can consist of a single generator or of multiple generators at a single location. In general a single location will be a contiguous piece of property. Breaks in property lines from publicly owned roads should be ignored when considering whether property is contiguous. Note that in some case a single facility may expand over nearby but discontinuous pieces of property. For example universities in an urban setting may reside on nearby but discontinuous pieces of property. For purposes of reporting the generators owned or operated by this university on nearby but discontinuous pieces of property would be considered to be part of one facility.

For the purpose of wind plants and solar plants, a plant can be defined based on phased expansions or other grouping methodologies used by the reporting entity. Include all plants that are (1) in commercial operation, (2) capable of commercial operation but currently inactive or on standby, or (3) expected to be in commercial operation within 10 years in the case of coal and nuclear units, or within 5 years for all other units.

1. For line 1, What are the plant name and EIA Plant Code for this plant? Enter the name of the power plant. When assigning a name to a plant, use its full name (i.e. do not shorten Alpha Generating Station to Alpha) and include as much detail as possible (e.g. Beta Paper Mill, Gamma Landfill Gas Plant, Delta Dam). The plant name may include additional details like owner name and business structure but “Corporation” should be shorted to “Corp” and “Incorporated” should be shortened to “Inc.” Enter “NA 1,” “NA 2,” etc., for unnamed planned facilities.
   
   The EIA Plant Code is generated and provided by EIA upon the initial submission of the Form EIA-860.

2. For line 2, What is this plant’s physical address? Enter the physical address where the plant is located or will be located. Do not enter the plant’s mailing address. Do not enter the address of the plant’s operator, holding company or other corporate entity. If the plant does not have a single, permanent address, indicate it with a note in SCHEDULE 7.

3. For line 3, What is this plant’s latitude and longitude? Enter the latitude and longitude of the plant in decimal format. The coordinates should relate to a central point within the plant’s property such as a generator. Do not enter the coordinates of the plant’s operator, holding company or other corporate entity.

4. For line 4, Which North American Electric Reliability Corporation region does this plant operate in? Select the North American Electric Reliability Corporation (NERC) region in which the plant operates.

5. For line 5, What is this plant’s balancing authority? Select the plant’s Balancing Authority. A balancing authority manages supply, demand, and interchanges within an electrically defined area. It may or may not be the same as the Owner of Transmission/Distribution Facilities, requested below. If you believe the plant is connected to more than one balancing authority, explain in SCHEDULE 7.

6. For line 6, What is the name of the principle water source used by this plant for cooling or hydroelectric generation? Enter the name of the principal source from which cooling water or water for generating power for hydroelectric plants is obtained. If water is from an underground aquifer, provide name of aquifer, if known. If name of aquifer is not known, enter “Wells.” Enter “Municipality” if the water is from a municipality. Enter “UNK” for planned facilities for which the water source is not known. Enter “NA” for plants that do not use a water source for cooling or hydroelectric generation.

7. The response for line 7, What is this plant’s steam plant type? is entered by EIA staff for all plants. If you are filling out this form on EIA’s Internet Data Collection System and believe that the designation is not accurate, please contact the survey manager.

8. For line 8, Which North American Industry Classification System (NAICS) Code that best describes this plant’s primary purpose? Enter the North American Industry Classification System (NAICS) code found in Table 29 at the end of these instructions that best describes the primary purpose of the plant. Electric utility plants and independent power producers whose primary purpose is generating electricity for sale will generally use code 22. For generators whose primary business is an industrial or commercial process (e.g., paper mills, refineries, chemical plants, etc.) and for which generating electricity is a secondary purpose, use a code other than 22. For plants with multiple purposes, select the NAICS code corresponding to the line of business that generates - or where the chartered intent of the line of business is intended to generate - the highest value for the company.

9. For lines 9a and 9b, Does this plant have Federal Energy Regulatory Commission Qualifying Facility (QF) Cogenerator status? Check “Yes” or “No”; if “Yes” provide all QF docket numbers granted to the facility. Please do not include the prefix (e.g. QF, EWG, etc.) when entering the docket numbers. Only include the numerical portion of the docket number, including dashes.

10. For lines 10a and 10b, Does this plant have Federal Energy Regulatory Commission Qualifying Facility (QF) Small Power Producer status? Check “Yes” or “No”; if “Yes” provide all QF docket numbers granted to the facility. Please do not include the prefix (e.g. QF, EWG, etc.) when entering the docket numbers. Only include the numerical portion of the docket number, including dashes.

11. For lines 11a and 11b, Does this plant have Federal Energy Regulatory Commission Qualifying Facility (QF) Exempt Wholesale Generator status? Check “Yes” or “No”; if “Yes,” provide all QF docket numbers granted to the facility. Please do not include the prefix (e.g. QF, EWG, etc.) when entering the docket numbers. Only include the numerical portion of the docket number, including dashes.

12. For line 12a, Is there an ash impoundment (e.g. pond, reservoir) at the plant? Indicate whether there is an impoundment (e.g. pond, reservoir) at the plant where fly ash, bottom ash or other ash byproducts can be stored.

If you entered “yes" to Question 12a, for Question 12b, Is this ash impoundment lined? Indicate whether the impoundment is lined and, in Question 12c, What was this ash impoundment’s status as of December 31 of the reporting year? select the impoundment’s status from the list of codes in Table 1 below.

Table 1. Ash Impoundment Status Codes and Descriptions

Ash Impoundment Status Code	Ash Impoundment Status Code Description
OP	Operating - in service (commercial operation)
SB	Standby/Backup - available for service but not normally used for this reporting period
OA	Out of service – was not used for some or all of the reporting period but is expected to be returned to service in the next calendar year
OS	Out of service – was not used for some or all of the reporting period and is NOT expected to be returned to service in the next calendar year

13. For line 13, Who is the current owner of the transmission lines and/ or distribution facilities that this plant is interconnected to? Enter the name of the current owner of the transmission or distribution facilities to which the plant is interconnected and which receives or may receive the plant’s output. If the plant is interconnected to multiple owners, enter the name of the principal owner and list the other owners and their roles in SCHEDULE 7.

14. For line 14, What is this plant’s grid voltage at the point(s) of interconnection to transmission or distribution facilities? Enter up to three grid voltages, in kilovolts, at the points of interconnection to the transmission/distribution facilities. If the plant is interconnected to more than three transmission/distribution facilities, enter the three highest grid voltages.

15. For Line 15, Does this facility have energy storage capabilities? Indicate whether this facility has the capability to store excess electrical generation. Please note energy storage is not limited to only batteries. Examples of energy storage capabilities that should be reported include batteries, pumped storage, thermal storage supporting electrical generation, flywheels, and compressed air. Note emergency battery rooms used only for the safe shutdown of generator units do not need to be reported. Also note that if a facility has an integrated energy storage system located offsite then the energy storage system does not need to be reported at this facility; however the remote energy storage system may need to be reported as a separate facility if it has generating capacity >1 MW.

16. Plants that receive natural gas should answer lines 16a-16d.

For line 16a, If this facility has an existing natural gas-fired generator for which it has pipeline connection to a Local Distribution Company (LDC), provide the name of the LDC, Identify the name(s) of the a natural gas Local Distribution Company to which the facility is directly connected.

For line 16b, If this facility has an existing natural gas-fired generator and has a pipeline connection other than to a Local Distribution Company, provide the name(s) of the owner or operator of each natural gas pipeline that connects directly to this facility or that connects to a lateral pipeline owned by this facility. Identify the name(s) of the natural gas pipeline(s) that connect to the facility or that connect to a lateral pipeline owned by the facility.

For line 16c, Does this facility have on-site natural gas storage? Specify whether the facility has on-site natural gas storage.

For line 16d, If this facility has on-site storage of natural gas, does the facility have the capability to store the natural gas in the form of liquefied natural gas? Specify whether the facility has the capability to store natural gas in the form of liquefied natural gas.

SCHEDULE 3. GENERATOR INFORMATION

Complete SCHEDULE 3 for each generator at this plant that is:

• In commercial operation;

• Capable of commercial operation but currently inactive or on standby;

• Retired;

• Expected to be in commercial operation within 10 years in the case of coal and nuclear generators; or

• Expected to be in commercial operation within 5 years for all generators other than coal and nuclear generators.

1. Do not report auxiliary generators that are typically used solely for blackstart or maintenance purposes.

2. For generators associated with wind and solar plants, a generator can be any grouping of photovoltaic panels or wind turbines with similar characteristics (e.g. manufacturer, technical parameters, location, commercial operating date, etc.).

3. Treat energy storage facilities as generators and provide all necessary data requested below.

4. Include generators with maximum capability of less than 1 MW if located at a plant with a total nameplate capacity of 1 MW or greater.

5. To report a new generator, use a separate and blank section of SCHEDULE 3.

6. To report a new generator that has replaced one that is no longer in service, update the status of the generator that has been replaced along with other related information (e.g., retirement date), then use a separate and blank section of SCHEDULE 3 to report all of the applicable data about the new generator.

7. Each generator must be uniquely identified within a plant. The EIA cannot use the same generator ID for the new generator that was used for the generator that was replaced.

SCHEDULE 3. PART A. GENERATOR INFORMATION – GENERATORS

1. For line 1, What is the generator ID for this generator? Enter the unique generator identification commonly used by plant management. Generator identification should be the same identification as reported on other EIA forms to be uniquely defined within a plant. For new wind and solar projects a unique generator ID should be used for each installation phase of the project. For new solar projects also select unique generator IDs for fixed tilt arrays having different tilt or azimuth angles. This identification code is restricted to five characters and cannot be changed once provided to EIA.

2. For line 2, What is this generator’s prime mover? Enter one of the prime mover codes in Table 2. For combined cycle units, a prime mover code must be entered for each generator.

Table 2. Prime Mover Codes and Descriptions

Prime Mover Code	Prime Mover Description
BA	Energy Storage, Battery
CE	Energy Storage, Compressed Air
CP	Energy Storage, Concentrated Solar Power
FW	Energy Storage, Flywheel
PS	Energy Storage, Reversible Hydraulic Turbine (Pumped Storage)
ES	Energy Storage, Other (specify in SCHEDULE 7)
ST	Steam Turbine, including nuclear, geothermal and solar steam (does not include combined cycle)
GT	Combustion (Gas) Turbine (does not include the combustion turbine part of a combined cycle; see code CT, below)
IC	Internal Combustion Engine (diesel, piston, reciprocating)
CA	Combined Cycle Steam Part
CT	Combined Cycle Combustion Turbine Part
CS	Combined Cycle Single Shaft (combustion turbine and steam turbine share a single generator)
CC	Combined Cycle Total Unit (use only for plants/generators that are in planning stage, for which specific generator details cannot be provided)
HA	Hydrokinetic, Axial Flow Turbine
HB	Hydrokinetic, Wave Buoy
HK	Hydrokinetic, Other (specify in SCHEDULE 7)
HY	Hydroelectric Turbine (includes turbines associated with delivery of water by pipeline)
BT	Turbines Used in a Binary Cycle (including those used for geothermal applications)
PV	Photovoltaic
WT	Wind Turbine, Onshore
WS	Wind Turbine, Offshore
FC	Fuel Cell
OT	Other (specify in SCHEDULE 7)

Combined heat and power systems often generate steam with multiple sources and generate electric power with multiple prime movers. For reporting purposes, a simple cycle prime mover should be distinguished from a combined cycle prime mover by determining whether the power generation part of the steam system can operate independently of the rest of the steam system. If these system components cannot be operated independently, then the prime movers should be reported as combined cycle types.

3. For line 3, What is this generator’s unit or multi-generator code? If this generator operates as a single unit with another generator (including as a combined cycle unit), enter a unique 4-character code for the unit. All generators that operate as a unit must have the same unit code. Leave blank if this generator does not operate as a single unit with another generator.

4. For line 4, What is this generator’s ownership code? Identify the ownership for each generator using the following codes:

Table 3: Generator Ownership Codes and Descriptions

Ownership Code	Ownership Code Description
S	Single ownership by respondent
J	Jointly owned with another entity
W	Wholly owned by an entity other than respondent

5. For line 5, Does this generator have duct burners for the supplementary firing of the turbine exhaust gas? Check “Yes” if 1) the generator has a combined cycle prime mover code of “Combined Cycle Steam Part (CA)” “Combined Cycle Single Shaft (CS),” or “Combined Cycle Total Unit (CC,)” and 2) if the unit has duct-burners for supplementary firing of the turbine exhaust gas. Otherwise, check “No.”

6. For line 6, Can this generator operate while bypassing the heat recovery steam generator? Check “Yes” if 1) the generator has a combined cycle prime mover code of “Combined Cycle Combustion Turbine Part (CT)” or “Combined Cycle Total Unit (CC)” and 2) the combustion turbine can operate while bypassing the heat recovery steam generator. Otherwise, check “No.”

7. For line 7a, For this generator what is the RTO/ISO LMP price node designation? If this generator operates in an electric system operated by a Regional Transmission Organization (RTO) or Independent System Operator (ISO) and the RTO/ISO calculates a nodal Locational Marginal Price (LMP) at the generator location, then provide the nodal designation used to identify the price node in RTO/ISO LMP price reports.

For line 7b, For this generator what is the RTO/ISO location designation for reporting wholesale sales data to FERC? If this generator operates in an electric system operated by a Regional Transmission Organization (RTO) or Independent System Operator (ISO) and the generator’s wholesale sales transaction data is reported to FERC for the Electric Quarterly Report, then provide the designation used to report the specific location of the wholesale sales transactions to FERC. In many cases the RTO/ISO location designation may be the same as the RTO/ISO LMP price node designation submitted in line 7a. In these cases enter the same response in both line 7a and line 7b.

SCHEDULE 3, PART B. GENERATOR INFORMATION – EXISTING GENERATORS

Complete one SCHEDULE 3, Part B for each generator at this plant that is in commercial operation.

1. For line 1a, What is the nameplate capacity for this generator? Report the highest value on the generator nameplate in MW rounded to the nearest tenth, as measured in alternating current (AC). If the nameplate capacity is expressed in kilovolt amperes (kVA), first convert the nameplate capacity to kilowatts by multiplying the corresponding power factor by the kVA and then convert to megawatts by dividing by 1,000. Round this value to the nearest tenth. If generator nameplate capacity is less than net summer capacity, provide the reason(s) in SCHEDULE 7. In order to correct erroneous nameplate reported in prior year(s) send an image of the nameplate to EIA-860@eia.gov.

For line 1b, What is the nameplate power factor for this generator? Enter the power factor stamped on the generator nameplate. This should be the same power factor used to convert the generator’s kilovolt-ampere rating (kVA) to megawatts (MW) as directed for line 1a above. Solar photovoltaic systems, wind turbines, batteries, fuel cells, and flywheels may skip this question.

2. For line 2a, What is this generator’s net capacity? Enter the generator's net summer and net winter capacities for the primary energy source. Report in MW rounded to the nearest tenth, as measured in alternating current (AC). For generators that are out of service for an extended period or on standby, report the estimated capacities based on historical performance. For generators that are tested as a unit, report a single aggregate net summer capacity and a single aggregate net winter capacity. For hydroelectric generators, report the instantaneous capacity at maximum water flow. For solar photovoltaic generators report the peak net capacity during the day for the generator assuming clear sky conditions on June 21 for summer capacity and on December 21 for winter capacity; assume average seasonal temperatures and average wind speeds for June 21 and December 21, respectively. If net capacity is only available as direct current (DC), estimate the effective AC output and explain in SCHEDULE 7.

Answer the question on lines 2b only if the generator is powered by a photovoltaic solar technology

For line 2b, What is the net capacity of this photovoltaic generator in direct current (DC) under standard test conditions (STC) of 1000 W/m² solar irradiance and 25 degrees Celsius PV module temperature? Enter the sum of the DC capacity ratings of the photovoltaic modules associated with this generator.

3. For line 3, What minimum load can this generator operate at continuously? Enter the minimum load (MW) at which the unit can operate continuously. Solar-powered generators are not required to answer this question. For generators operating as a single unit that entered a Unit Code (Multi-Generator Code) on SCHEDULE 3, Part A, Line 3, provide the load when all generators are operating at their minimum load.

4. For line 4a, Was an uprate or derate project completed on this generator during the reporting year? Check “Yes” if an uprate or derate project was implemented during the reporting year. Check “No” if it was not. If both an uprate and derate were implemented during the reporting year, check “Yes” and explain in SCHEDULE 7.

For line 4b, When was this uprate or derate project completed? Enter the date when the uprate or derate project identified in line 4a was completed.

5. For line 5a, What was the status of this generator as of December 31 of the reporting year? Enter one of the following status codes:

Table 4. Generator Status Codes and Descriptions

Code	Code Description
OP	Operating - in service (commercial operation) and producing some electricity. Includes peaking units that are run on an as needed (intermittent or seasonal) basis.
SB	Standby/Backup - available for service but not normally used (has little or no generation during the year) for this reporting period.
OS	Out of service – was not used for some or all of the reporting period and is NOT expected to be returned to service in the next calendar year.
OA	Out of service – was not used for some or all of the reporting period but is expected to be returned to service in the next calendar year.
RE	Retired - no longer in service and not expected to be returned to service.

For line 5b, If Is this generator equipped to be synchronized to the grid? If the status code entered on line 5a is standby (SB), check “Yes” if the generator is currently equipped to be synchronized to the grid when operating. Check “No” if it is not.

6. For line 6, When did this generator begin commercial operation? Enter the month and year of initial commercial operation in the format MM-YYYY.

7. For line 7, When was this generator retired? Enter the month and year that the generator was retired in the format (MM-YYYY).

8. For line 8, If this generator will be retired in the next ten years, what is its estimated retirement date? If you expect this generator to be retired in the next 10 years, enter your best estimate for this planned retirement date in the format MM-YYYY.

9. For line 9 Is this generator associated with a combined heat and power system? Check “Yes” if this generator is associated with a combined heat and power system. Check “No” if it is not.

10. For line 10, Is this generator part of a topping or bottoming cycle? If you checked “Yes” on line 9, check “Topping” if this generator is part of a topping cycle. In a topping cycle system, electricity is produced first and any waste heat from that production is used in a manufacturing or commercial application. Check “Bottoming” if this generator is part of a bottoming cycle. In a bottoming cycle system, thermal output is used in a process other than electricity production and any waste heat is then used to produce electricity.

11. For line 11, What is this generator’s predominant energy source? Enter the energy source code for the fuel used in the largest quantity (Btus) during the reporting year to power the generator. For generators that are out of service for an extended period of time or on standby, report the energy sources based on the generator’s latest operating experience. For generators driven by turbines using steam that is produced from waste heat or reject heat, report the original energy source used to produce the waste heat (reject heat). Do not include fuels expected to be used only for start-up or flame stabilization. Select the appropriate energy source code from Table 28 in these instructions.

12. For line 12, What are the energy sources used by this generator’s combustion units for start-up and flame stabilization? If the prime mover is steam turbine (ST), report the energy sources used by the combustion unit(s) associated with this generator for start-up and flame stabilization; otherwise leave blank. Select the appropriate energy source code from Table 28 in these instructions.

13. For line 13, What is this generator’s second most predominant energy source? Enter the energy source code for the energy source used in the second largest quantity (Btus) during the reporting year to power the generator. DO NOT include a fuel used only for start-up or flame stabilization. For generators driven by turbines using steam that is produced from waste heat or reject heat, report the original energy source used to produce the waste heat or reject heat. Select the appropriate energy source code from Table 28 in these instructions.

14. For line 14, What other energy sources are used by the generator? Enter the codes for other energy sources that can be used by the generator to generate electricity: first, list the energy sources actually used in order of predominance (based on quantity of Btus), then list ones that the generator was capable of using but was not used to generate electricity during the last 12 months. For generators that are out of service for an extended period of time or on standby, report the energy sources based on the generator’s latest operating experience. For generators driven by turbines using steam that is produced from waste heat or reject heat, report the original energy source used to produce the waste heat or reject heat. Select the appropriate energy source codes from Table 28 in these instructions.

15. For line 15, Is this generator part of a solid fuel gasification system? Check “Yes” if this generator is part of a solid fuel gasification system. Check “No” if it is not.

16. For line 16, What is the tested heat rate for this generator? Enter the tested heat rate under full load conditions for all combustible-fueled generators and nuclear-fueled generators. The tested heat rate is the amount of fuel, measured in British thermal units (Btus) necessary to generate one net kilowatt-hour of electric energy. Do not report the actual heat rate, which is the quotient of the total Btu(s), consumed and total net generation. If generators are tested as a unit (not tested individually), report the same test result for each generator. For generators that are out of service for an extended period or on standby, report the heat rate based on the unit’s latest test. If the generator is associated with a combined heat and power (CHP) system, and no tested heat rate data are available, report either the manufacturer’s specification for heat rate or an estimated heat rate. DO NOT report a heat rate that includes the fuel used for the production of useful thermal output. For Internal Combustion units, a manufacturer’s specification or estimated heat rate should be reported, if no tested heat rate is available. If the reported value is not a tested heat rate, specify in SCHEDULE 7.
    
    This information will be protected and not disclosed to the extent that it satisfies the criteria for exemption under the Freedom of Information Act (FOIA), 5 U.S.C. §552, the Department of Energy (DOE) regulations, 10 C.F.R. §1004.11, implementing the FOIA, and the Trade Secrets Act, 18 U.S.C. §1905

17. For line 17, What fuel was used to determine this generator’s tested heat rate? Enter the fuel code for the fuel used to determine the heat rate reported in line 16. Enter “M” if multiple fuels were used to calculate the heat rate reported in line 16. For generators driven by turbines using steam that is produced from waste heat or reject heat, report the original energy source used to produce the waste or reject heat). Select appropriate energy source codes from Table 28 in these instructions.

18. For line 18, Is the generator associated with a carbon dioxide capture process? Check “Yes” if this generator is associated with carbon dioxide capture. Check “No” if it is not.

19. For line 19, How many wind turbines or hydrokinetic buoys are there at this generator? Wind generators should enter the number of wind turbines and hydrokinetic generators should enter the number of hydrokinetic buoys. All other generators should enter 0.

20. Line 20 is reserved for future use.

21. For line 21, What is the minimum amount of time required to bring this generator from cold shut down to full load? Select the minimum amount of time required to bring the unit to full load from cold shutdown. Wind and solar-powered generators should not answer this question.

22. Line 22 is reserved for future use.

Answer questions on lines 23 and 24 only if generator is fueled by coal or petroleum coke

23. For line 23, What combustion technology applies to this generator? Select the appropriate combustion technology that applies to the generator.

24. For line 24, What steam conditions apply to this generator? Select the appropriate steam conditions that apply to the unit.

Answer questions on lines 25 through 28 only if generator is wind-powered

25. For line 25, What is the predominant manufacturer of the turbines at this generator? Enter the predominant manufacturer of the turbines at the generator. If the predominant manufacturer is not known, enter “UNKNOWN.”

26. For line 26, What is the predominant turbine model number at this generator? Enter the predominant model number. If the predominant model number is not known, enter “UNKNOWN.”

27. On line 27a, What is the average annual wind speed at this generator site? Enter the average annual wind speed in miles per hour for the turbines included in the generator. If more than one value exists, select the one that best represents the turbines.

On line 27b, What is the International Electrotechnical Commission wind quality class for turbines included in this generator? Select the wind quality class for the turbines included in the generator, as defined by the International Electrotechnical Commission (IEC 61400-1 ed. 2) and Table 5 below. If more than one wind class exists, select the one that best represents the turbines.

Table 5. Wind Quality Class and Descriptions

Class	Annual Average Wind Speed	Extreme 50-Year Gust	Turbulence Intensity
Class 1 – High Wind	10 m/s (22.4 mph)	70 m/s (156 mph)	A: 0.210 B: 0.180
Class 2 – Medium Wind	8.5 m/s (19.0 mph)	59.5 m/s (133 mph)	A: 0.226 B: 0.191
Class 3 – Low Wind	7.5 m/s (16.8 mph)	52.5 m/s (117 mph)	A: 0.240 B: 0.200
Class 4 – Very Low Wind	6 m/s (13.4 mph)	42 m/s (94 mph)	A: 0.270 B: 0.220

28. On line 28, What is the hub height for the turbines in this generator? Enter the hub height in feet for the turbines at the generator. If this generator consists of turbines with multiple hub heights, select the one that best represents all of the turbines.

Answer questions on lines 29 through 33 only if generator is powered by photovoltaic or concentrated solar thermal technology

29. On line 29, What are the solar tracking, concentrating and collector technologies used at this generator? Select all applicable solar tracking, concentrating or collector technologies used at the unit. If you select “Other,” provide details in SCHEDULE 7.

30. On line 30a, For generators having fixed tilt technologies or single-axis technologies with a fixed azimuth angle, what is the azimuth angle of the unit? Provide the azimuth angle of the unit (Specify an angle ranging from 0 degrees to 359 degrees: North = 0 degrees, East = 90 degrees, South = 180 degrees, and West = 270). If the units included in the “generator” have various azimuth angles provide a representative angle. Skip this question for units configured with an East-West Fixed Tilt (alternating rows) technology.

On line 30b, For generators having fixed tilt technologies or single-axis technologies with a fixed tilt angle, what is the tilt angle of the unit? Provide the tilt angle of the unit (Specify an angle ranging from 0 degrees to 90 degrees: horizontal surface = 0 degrees, vertical surface = 90 degrees). If the units included in the “generator” have various tilt angles provide a representative angle.

31. On line 31, What materials are the photovoltaic panels included in this generator made of? Select the material of the Photovoltaic panels. If the panels included in the “generator” are made of different materials, select all materials used. If you select “Other,” provide details on the material in SCHEDULE 7.

32. On line 32a, Is the output from this generator part of a net metering agreement? Indicate whether the output from this generator is part of an arrangement that allows output from renewable resources to be credited against a customer’s electric bill. For purposes of this question do not include virtual net metering agreements (see the instructions to line 33a for the definition of virtual net metering).

On line 32b, If the output from this generator is part of a net metering agreement how much DC capacity (in MW) is part of the net metering agreement (exclude virtual net metering)? Specify the amount of DC capacity from the generator that is part of a net metering agreement.  For purposes of this question do not include capacity that is part of a virtual net metering agreement.

33. On line 33a, Is the output from this generator part of a known virtual net metering agreement? Indicate whether the output from this generator is part of a known billing arrangement that allows multiple energy customers to receive net metering credit from a shared onsite or remote renewable energy system much as if it was located behind the customer’s own meter.

On line 33b, If the output from this generator is part of a known virtual net metering agreement how much DC capacity (in MW) is part of the known virtual net metering? Specify the amount of DC capacity from the generator that is part of a known virtual net metering agreement.

Answer questions on lines 34 through 40 only if generator is an energy storage device other than pumped storage or thermal storage (examples include battery, flywheel, and compressed air).

34. On line 34, What is the nameplate energy capacity (MWh)? Specify the nameplate energy capacity

35. On line 35, What is the maximum charge rate (MW)? Specify the maximum charge rate

36. On line 36, What is the maximum discharge rate (MW)? Specify the maximum discharge rate

37. On line 37, For battery applications, what electro-chemical storage technology(s) are used? Enter the electro-chemical storage technology(s) used for batter applications. Select appropriate technology codes from Table 5b in these instructions.

Table 5b. Electro-chemical Storage Technology Codes and Descriptions

Electro-chemical Storage Technology Code	Electro-chemical Storage Technology Description
ECC	Electro-chemical capacitor
FLB	Flow battery
PBB	Lead-acid battery
LIB	Lithium-ion battery
MAB	Metal air battery
NIB	Nickel based battery
NAB	Sodium based battery
OTH	Other (specify in SCHEDULE 7)

38. On line 38, What is the nameplate reactive power rating for the energy storage device? Specify the nameplate reactive power rating for the energy storage device.

39. On line 39, Which enclosure type best describes where the generator is located? Select the enclosure type that best describes where the generator is located. Select appropriate enclosure type codes from Table 5c in these instructions

Table 5c. Storage Technology Enclosure Type Codes and Descriptions

Enclosure Type Code	Enclosure Type Code Description
BL	Building
CS	Containerized - Stationary
CT	Containerized - Transportable
OT	Other (specify in SCHEDULE 7)

40. On line 40, For which applications did this energy storage device serve during the reporting year (select all that apply)? Select all applications for which this energy storage device served during the reporting year.

Lines 41-44 apply to proposed changes to existing generators

41. If a capacity uprate is planned within the next 10 years, answer Questions 41a – 41c.

For line 41a, What is the expected incremental increase in the net summer capacity? If an uprate is planned within the next 10 years enter the incremental amount by which the net summer capacity is expected to increase. If no uprate is planned in the next ten years, leave this blank.

For line 41b, What is the expected incremental increase in the net winter capacity? If an uprate is planned within the next 10 years, enter the incremental amount by which the net winter capacity is expected to increase. If no uprate is planned in the next ten years, leave this blank.

For line 41c, What is the planned effective date for this capacity uprate? If an uprate is planned within the next 10 years, enter the date on which the generator is scheduled to re-enter commercial operation after the planned uprate. Enter the date in the format MM-YYYY. If no uprate is planned in the next 10 years, leave this blank.

42. If a capacity derate is planned within the next 10 years, answer Questions 42a – 42c.

For line 42a, What is the expected incremental decrease in the net summer capacity? If a derate is planned within the next 10 years, enter the incremental amount by which the net summer capacity is expected to decrease. If no derate is planned in the next 10 years, leave this blank.

For line 42b, What is the expected incremental decrease in the net winter capacity? If a derate is planned within the next 10 years, enter the incremental amount by which the net winter capacity is expected to decrease. If no derate is planned in the next ten years, leave this blank.

For line 42c, What is the planned effective date for this capacity derate? If a derate is planned in the next 10 years, enter the date on which the generator is scheduled to re-enter commercial operation after the planned derate. Enter the date in the format MM-YYYY. If no derate is planned in the next 10 years, leave this blank.

43. For line 43a, What is the expected new prime mover for this generator? If a repowering is planned within the next 10 years, enter the new prime mover for this generator. Select the prime mover code from those listed in the instructions for SCHEDULE 3 Part A, Table 2. If no repowering is planned within the next 10 years, leave this blank.

For line 43b, What is the expected new energy source for this generator? If a repowering is planned within the next 10 years, enter the new energy source for this generator. Select the energy source code from Table 28 in these instructions. If no repowering is planned in the next ten years, leave this blank.

For line 43c, What is the expected new nameplate capacity for this generator? If a repowering is planned for within the next 10 years, enter the new nameplate capacity for this generator.

For line 43d, What is the planned effective date for this repowering? Enter the date on which this generator is scheduled to re-enter operation after the repowering. Enter the date in the format MM-YYYY. If no repowering is planned, leave this blank.

44. On line 44a, Are any other modifications planned within the next 10 years? Check “Yes” if any other significant modifications are planned for this generator in the next 10 years. Explain these modifications on SCHEDULE 7 of this form. Check “No” If no other significant modifications are planned within the next 10 years.

On line 44b, What is the planned date of these other modifications? If you checked “Yes” on line 44a, enter the date on which this generator will reenter service after the modification. Enter the date in the format MM-YYYY. If you selected “No,” leave this blank.

45. On line 45a, Can this generator burns multiple fuels? Indicate if the combustion system that powers each generator has both:

• The regulatory permits necessary to either co-fire fuels or fuel switch, and

• The equipment, including fuel storage facilities in working order, necessary to either co-fire fuels or fuel switch.

If the answer to this question is “No,” go to SCHEDULE 3, PART C. GENERATOR INFORMATION - PROPOSED GENERATORS.

For line 45b, Can this generator co-fire fuels? Indicate yes if the combustion system that powers each generator has both:

• The regulatory permits necessary to co-fire fuels, and

• The equipment, including fuel storage facilities in working order, necessary to either co-fire fuels or fuel switch.

Note: Co-firing means the simultaneous use of two or more fuels by a single combustion system to meet load. Co-firing excludes the limited use of a secondary fuel for start-up or flame stabilization.

Line 45c applies only if the generator can co-fire fuels

For line 45c, What are the fuel options for co-firing? Indicate up to six fuels that can be co-fired. Select appropriate energy source codes from Table 28 in these instructions.

Note: fuel options listed for co-firing must also be included under either “Predominant Energy Source,” Second Most Predominant Energy Source,” or “Other Energy Sources.”

46. For line 46a, Can this generator switch between oil and natural gas? Check “Yes” if:

• the primary energy source of the unit is oil or natural gas;

• the combustion system that powers the generator has, in working order, the equipment (including fuel oil storage tanks) necessary to switch between natural gas and oil; and

• this combustion system has the regulatory permits necessary to switch between natural gas and oil.

Note: Fuel switching means the ability of a combustion system running on one fuel to replace that fuel in its entirety with a substitute fuel. Fuel switching excludes the limited use of a secondary fuel for start-up or flame stabilization.

Answer questions on lines 46b through 50 only if generator can fuel switch between oil and natural gas

For line 46b, Can this generator switch between oil and natural gas while operating? Check “Yes,” if 1) you checked “Yes” for line 38a, and 2) if the combustion system that powers this generator is able to switch between natural gas and oil while operating.

47. For line 47a, What is the maximum net summer output achievable when running on natural gas? Enter the maximum net summer output in MW that the unit can achieve when running on natural gas, taking into account all applicable legal, regulatory, and technical limits.

For line 47b, What is the maximum net winter output achievable when running on natural gas? Enter the maximum net winter output in MW that the unit can achieve when running on natural gas, taking into account all applicable legal, regulatory, and technical limits.

48. For line 48a, What is the maximum net summer output achievable when running on oil? Enter the maximum net summer output in MW that the unit can achieve when running on fuel oil, taking into account all applicable legal, regulatory, and technical limits.

For line 48b, What is the maximum net winter output achievable when running on oil? Enter the maximum net winter output in MW that the unit can achieve when running on fuel oil, taking into account all applicable legal, regulatory, and technical limits.

49. For lines 49a, How much time is required to switch the generator from using 100 percent natural gas to 100 percent oil? Enter the amount of time that it takes to switch the generator from using 100 percent natural gas to 100 percent oil.

For line 49b, How much time is required to switch this generator from using 100 percent oil to using 100 percent natural gas? Enter the amount of time that it takes to switch the generator from using 100 percent oil to 100 percent natural gas.

50. For line 50a, Are there factors that limit this generator’s ability to switch between natural gas and oil? These factors may include limits on maximum output, limits on annual operating hours, or other limitations.

For line 50b, Which factors limit this generator’s ability to switch between natural gas and oil? If you selected “Yes” on line 50a, select all of the factors that limit the ability to switch fuels. If you select “Other” provide explanation in SCHEDULE 7.

SCHEDULE 3, PART C. GENERATOR INFORMATION – PROPOSED GENERATORS

Complete this Schedule for all generators at this plant that are:

• Expected to be in commercial operation within 10 years in the case of coal and nuclear generators; or

• Expected to be in commercial operation within 5 years for all generators other than coal and nuclear generators.

1. For line 1a, What is the expected nameplate capacity for this generator? Enter the expected nameplate capacity in MW rounded to the nearest tenth, as measured in alternating current (AC). If the expected nameplate capacity is expressed in kilovolt amperes (kVA), first convert the expected nameplate capacity to kilowatts by multiplying the corresponding power factor by the kVA and then convert to megawatts by dividing by 1,000. Round this value to the nearest tenth.

For line 1b, What is the expected nameplate power factor for this generator? Enter the expected power factor. This should be the same power factor used to convert the generator’s kilovolt-ampere rating (kVA) to megawatts (MW) as directed for line 1a above.

2. For line 2, What is the expected net capacity for this generator? Enter the generator’s net summer and net winter capacities for the primary energy source that are expected when the generator goes into commercial operation. Report these values in MW rounded to the nearest tenth, as measured in alternating current (AC).

3. For line 3, What was the status of this proposed generator as of December 31 of the reporting year? Enter one of the following status codes:

Table 6. Proposed Generator Status Codes and Descriptions

Proposed Generator Status Code	Proposed Generator Status Code Descriptions
CN	Planned new generator has been canceled
IP	Planned new generator indefinitely postponed, or no longer in resource plan
TS	Construction complete, but not yet in commercial operation (including low power testing of nuclear units)
P	Planned for installation but regulatory approvals not initiated; Not under construction
L	Regulatory approvals pending. Not under construction but site preparation could be underway
T	Regulatory approvals received. Not under construction but site preparation could be underway
U	Under construction, less than or equal to 50 percent complete (based on construction time to date of operation)
V	Under construction, more than 50 percent complete (based on construction time to date of operation)
OT	Other (specify in SCHEDULE 7)

4. For line 4, What is the planned original effective date for this generator? Enter the date on which the generator is scheduled to start commercial operation. Enter the date in the format MM-YYYY. This date will not change after it has been reported the first time.

5. For line 5, What is the planned current effective date for this generator? If a Planned Original Effective Date was submitted an earlier filing and is no longer accurate, enter the updated date on which the generator is scheduled to start commercial operation. Enter the date in the format MM-YYYY. Leave blank if this is your first time filling out this form.

6. For line 6, Will this generator be associated with a combined heat and power system? Check “Yes” if this generator will be associated with combined heat and power system. If it will not, check “No.”

7. For line 7, Is this generator part of a site that was previously reported as indefinitely postponed or cancelled? Check “Yes” if this generator is part of a site that was previously reported by either your company or a previous owner as an indefinitely postponed or cancelled plant. Check “No” if it is not. Check “Unknown” if this history is not known.

8. For line 8, What is the predominant expected energy source for this generator? Enter the energy source code for the energy source expected to be used in the largest quantity, as measured in Btus, when the generator starts commercial operation. Select appropriate energy source codes from Table 28 in these instructions.

9. For line 9, What is the second most predominant expected energy source for this generator? Enter the energy source code for the energy sources expected to be used in the second largest quantity, as measured in Btus, when the generator starts commercial operation. Do not include fuels expected to be used only for start-up or flame stabilization. Select the appropriate energy source code from Table 28 in these instructions.

10. For line 10, What other energy sources do you expect to use for this generator? Enter the codes for other energy sources that will be used at the plant to power the generator. Enter up to four codes. Enter these codes in order of their expected predominance as measured in Btus. Select appropriate energy source codes from Table 28 in these instructions.

11. For line 11, How many turbines, or buoys is this generator expected to have? Wind generators should enter the number of turbines, and hydroelectric generators should enter the number of buoys.

12. For line 12, What combustion technology will apply to this generator? If the generator will be fired by coal or petroleum coke, select the appropriate combustion technology. If you select “Other” provide explanation in SCHEDULE 7.

13. For line 13 What steam conditions will apply to this generator? If the generator will be fired by coal or petroleum coke, select the appropriate steam conditions.

14. For line 14, Will this generator be part of a solid fuel gasification system? Check “Yes” if this generator will be part of a solid fuel gasification system. Check “No” if it will not be.

15. For line 15, Will this generator be associated with a carbon dioxide capture process? Check “Yes” if this generator will be associated with a carbon capture process. Check “No” if it will not be associated with carbon capture.

Line 16 applies only if the generator will be able to burn multiple fuels.

Line 17 applies only if the generator will be able to fuel switch.

Lines 18a and 18b apply only if the generator will be able to co-fire fuels.

16. Note: Co-firing means the simultaneous use of two or more fuels by a single combustion system to meet load. Fuel switching means the ability of a combustion system running on one fuel to replace that fuel in its entirety with a substitute fuel. Co-firing and fuel switching exclude the limited use of a secondary fuel for start-up or flame stabilizationFor line 16, Will this generator be able to burn multiple fuels? Indicate if the combustion system that will power the generator will have 1) the regulatory permits necessary to either co-fire fuels or fuel switch, and 2) the equipment (including fuel storage facilities) necessary to either co-fire or fuel switch are in working order.

If the answer is “No” or “Undetermined”, go to SCHEDULE 4. OWNERSHIP OF GENERATORS OWNED JOINTLY OR BY OTHERS

17. For line 17, Will the combustion system that powers this generator be able to switch between natural gas and oil? Check “Yes” if 1) the primary energy source of the generator will be natural gas or oil and 2) the combustion system that will power the generator will have the ability and equipment necessary (including fuel oil storage tanks) to switch between natural gas and oil. Check “No” if it will not. Check “Undetermined” if a determination on switching between natural gas and oil has not yet been made.

18. For line 18a, Will the combustion system that powers this generator be able to co-fire fuels? Indicate whether or not the combustion system that will power the generator will have the necessary equipment and regulatory permits to co-fire fuels.

For line 18b, What are the fuel options for co-firing? Indicate up to six fuels that the generator will be designed to co-fire. Select the energy source codes from Table 28 in these instructions. Note: fuel options listed for co-firing must also be included under “Predominant Energy Source,” Second Most Predominant Energy Source,” and/or “Other Energy Sources.”

SCHEDULE 4. OWNERSHIP OF GENERATORS OWNED JOINTLY OR BY OTHERS

1. Complete SCHEDULE 4 for each operable or planned generator that is or will be either jointly owned with another entity or wholly owned by an entity other than the reporting entity as entered on SCHEDULE 1, Line 3.

2. For each generator that is either jointly owned with another entity or wholly owned by another specify the Plant Name, EIA Plant Code, and Generator Identification Code, as listed on SCHEDULE 3, PART A.

3. For each owner of either a jointly owned generator or wholly owned by an entity other than the reporting entity generator, enter the name, address and percentage owned. The total percentage of reported ownership must equal 100 percent.

4. If known, enter the EIA Owner Code for the owner, otherwise leave blank. The EIA Owner Code is the same as the EIA Utility Identification Code and EIA Entity Identification Code.

5. Enter the Percent Owned to two decimal places, i.e., 12.5 percent as “12.50.” Include any notes or comments in SCHEDULE 7.

SCHEDULE 5. GENERATOR CONSTRUCTION COST INFORMATION

1. The reporting year is the calendar year that you are filing the survey for. For example, if you are reporting data as of December 31, 2013, then the reporting year is 2013.

2. Include all construction costs in SCHEDULE 5 regardless of which party is ultimately responsible for those costs. All disputed costs must be included in the reported estimated or final project costs. If disputed costs are included in the reported estimated or final project costs, you can note this in SCHEDULE 7.

SCHEDULE 5, PART A. GENERATOR CONSTRUCTION COST INFORMATION - COAL AND NUCLEAR GENERATORS

Complete a separate SCHEDULE 5, PART A for each coal or nuclear generator that, during the reporting year:

• Began commercial operation; or

• Was under construction, in final testing or in the process of receiving permits and regulatory approvals; or

• Was a nuclear generator that has applied for a combined operating license (COL) from the Nuclear Regulatory Commission.

Enter the Plant Name, EIA Plant Code, and Generator ID as previously reported in SCHEDULE 3, PART A.

1. For line 1, What is the total construction cost for this generator (in thousands of dollars)? If the generator did not enter commercial operation during the reporting year, provide the best available projection of the total construction cost to completion. If the project entered commercial operation during the reporting year, provide the best available estimate of total construction costs. Total Construction Costs should be provided in nominal dollars (do not discount future costs to reflect the time value of money and do not adjust past costs to reflect inflation) and typically include the following items:

• Civil and structural costs - allowance for site preparation, drainage, installation of underground utilities, structural steel supply, and construction of buildings on the site. Exclude land acquisition or leasing costs.

• Mechanical equipment supply and installation - major equipment, including but not limited to, boilers, flue gas desulfurization scrubbers, cooling towers, steam turbine generators, condensers, and other auxiliary equipment.

• Electrical and instrumentation control – electrical transformers, switchgear, motor control centers, switchyards, distributed control systems, and other electrical commodities.

• Project indirect costs – engineering, distributable labor and materials, craft labor overtime and incentives, scaffolding costs, construction management start up and commissioning, and fees for contingency (including contractor overhead costs, fees, profits, and construction).

• Owner Costs – development costs, preliminary feasibility and engineering studies, environmental studies and permitting, legal fees, insurance costs, property taxes during construction, and the electrical interconnection costs, including a tie-in to a nearby electrical transmission system.

Exclude financing, government grants, tax benefits, or other incentives from this number.

2. For line 2, What are the total financing costs for construction of this generator (in thousands of dollars)? Enter the total financing costs including (1) the interest cost of debt financing, (2) any imputed cost of equity financing, and (3) funds recovered to maintain a debt service coverage ratio for the project. In the cast of investor-owned utilities, financing costs include any allowance for funds used during construction (AFUDC). For example, the net cost for the period of construction of borrowed funds used for construction purposes and a reasonable rate on other funds when so used.

3. For line 3, What is the total cost to construct this generator including financing costs (in thousands of dollars)? Enter the total cost to construct the generator including both construction costs and financing. This value should be the sum of the answers to the two previous questions.

SCHEDULE 5, PART B. GENERATOR CONSTRUCTION COST INFORMATION - OTHER THAN COAL AND NUCLEAR GENERATORS

Complete a separate SCHEDULE 5, PART B for each generator other than coal or nuclear generators that, during the reporting year:

• Began commercial operation

Do not report for any units reported on SCHEDULE 5, PART A.

Enter the Plant Name, EIA Plant Code, and Generator ID as previously reported in SCHEDULE 3, PART A.

1. For line 1, What is the total construction cost for this generator (in thousands of dollars)? Enter the total construction cost to completion. Total Construction Costs should be provided in nominal dollars (do not discount future costs to reflect the time value of money and do not adjust past costs to reflect inflation) and typically include the following items:

• Civil and structural costs - allowance for site preparation, drainage, installation of underground utilities, structural steel supply, and construction of buildings on the site. Exclude land acquisition or leasing costs.

• Mechanical equipment supply and installation - major equipment, including but not limited to, boilers, flue gas desulfurization scrubbers, cooling towers, steam turbine generators, condensers, photovoltaic modules, combustion turbines, and other auxiliary equipment.

• Electrical and instrumentation control – electrical transformers, switchgear, motor control centers, switchyards, distributed control systems, and other electrical commodities.

• Project indirect costs – engineering, distributable labor and materials, craft labor overtime and incentives, scaffolding costs, construction management start up and commissioning, and fees for contingency (including contractor overhead costs, fees, profits, and construction).

• Owner Costs – development costs, preliminary feasibility and engineering studies, environmental studies and permitting, legal fees, insurance costs, property taxes during construction, and the electrical interconnection costs, including a tie-in to a nearby electrical transmission system.

Exclude financing, government grants, tax benefits, or other incentives from this number.

2. For line 2, What are the total financing costs for construction of this generator (in thousands of dollars)? Enter the total financing costs including (1) the interest cost of debt financing, (2) any imputed cost of equity financing, and (3) funds recovered to maintain a debt service coverage ratio for the project. In the cast of investor-owned utilities, financing costs include any allowance for funds used during construction (AFUDC). For example, the net cost for the period of construction of borrowed funds used for construction purposes and a reasonable rate on other funds when so used.

3. For line 3, What is the total cost to construct this generator including financing costs (in thousands of dollars)? Enter the total cost to construct the generator including both construction costs and financing. This value should be the sum of the answers to the two previous questions.

SCHEDULE 6. INFORMATION ON BOILERS AND ASSOCIATED EQUIPMENT

SCHEDULE 6 collects information on existing and planned boilers and associated equipment serving steam electric generators, including units burning combustible fuels, nuclear units, and solar thermal units. Complete for EACH boiler.

Complete SCHEDULE 6 as follows:

SCHEDULE 6, PART A. PLANT CONFIGURATION AND ENVIRONMENTAL EQUIPMENT INFORMATION

Complete SCHEDULE 6, Part A, if you are reporting for a plant where the sum of the nameplate capacity of the steam-electric generators, including duct-fired steam components of combined cycle units, sum to 10 MW or more.

1. For line 1, What equipment is associated with each boiler at this plant?

Enter the unique identification codes commonly used by plant management to identify the boiler and all associated equipment: generators, cooling systems, particulate matter control systems, sulfur dioxide control systems, NOx control, mercury control and stacks.

These identification codes are generally restricted to six characters and cannot be changed once provided to EIA. However, the identification codes for generators are restricted to five characters.

Include all equipment that:

• Was operable in the past calendar year; or

• Is expected to be in commercial operation within 10 years in the case of equipment associated with coal and nuclear generators; or

• Is expected to be in commercial operation within 5 in the case of equipment not associated with coal and nuclear generators

If two or more pieces of equipment (e.g., two generators) are associated with a single boiler, report each identification code separated by commas under the appropriate boiler.

If any equipment is associated with multiple boilers, repeat the equipment identification code under each boiler. Do not change prepopulated equipment identification codes.

Note equipment such as selective catalytic reduction, activated carbon injection, and dry sorbent injection into a fluidized bed boiler will require an identification code entry as these were not collected in past reporting years.

• Row 1 – Enter boiler ID

• Row 2 – Enter all generator ID(s) associated with the boiler (Generator ID must match those entered on SCHEDULE 3 PART A.

• Row 3 – Enter associated cooling system ID(s)

• Row 4 – Enter associated particulate matter control system ID(s)

• Row 5 – Enter associated sulfur dioxide control system ID(s) including dry sorbent injection (DSI) in a fluidized bed combustion boiler

• Row 6 – Enter associated nitrogen oxide (NOx) control equipment ID(s) (assign an ID to each selective catalytic reduction and selective noncatalytic reduction device).

• Row 7 – Enter associated mercury control ID(s), including activated carbon injection (assign an ID to each mercury control system).

• Row 8 – Enter associated stack (or flue) ID(s)

2. For Line 2, What are the characteristics of each piece of emissions control equipment?

Enter in Column A, the Equipment Type code from Table 7.

Table 7. Equipment Type Code and Description

Equipment Type Code	Equipment Type Description
JB	Jet bubbling reactor (wet) scrubber
MA	Mechanically aided type (wet) scrubber
PA	Packed type (wet) scrubber
SP	Spray type (wet) scrubber
TR	Tray type (wet) scrubber
VE	Venturi type (wet) scrubber
BS	Baghouse (fabric filter), shake and deflate
BP	Baghouse (fabric filter), pulse
BR	Baghouse (fabric filter), reverse air
EC	Electrostatic precipitator, cold side, with flue gas conditioning
EH	Electrostatic precipitator, hot side, with flue gas conditioning
EK	Electrostatic precipitator, cold side, without flue gas conditioning
EW	Electrostatic precipitator, hot side, without flue gas conditioning
MC	Multiple cyclone
SC	Single cyclone
CD	Circulating dry scrubber
SD	Spray dryer type / dry FGD / semi-dry FGD
DSI	Dry sorbent (powder) injection type (DSI)
ACI	Activated carbon injection system
SN	Selective noncatalytic reduction
SR	Selective catalytic reduction
OT	Other equipment (Specify in SCHEDULE 7)

For Columns B to J:

Enter the identification codes from the above table in the appropriate columns for emissions controls. If a piece of equipment controls multiple air emissions, enter the appropriate code in multiple columns (for example, if a wet scrubber controls for both sulfur dioxide, particulate matter and mercury, enter the associated identification code from the table above in Columns B, C and E).

• For Particulate Control (PM) equipment, enter identification code(s) in Column B

• For Sulfur Dioxide Control (SO2) equipment, enter the identification code(s) in Column C

• For Nitrogen Oxide Control (NOx) equipment, enter the identification code(s) in Column D

• For Mercury Control (Hg) equipment, enter the identification code(s) in Column E

• For HCl gas control, enter an X in Column F (no identification codes are required).

• For Column G, enter the status for the equipment as of December 31 of the reporting year from Table 8 in the instructions.

Table 8. Equipment Status Codes and Descriptions

Status Code	Status Description
CN	Cancelled (previously reported as “planned”)
CO	New unit under construction
OP	Operating (in commercial service or out of service less than 365 days)
OS	Out of service (365 days or longer)
OZ	Operated only during the ozone season (May through September)
PL	Planned (expected to go into commercial service within 10 years)
RE	Retired (no longer in service and not expected to be returned to service)
SB	Standby (or inactive reserve); i.e., not normally used, but available for service
SC	Cold Standby (Reserve); deactivated (usually requires 3 to 6 months to reactivate)
TS	Operating under test conditions (not in commercial service)

In Column H, In-service Date, enter the date on which the equipment began commercial operation or the date on which it is expected to begin commercial operation (MM/YYYY).

In Column I, Retirement Date, enter the date on which the equipment retired or is expected to be retired. If the expected retirement date is unknown leave blank.

In Column J, Total Costs (Thousand Dollars), enter the nominal installed cost for the existing system or the anticipated cost to bring a planned piece of equipment into commercial operation (in thousands of dollars). Installed cost should include the cost of all major modifications. A major modification is any physical change which results in a change in the amount of air emissions or pollutants or which results in a different pollutant being emitted. Costs should be provided in nominal dollars (do not discount future costs to reflect the time value of money and do not adjust past costs to reflect inflation)

SCHEDULE 6, PART B. BOILER INFORMATION – AIR EMISSION STANDARDS AND CONTROL STRATEGIES

For plants with a total steam-electric nameplate capacity of 10 MW or greater but less than 100 MW:

Complete ONLY questions 1, 3 to 8, 11,12, 13 and 14 (SO2, NOx and Mercury questions) SCHEDULE 6, Part B for each boiler and its associated equipment that serve or are expected to serve combustible-fueled steam electric generators or combined cycle steam generators with duct firing.

For plants with a total steam-electric nameplate capacity of 100 MW or greater:

Complete one SCHEDULE 6, Part B in its entirety for each boiler and its associated equipment that serve or are expected to serve combustible-fueled steam electric generators and combined cycle steam generators with duct firing.

Include all boilers that:

• Were operable in the past calendar year; or

• Are expected to be in commercial operation within 10 years in the case of coal plans; or

• Are expected to be in commercial operation within 5 years in the case of non-coal plants

1. For line 1, What is this boiler’s identification code? Enter the boiler identification number corresponding to each boiler listed on SCHEDULE 6, PART A.

2. For Line 2a, Type of Boiler Standards under Which the Boiler is Operating, indicate the standards as described in the U. S. Environmental Protection Agency regulation under 40 CFR. Select from the codes in Table 9 of the New Source Performance Standards (NSPS):

Table 9. Boiler Standards Codes and Descriptions

D	Standards of Performance for fossil-fuel fired steam boilers for which construction began after August 17, 1971.
Da	Standards of Performance for fossil-fuel fired steam boilers for which construction began after September 18, 1978
Db	Standards of Performance for fossil-fuel fired steam boilers for which construction began after June 19, 1984.
Dc	Standards of Performance for small industrial-commercial-institutional steam generating units
N	Not covered under New Source Performance Standards.

For line 2b, Is this boiler operating under a new Source Review (NSR) permit?, indicate whether the boiler is operating under a new source review permit

For line 2c, if the boiler is operating under a NSR permit, provide the NSR Permit List Date and NSR Permit identification number.

Lines 3-5 apply to sulfur dioxide compliance

Boilers that burn only natural gas may select “Not Applicable” for line 3a and skip questions 3b, 3c, 3d, 3e, 4, 5a, and 5b .

3. For line 3a, What is the regulatory level of the most stringent regulation that this boiler is operating under to meet sulfur dioxide control standards? Select the most stringent regulation that the boiler operates under to meet sulfur dioxide control standards.

For line 3b, What is the emission rate specified by the most stringent sulfur dioxide regulation? Enter the emission rate corresponding to the most stringent sulfur dioxide regulation. Pounds of sulfur dioxide per million Btu in fuel is the preferred measurement or use Units of Measurement in Table 10.

For line 3c, What is the percent of sulfur to be scrubbed specified by the most stringent sulfur dioxide regulation? If the most stringent regulation specifies a percent (by weight) of sulfur to be scrubbed enter the percent.

For line 3d, What is the unit of measurement specified by the most stringent sulfur dioxide regulation? Select the unit of measure corresponding to the emission rate entered in line 3b from the values in Table 10. Note that DP*, “Pounds of sulfur dioxide per million Btu in fuel” is the preferred measurement.

Table 10. Sulfur Dioxide Unit of Measurement Codes

Sulfur Dioxide Unit of Measurement Code	Sulfur Dioxide Unit of Measurement Code Description
DC	Ambient air quality concentration of sulfur dioxide (parts per million)
DH	Pounds of sulfur dioxide emitted per hour
DL	Annual sulfur dioxide emission level less than a level in a previous year
DM	Parts per million of sulfur dioxide in stack gas
DP*	Pounds of sulfur dioxide per million Btu in fuel
SB	Pounds of sulfur per million Btu in fuel
SR	Percent sulfur removal efficiency (by weight)
SU	Percent sulfur content of fuel (by weight)
OT	Other (specify in SCHEDULE 7)

For line 3e, What is the time period specified by the most stringent sulfur dioxide regulation? Enter the time period corresponding to the emission rate entered in line 3b from the values in Table 11.

Table 11. Time Period Codes

Time Period Code	Time Period Code Description
NV	Never to exceed
FM	5 minutes
SM	6 minutes
FT	15 minutes
OH	1 hour
WO	2 hours
TH	3 hours
EH	8 hours
DA	24 hours
WA	1 week
MO	30 days
ND	90 days
YR	Annual
PS	Periodic stack testing
DT	Defined by testing
NS	Not specified
OT	Other (specify in SCHEDULE 7)

4. For line 4, In what year did the boiler became compliant or is expected to become compliant with the most stringent sulfur dioxide regulation? Indicate the year in which the boiler came into compliance or is expected to come into compliance with Federal, State and Local Regulations as they relate to sulfur dioxide control.

5. For line 5a, What is your existing strategy for complying with the most stringent sulfur dioxide regulation? Identify up to three strategies from Table 12 that are currently used to address Federal, State or local regulations as they relate to sulfur dioxide control.

Table 12. Sulfur Dioxide Compliance Strategies

Sulfur Dioxide Compliance Codes	Sulfur Dioxide Compliance Code Descriptions
CF	Fluidized Bed Combustor
IF	Use flue gas desulfurization unit or other SO2 control process (specify the specific type of equipment in Schedule 6A)
SS	Switch to lower sulfur fuel
WA	Allocated allowances and purchase allowances
OT	Other (specify in SCHEDULE 7)
SE	Seeking revision of government regulation
ND	Not determined at this time
NP	No plans to control
NA	Not applicable

For line 5b, What is your proposed strategy for complying with the most stringent sulfur dioxide regulation? Identify up to three strategies from Table 12 that are planned to be used to address Federal, State or local regulations as they relate to sulfur dioxide control.

Lines 6-8 apply to nitrogen oxide compliance

6. For line 6a, What is the regulatory level of the most stringent regulation that this boiler is operating under to meet nitrogen oxide control standards? Select the most stringent regulation that the boiler operates under to meet nitrogen oxide control standards.

For line 6b, What is the emission rate specified by the most stringent nitrogen oxide regulation? Enter the emission rate corresponding to the most stringent nitrogen oxide regulation. Pounds of nitrogen oxides per million Btu in fuel is the preferred measurement or use Units of Measurement in Table 13.

For line 6c, What is the unit of measurement specified by the most stringent nitrogen oxide regulation? Select the unit of measure corresponding to the emission rate entered in line 6b from the values in Table 13. Note that “Pounds of nitrogen oxides per million Btu in fuel” is the preferred measurement.

Table 13. Nitrogen Oxide Unit of Measurement Codes

Nitrogen Oxide Unit of Measurement Code	Nitrogen Oxide Unit of Measurement Code Description
NH	Pounds of nitrogen oxides emitted per hour
NL	Annual nitrogen oxides emission level less than a level in a previous year
NM	Parts per million of nitrogen oxides in stack gas
NO	Ambient air quality concentration of nitrogen oxides (parts per million)
NP*	Pounds of nitrogen oxides per million Btu in fuel
OT	Other (specify in SCHEDULE 7)

For line 6d, What is the time period specified by the most stringent nitrogen oxide regulation? Enter the time period corresponding to the emission rate entered in line 6b from the values in Table 11.

7. For line 7, In what year did the boiler became compliant or is expected to become compliant with the most stringent nitrogen oxide regulation? Indicate the year in which the boiler came into compliance or is expected to come into compliance with Federal, State and Local Regulations as they relate to nitrogen oxide control.

8. For line 8a, What is your existing strategy for complying with the most stringent nitrogen oxide regulation? Identify up to three strategies from Table 14 that are currently used to address Federal, State or local regulations as they relate to nitrogen oxide control.

Table 14. Nitrogen Oxide Compliance Codes and Strategies

Nitrogen Oxide Compliance Codes	Nitrogen Oxide Compliance Strategies
AA	Advanced overfire air
BO	Burner out of service
BF	Biased firing (alternative burners)
CF	Fluidized bed combustor
FR	Flue gas recirculation
FU	Fuel reburning
H2O	Water injection
LA	Low excess air
LN	Low NOx burner
NH3	Ammonia injection
OV	Overfire air
RP	Repower unit
SN	Selective noncatalytic reduction
SR	Selective catalytic reduction
STM	Steam injection
UE	Decrease utilization – rely on energy conservation and/or improved efficiency
OT	Other (specify in SCHEDULE 7)
SE	Seeking revision of government regulation
ND	Not determined at this time
NP	No plans to control
NA	Not applicable

For line 8b, What is your proposed strategy for complying with the most stringent nitrogen oxide regulation? Identify up to three strategies from Table 14 that are planned to be used to address Federal, State or local regulations as they relate to nitrogen oxide control.

Lines 9-10 apply to particulate matter compliance

9. For line 9a, What is the regulatory level of the most stringent regulation that this boiler is operating under to meet particulate matter control standards? Select the most stringent regulation that the boiler operates under to meet particulate matter control standards.

For line 9b, What is the emission rate specified by the most stringent particulate matter regulation? Enter the emission rate corresponding to the most stringent particulate matter regulation. Pounds of particulate matter per million Btu in fuel is the preferred measurement or use Units of Measurement in Table 15.

For line 9c, What is the unit of measurement specified by the most stringent particulate matter regulation? Select the unit of measure corresponding to the emission rate entered in line 9b from the values in Table 15. Note that “Pounds of Particulate matter per million Btu in fuel” is the preferred measurement.

Table 15. Particulate Matter Unit of Measurement Codes

Particulate Matter Unit of Measurement Code	Particulate Matter Unit of Measurement Code Description
OP	Percent of opacity
PB*	Pounds of Particulate matter per million Btu in fuel
PC	Grains of particulate matter per standard cubic foot of stack gas
PG	Pounds of particulate matter per thousand pounds of stack gas
PH	Pounds of particulate matter emitted per hour
UG	Micrograms of particulate matter per cubic meter
OT	Other (specify in SCHEDULE 7)

For line 9d, What is the time period specified by the most stringent particulate matter regulation? Enter the time period corresponding to the emission rate entered in line 9b from the values in Table 11.

10. For line 10, In what year did the boiler became compliant or is expected to become compliant with the most stringent particulate matter regulation? Indicate the year in which the boiler came into compliance or is expected to come into compliance with Federal, State and Local Regulations as they relate to particulate matter control.

Lines 11-14 apply to mercury and acid gas compliance

11. For line 11, What is the regulatory level of the most stringent regulation that this boiler is operating under to meet mercury and acid gas standards? Select the most stringent regulation that the boiler operates under to meet mercury and acid gas control standards.

12. For line 12, In what year did the boiler became compliant or is expected to become compliant with the most stringent mercury and acid gas regulation? Indicate the year in which the boiler came into compliance or is expected to come into compliance with Federal, State and Local Regulations as they relate to mercury and acid gas control.

13. For line 13, What are the existing strategies to control mercury emissions? Identify up to three strategies from Table 16 that are currently used to address Federal, State or local regulations as they relate to mercury control. .

Table 16. Mercury Compliance Codes and Descriptions

Strategy Type Code	Strategy Type Description
BS	Baghouse (fabric filter), shake and deflate
BP	Baghouse (fabric filter), pulse
BR	Baghouse (fabric filter), reverse air
CD	Circulating dry scrubber
SD	Spray dryer type / dry FGD / semi-dry FGD
DSI	Dry sorbent (powder) injection type
ACI	Activated carbon injection system
LIJ	Lime injection
EC	Electrostatic precipitator, cold side, with flue gas conditioning
EH	Electrostatic precipitator, hot side, with flue gas conditioning
EK	Electrostatic precipitator, cold side, without flue gas conditioning
EW	Electrostatic precipitator, hot side, without flue gas conditioning
JB	Jet bubbling reactor (wet) scrubber
MA	Mechanically aided type (wet) scrubber
PA	Packed type (wet) scrubber
SP	Spray type (wet) scrubber
TR	Tray type (wet) scrubber
VE	Venturi type (wet) scrubber
OT	Other (specify in SCHEDULE 7)
SE	Seeking revision of government regulation
ND	Not determined at this time
NP	No plans to control
NA	Not applicable

14. For line 14, What are the proposed strategies to control mercury emissions? Identify up to three strategies from Table 16 that are planned to be used to address Federal, State or local regulations as they relate to mercury control.

SCHEDULE 6, PART C. BOILER INFORMATION – DESIGN PARAMETERS

Complete SCHEDULE 6, Part C, ONLY Lines 1 through 3 if you are reporting for a plant where the sum of the nameplate capacity of the steam-electric generators, including duct fired steam components of combined cycle units, sum to at least 10 MW, but less than 100 MW.

Complete SCHEDULE 6, Part C in its entirety if you are reporting for a plant where the sum of the nameplate capacity of the steam-electric generators, including duct fired steam components of combined cycle units, sum to 100 MW or more.

Complete one SCHEDULE 6, Part C for each unique Boiler ID as reported on SCHEDULE 6 PART A, Line 1, Row 1

1. For Line 1a, Is this boiler a heat recovery steam generator (HRSG)? Indicated whether the boiler being identified is actually a heat recovery steam generator.

For line 1b, What was this boiler’s status as of December 31 of the reporting year? Select the boiler status from Table 17:

Table 17. Boiler Status Codes and Descriptions

Boiler Status Code	Boiler Status Description
CN	Cancelled (previously reported as “planned”)
CO	New unit under construction
OP	Operating (in commercial service or out of service less than 365 days)
OS	Out of service (365 days or longer)
PL	Planned (expected to go into commercial service within 10 years)
RE	Retired (no longer in service and not expected to be returned to service)
SB	Standby (or inactive reserve); i.e., not normally used, but available for service
SC	Cold Standby (Reserve); deactivated (usually requires 3 to 6 months to reactivate)
TS	Operating under test conditions (not in commercial service)

2. For line 2, What is the actual or projected in-service date for this boiler? Enter the month during which the boiler came into service or is expected to come into service. The month-year date should be entered as follows: August 1959 as 08-1959. If the month is unknown, use the month of June.

3. For line 3, What is the actual or projected retirement date for this boiler? Enter the month during whicht the boiler was retired or is expected to be retired. The month-year date should be entered as follows: August 1959 as 08-1959. If the month is unknown, use the month of June.

4. For line 4, What type of boiler is this? Enter up to three of the firing codes from Table 18.

Table 18. Boiler Firing Type Code and Description

Boiler Type Code	Boiler Type Description
CB	Cell Burner
CY	Cyclone Firing
DB	Duct Burner
FB	Fluidized Bed Firing (Circulating Fluidized Bed, Bubbling Fluidized Bed)
SS	Stoker (Spreader, Vibrating Gate, Slinger)
TF	Tangential Firing / Concentric Firing / Corner Firing
VF	Vertical Firing / Arch Firing
WF	Wall Fired (Opposed Wall, Rear Wall, Front Wall, Side Wall)
OT	Other (specify in SCHEDULE 7)

5. For lines 5, What is the maximum continuous steam flow at 100 percent load for this boiler? Enter the maxium, design steam flow for the boiler at 100 percent load in 1000 pounds per hour.

6. For line 6, What is the design firing rate at the maximum continuous steam flow for coal and petroleum coke? Enter the design firing rate data for burning coal and petroleum coke to the nearest 0.1 tons per hour. Do not enter firing rate data for startup or flame stabilization fuels. For waste-heat boilers with auxiliary firing, enter the firing rate for auxiliary firing.

7. For line 7, What is the design firing rate at the maximum continuous steam flow for petroleum liquids? Enter the design firing rate data for burning petroleum liquids to the nearest 0.1 barrels per hour. Do not enter firing rate data for startup or flame stabilization fuels. For waste-heat boilers with auxiliary firing, enter the firing rate for auxiliary firing.

8. For line 8, What is the design firing rate at the maximum continuous steam flow for natural gas? Enter the design firing rate data for burning natural gas to the nearest 0.1 thousand cubic feet per hour. Do not enter firing rate data for startup or flame stabilization fuels. For waste-heat boilers with auxiliary firing, enter the firing rate for auxiliary firing.

9. For line 9, What is the design firing rate at the maximum continuous steam flow for energy sources other than coal, petroleum or natural gas? Enter the design firing rate data for burning any other primary fuel other than coal, petroleum or natural gas. Do not enter firing rate data for startup or flame stabilization fuels. For waste-heat boilers with auxiliary firing, enter the firing rate for auxiliary firing. Specify the primary fuel (use codes from Table 28) for which value is provided along with related measurement unit in SCHEDULE 7.

10. For line 10, What is the design waste-heat input rate at maximum continuous steam flow for this boiler? If the boiler receives all or a substantial portion of its energy input from the noncombustible exhaust gases of a separate fuel-burning process, enter the design waste-heat input rate as measured in million Btu per hour at maximum continuous steam flow.

11. For line 11, What fuels are used by this boiler in order of predominance? Enter the fuels used by this boiler in order of predominance. Select energy source codes from Table 28 in the instructions in order of predominance based on Btu. Enter up to six energy sources.

12. For line 12, What is the turndown ratio for this boiler? Calculate (to nearest 0.1) the turndown ratio for the boiler as the ratio of the boiler’s maximum output to its minimum output.

13. For line 13, What is the efficiency of this boiler when it is burning the reported primary fuel at 100 percent load? Enter the efficiency of the boiler when burning the reported primary fuel at 100 percent load.

14. For line 14, What is the efficiency of this boiler when it is burning reported primary fuel at 50 percent load? Enter the efficiency of the boiler when burning the reported primary fuel at 50 percent load.

15. For line 15, What is the total air flow (including excess air) at 100 percent load? Report the total air flow (including excess air) at 100 percent load. Report air flow at standard temperature and pressure (i.e., 68 degrees Fahrenheit and one atmosphere pressure).

16. For line 16, Does the boiler have a wet bottom or a dry bottom? Indicate whether the boiler has a wet bottom or dry bottom. Report only for coal-capable boilers. Wet Bottom is defined as having slag tanks installed at the furnace’s throat to contain and remove molten ash from the furnace. Dry Bottom is defined as having no slag tanks installed at the furnace’s throat so bottom ash drops through throat to bottom ash water hoppers.

17. For line 17, Is the boiler capable of fly ash re-injection? Indicate whether the boiler is capable of re-injecting fly ash.

SCHEDULE 6, PART D. COOLING SYSTEM INFORMATION – DESIGN PARAMETERS

Complete SCHEDULE 6, PART D for plants with a total steam-electric nameplate capacity of 100 MW or greater consisting of:

• Combustible fueled steam-electric generators, including combined cycle steam generators with duct firing;

• Combined cycle steam-electric generators without duct firing;

• Nuclear generators; or

• Solar thermal units using a steam cycle.

Complete one SCHEDULE 6 PART D for each unique Cooling system ID as reported on SCHEDULE 6 PART A, Line 1, Row 3.

1. For line 1, What is this identification code of the cooling system? Enter the cooling system’s identification code commonly used by plant management to refer to this cooling system. Cooling system identification should be the same identification as entered on SCHEDULE 6, PART A, Line 1, Row 3 and as reported on other EIA forms. This identification code is restricted to six characters and cannot be changed once provided to EIA.

2. For line 2, What was the status of this cooling system as of December 31 of the reporting year? Select from the cooling system’s status codes in Table 19.

Table 19. Cooling System Status Codes and Descriptions

Cooling System Status Code	Cooling System Status Description
CN	Cancelled (previously reported as “planned”)
CO	New unit under construction
OP	Operating (in commercial service or out of service less than 365 days)
OS	Out of service (365 days or longer)
PL	Planned (expected to go into commercial service within 10 years)
RE	Retired (no longer in service and not expected to be returned to service)
SB	Standby (or inactive reserve); i.e., not normally used, but available for service)
SC	Cold Standby (Reserve); deactivated (usually requires 3 to 6 months to reactivate)
TS	Operating under test conditions (not in commercial service)

3. For line 3, What is the actual or projected in-service date of commercial operation for this cooling system? Enter either the date on which the cooling system began commercial operation or the date on which the system is expected to begin commercial operation.

4. For line 4a, What type of cooling system is this? Select up to four types from the cooling system type codes in Table 20 that reflect that components of the cooling system. If the plant has a downstream helper tower that is associated with all boilers at a plant instead of any particular boiler or combination of boilers, treat it as a distinct cooling system and select “HT” from the list of codes.

Table 20. Cooling System Type Codes and Descriptions

Cooling System Type Code	Cooling System Type Description
DC	Dry (air) cooling system
HRC	Hybrid: cooling pond(s) or canal(s) with dry cooling
HRF	Hybrid: forced draft cooling tower(s) with dry cooling
HRI	Hybrid: induced draft cooling tower(s) with dry cooling
OC	Once through with cooling pond(s)
ON	Once through without cooling pond(s)
RC	Recirculating with cooling pond(s) or canal(s)
RF	Recirculating with forced draft cooling tower(s)
RI	Recirculating with induced draft cooling tower(s)
RN	Recirculating with natural draft cooling tower(s)
HT	Helper Tower
OT	Other (specify in SCHEDULE 7)

For line 4b, If this is a hybrid cooling system, what percent of the cooling load is served by dry cooling components? In the case of a hybrid cooling system, indicate the percent of total cooling load that is served by any dry cooling components.

5. For line 5, What is the name of the water source for this cooling system? Provide the name of the river, lake, or other water source for the cooling system if different than the water source listed on question 6 of SCHEDULE 2.

6. For line 6, What is the name of the cooling system’s discharge body of water? If the discharge body of water is different than the source of the cooling water, enter the name of the water.

7. For line 7, What is the cooling water source code for this system? Select the appropriate cooling water source from Table 21:

Table 21. Cooling Water Source Code and Description

Cooling Water Source Code	Cooling Water Source Description
SW	Surface Water (ex: river, canal, bay)
GW	Ground Water (ex: aquifer, well)
PD	Plant Discharge Water (ex: wastewater treatment plant discharge)
OT	Other (specify in SCHEDULE 7)

8. For line 8, What type of cooling water is used for this system? Select the type of cooling water used by the cooling system from Table 22.

Table 22. Cooling Water Type Codes and Description

Type of Cooling Water Code	Type of Cooling Water Description
BR	Brackish Water
FR	Fresh Water
BE	Reclaimed Water (ex: treated wastewater effluent)
SA	Saline Water
OT	Other (specify in SCHEDULE 7)

9. For line 9, What is the design maximum cooling water flow rate at 100 percent load at intake? Enter the design maximum flow rate (gallons per minute) for the cooling system when operating at 100 percent load.

10. For line 10, What is the actual or projected in-service date for the chlorine discharge control structures and equipment? Enter either the date on which the chlorine discharge control structures and equipment began commercial operation or the date on which the chlorine discharge control structures and equipment are expected to begin commercial operation, if applicable.

11. For lines 11, What is the actual or projected in-service date for the cooling pond(s)? Enter either the date on which the cooling pond(s) began commercial operation or the date on which cooling pond(s) is expected to begin commercial operation, if applicable. A cooling pond is a natural or man-made body of water that is used for dissipating waste heat from power plants.

12. For line 12 What is the total surface area for the cooling pond(s)? Enter the total surface area for the cooling pond(s), if applicable. A cooling pond is a natural or man-made body of water that is used for dissipating waste heat from power plants.

13. For line 13, What is the total volume of the cooling ponds? Enter the total volume of the cooling pond(s), if applicable. A cooling pond is a natural or man-made body of water that is used for dissipating waste heat from power plants.

14. For line 14, What is the actual or projected in-service date for cooling towers? Enter either the date on which the cooling tower(s) began commercial operation or the date on which the cooling tower(s) is expected to begin commercial operation, if applicable.

15. For line 15, What types of cooling towers are at this plant or are planned to be at this plant? Enter all tower types that apply from the cooling tower codes in Table 23.

Table 23. Types of Towers

Tower Type Code	Tower Type Description
MD	Mechanical draft, dry process
MW	Mechanical draft, wet process
ND	Natural draft, dry process
NW	Natural draft, wet process
WD	Combination wet and dry processes
OT	Other (specify in SCHEDULE 7)

16. For line 16 What is the design rate of water flow at 100 percent load for the cooling towers? Enter the design flow rate (gallons per minute) for the cooling tower when operating at 100 percent generator load in gallons per minute.

17. For line 17, What is the maximum power requirement for the cooling towers at 100 percent load? Enter the maximum design power requirement for the cooling tower when operating at 100 percent generator load in megawatts.

18. For line 18, What is the total installed cost for this cooling system? Enter the total nominal installed cost for the existing system or the anticipated cost to bring a planned system into commercial operation in thousands of dollars. Installed cost should include the cost of all major modifications. The Total System Cost should include amounts for items such as pumps, piping, canals, ducts, intake and outlet structures, dams and dikes, reservoirs, cooling towers, and appurtenant equipment.

19. For line 19, What is the installed cost for the cooling ponds? Enter the nominal installed cost for the existing ponds or the anticipated cost to bring a planned pond into commercial operation in thousands of dollars. Installed cost should include the cost of all major modifications.

20. For line 20, What is the installed cost for the cooling towers? Enter the nominal installed cost for the existing towers or the anticipated cost to bring a planned tower into commercial operation in thousands of dollars. Installed cost should include the cost of all major modifications. A major modification is any physical change which results in a change in the amount of air or water pollutants or which results in a different pollutant being emitted.

21. For line 21, What is the installed cost for the chlorine discharge control structures and equipment? Enter in thousands of dollars, the nominal installed cost for the existing chlorine discharge control structures and equipment or the anticipated cost to bring planned chlorine discharge control structures and equipment into commercial operation. Installed cost should include the cost of all major modifications. A major modification is any physical change which results in a change in the amount of air or water pollutants or which results in a different pollutant being emitted.

22. For line 22a, What is the maximum distance of water intake from shore? Enter the maximum distance of the water intake from the shore, in feet.

For line 22b, What is the maximum distance of the water outlet from shore? Enter the maximum distance of the water outlet from the shore, in feet (not required for recirculating systems).

23. For lines 23a, What is the average distance of the water intake point below the surface of the water? Enter the average distance of the water intake point below the surface of the water, in feet.

For line 23b, What is the average distance of the water outlet point below the surface of the water? Enter the average distance of the water outlet points below the surface of the water, in feet (not required for recirculating systems).

SCHEDULE 6, PART E. FLUE GAS PARTICULATE COLLECTOR INFORMATION

Complete SCHEDULE 6, Part E for plants where the sum of the nameplate capacity of the steam-electric generators, including duct fired steam components of combined cycle units, sum to 10 MW or more.

Complete one SCHEDULE 6 PART E for each unique Particulate Matter Control system ID as reported on SCHEDULE 6 PART A, Line 1, Row 4.

1. For line 1, What is the identification code for the equipment controlling particulate matter? Enter the particulate matter control identification code as it was reported on SCHEDULE 6, Part A, Line 1, Row 4 (Associated Particulate Matter Control Systems).

2. For line 2, What type of flue gas particulate matter control is this? Select the flue gas particulate matter control type from Table 24. These should be the same equipment type entered on SCHEDULE 6, PART A, Line 2, COLUMN A for Particulate Matter Control. Enter up to three codes. If more than three exist, enter others in SCHEDULE 7, COMMENTS.

Table 24. Flue Gas Particulate Matter Control

Flue Gas Particulate Matter Control	Flue Gas Particulate Matter Control Description
BS	Baghouse (fabric filter), shake and deflate
BP	Baghouse (fabric filter), pulse
BR	Baghouse (fabric filter), reverse air
EC	Electrostatic precipitator, cold side, with flue gas conditioning
EH	Electrostatic precipitator, hot side, with flue gas conditioning
EK	Electrostatic precipitator, cold side, without flue gas conditioning
EW	Electrostatic precipitator, hot side, without flue gas conditioning
MC	Multiple cyclone
SC	Single cyclone
JB	Jet bubbling reactor (wet) scrubber
MA	Mechanically aided type (wet) scrubber
PA	Packed type (wet) scrubber
SP	Spray type (wet) scrubber
TR	Tray type (wet) scrubber
VE	Venturi type (wet) scrubber
OT	Other (specify in SCHEDULE 7)

3. For line 3, What is the design fuel specification for ash when burning coal or petroleum coke? Enter the design fuel specification for ash (as burned) to the nearest 0.1 percent of weight, when burning coal or petroleum coke, if applicable.

4. For line 4, What is the design fuel specification for ash when burning petroleum liquids? Enter the design fuel specification for ash (as burned) to the nearest 0.1 percent of weight, when burning petroleum liquids, if applicable.

5. For line 5, What is the design fuel specification for sulfur when burning coal or petroleum coke? Enter the design fuel specification for sulfur (as burned) to the nearest 0.1 percent of weight, when burning coal or petroleum coke, if applicable.

6. For line 6, What is the design fuel specification for sulfur when burning petroleum liquids? Enter design fuel specification for sulfur (as burned) to the nearest 0.1 percent of weight, when burning petroleum liquids, if applicable.

7. For line 7, What is the design collection efficiency for this flue gas particulate collector at 100 percent load? Enter the design collection efficiency (to nearest 0.1 percent) of the equipment at 100 percent generator load.

8. For line 8, What is the design particulate emission rate for this collector at 100 percent load? Enter the design particulate emission rate in pounds per hour at 100 percent generator load.

9. For line 9, What is the particulate collector gas exit rate at 100 percent load? Enter equipment’s gas exit rate in cubic feet per minute at 100 percent generator load.

10. For line 10, What is the particulate collector gas exit temperature? Enter the equipment’s gas exit temperature in degrees Fahrenheit.

SCHEDULE 6, PART F. FLUE GAS DESULFURIZATION UNIT INFORMATION (INCLUDES COMBUSTION TECHNOLOGIES)

Complete SCHEDULE 6, Part F for plants where the sum of the nameplate capacity of the steam-electric generators, including duct fired steam components of combined cycle units, sum to 10 MW or more.

Complete one SCHEDULE 6 PART F for each unique Sulfur Dioxide Control System ID as reported on SCHEDULE 6 PART A, Line 1, Row 5.

1. For line 1, What is the identification code for the equipment associated with this sulfur dioxide control? Enter the sulfur dioxide control identification code as reported on SCHEDULE 6, PART A, Line 1, Row 5 (Associated Sulfur Dioxide Control Systems)

2. For line 2, What type of sulfur dioxide control is this? Select the sulfur dioxide control code from Table 25. Enter up to three for each Sulfur Dioxide Control Identification Code.

Table 25. Sulfur Dioxide Control Codes and Descriptions

Sulfur Dioxide Control Codes	Sulfur Dioxide Control Description
ACI	Activated carbon injection system
JB	Jet bubbling reactor (wet) scrubber
MA	Mechanically aided type (wet) scrubber
PA	Packed type (wet) scrubber
SP	Spray type (wet) scrubber
TR	Tray type (wet) scrubber
VE	Venturi type (wet) scrubber
CD	Circulating dry scrubber
SD	Spray dryer type / dry FGD / semi-dry FGD
DSI	Dry sorbent (powder) injection type
OT	Other (specify in SCHEDULE 7)

3. For line 3, What type(s) of sorbent(s) is used by this unit? Select up to four sorbent codes from Table 26.

Table 26. Sorbent Type Codes and Descriptions

Sorbent Type Code	Type of Sorbent
AF	Alkaline fly ash
AM	Ammonia
CSH	Caustic Sodium hydroxide
DB	Dibasic acid assisted
LI	Lime / slacked lime / hydrated lime
LS	Limestone / dolomitic limestone / calcium carbonate
MO	Magnesium oxide
SA	Soda ash / Sodium bicarbonate / Sodium carbonate / Sodium formate / Soda liquid
TR	Trona
WT	Water / Treated wastewater (select only if no other sorbent is used)
OT	Other (specify in SCHEDULE 7)

4. For line 4, Is there any salable byproduct recovery? Enter “Yes” if there is any salable byproduct recovery. Otherwise, enter “No.”

5. For line 5, What are the annual pond and land fill requirements? Report the annual pond and land fill requirements in acre feet per year.

6. For line 6a, Is there a sludge pond associated with this unit? Indicate whether there is a sludge pond associated with this FGD unit.

For line 6b, Is the sludge pond lined? Indicate whether the sludge pond is lined.

7. For line 7, Can flue gas bypass the flue gas desulfurization unit? Indicate whether the flue gas can bypass the FGD unit.

8. For line 8, What is the design specification for ash when burning coal or petroleum coke? Enter the design fuel specifications for ash (as burned) to the nearest 0.1 percent of weight, when burning coal or petroleum coke, if applicable.

9. For line 9, What is the design specification for sulfur when burning coal or petroleum coke? Enter the design fuel specifications for sulfur (as burned) to the nearest 0.1 percent of weight, when burning coal or petroleum coke, if applicable.

10. For line 10, What is the total number of flue gas desulfurization unit scrubber trains or modules? Enter the total number of flue gas desulfurization unit scrubber trains or modules operated.

11. For line 11, How many flue gas desulfurization unit scrubber trains or modules are operated at 100 percent load? Enter how many flue gas desulfurization unit scrubber trains or modules are operated at 100 percent load.

12. For line 12, What is this unit’s design removal efficiency for sulfur dioxide when operating at 100 percent load? Report the design removal efficiency to nearest 0.1 percent by weight of gases removed from the flue gas when operating at 100 percent generator load.

13. For line 13, What is the design sulfur dioxide emission rate for this unit when operating at 100 percent load? Report the design sulfur dioxide emission rate in pounds per hour when operating at 100 percent generator load.

14. For line 14, What is the flue gas exit rate for this unit? Report the flue gas exit rate in actual cubic feet per minute when operating at 100 percent generator load.

15. For line 15, What is this unit’s flue gas exit temperature? Report the flue gas exit temperature in degrees Fahrenheit when operating at 100 percent generator load.

16. For line 16, What percentage of flue gas enters the flue gas desulfurization unit when operating at 100 percent load? Enter the percentage of flue gas entering this FGD unit at a percent of total gas when operating at 100 percent generator load.

17. For line 17, What are the installed or anticipated costs of all FGD structures and equipment, excluding land? Enter the nominal installed costs for the existing flue gas desulfurization unit or the anticipated costs, in thousand dollars, to bring a planned flue gas desulfurization unit into commercial operation. Installed cost should include the cost of all major modifications. A major modification is any physical change which results in a change in the amount of air or water pollutants or which results in a different pollutant being emitted.

18. For line 18, What are the installed costs of the sludge transport and disposal system? Enter the nominal installed costs for the sludge transport and disposal system, or the anticipated costs, in thousand dollars, to bring a planned sludge transport and disposal system into commercial operation. Installed cost should include the cost of all major modifications. A major modification is any physical change which results in a change in the amount of air or water pollutants or which results in a different pollutant being emitted.

19. For line 19, What other installed costs are there pertaining to the installation of the FGD unit? Enter any other nominal installed costs, in thousand dollars, pertaining to the installation of the flue gas desulfurization unit, or any other costs related to bringing a planned flue gas desulfurization unit into commercial operation. Installed cost should include the cost of all major modifications. A major modification is any physical change which results in a change in the amount of air or water pollutants or which results in a different pollutant being emitted.

20. For 20, What are the total installed costs of the FGD unit? Enter the total nominal installed cost, in thousand dollars, for the existing flue gas desulfurization unit or the total anticipated costs to bring a planned flue gas desulfurization unit into commercial operation. Installed cost should include the cost of all major modifications. A major modification is any physical change which results in a change in the amount of air or water pollutants or which results in a different pollutant being emitted. This total will be the sum of lines 17, 18, and 19.

SCHEDULE 6, PART G. STACK AND FLUE INFORMATION – DESIGN PARAMETERS

Complete SCHEDULE 6, Part G for plants where the sum of the nameplate capacity of the steam-electric generators, including duct fired steam components of combined cycle units, sum to 100 MW or more.

NOTE: A stack is defined as a vertical structure containing one or more flues used to discharge products of combustion into the atmosphere. A flue is defined as an enclosed passageway within a stack for directing products of combustion to the atmosphere. If the stack has a single flue, use the stack identification for the flue identification

Complete one SCHEDULE 6 PART G for each Stack ID or Flue ID reported on SCHEDULE 6 PART A, Line 1, Row 8.

1. For line 1, What is this stack or flue equipment’s identification code? Enter the identification code for each stack or flue as entered on SCHEDULE 6 PART A, Line 1, Row 8.

2. For line 2, What is the actual or projected in-service date for this stack or flue? Enter either the date on which the stack or flue began commercial operation or the date (MM/YYYY) on which the stack or flue are expected to begin commercial operation.

3. For line 3, What was the status of this stack or flue as of December 31 of the reporting year? Select one from the following equipment status codes from Table 27.

Table 27. Stack Status Codes and Description

Stack Status Code	Stack Status Code Description
CN	Cancelled (previously reported as “planned”)
CO	New unit under construction
OP	Operating (in commercial service or out of service within 365 days)
OS	Out of service (365 days or longer)
PL	Planned (on order or expected to go into commercial service within 10 years)
RE	Retired (no longer in service and not expected to be returned to service)
SB	Standby (or inactive reserve, i.e., not normally used, but available for service)
SC	Cold Standby (Reserve); deactivated. Usually requires 3 to 6 months to reactivate
TS	Operating under test conditions (not in commercial service).

4. For line 4, What is this stack’s height at the top, as measured from the ground? Enter the height of the stack in feet as measured from the ground by the plant.

5. For line 5, What is the cross-sectional area at the top of this stack? Enter the cross-sectional area at the top of the stack as measured in square feet.

6. For line 6, What is the design flue gas exit rate at the top of the stack at 100 percent load? Enter the design flue gas exit rate at the top of the stack when operating at 100 percent load as measured in actual cubic feet per minute. The rate should be approximately equal to the cross-sectional area of the flue multiplied by the velocity and then multiplied by 60.

7. For line 7, What is the design flue gas exit rate at the top of the stack at 50 percent load? Enter the design flue gas exit rate at the top of the stack when operating at 50 percent load as measured in actual cubic feet per minute. The rate should be approximately equal to the cross-sectional area of the flue multiplied by the velocity and then multiplied by 60.

8. For line 8, What is the design flue gas exit temperature at the top of the stack at 100 percent load? Enter the design flue gas exit temperature in degrees Fahrenheit at the top of the stack when operating at 100 percent load.

9. For line 9, What is the design flue gas exit temperature at the top of the stack at 50 percent load? Enter the design flue gas exit temperature in degrees Fahrenheit at the top of the stack when operating at 50 percent load.

10. For line 10, What is the design flue gas velocity at the top of the stack at 100 percent load? Enter the design flue gas exit velocity in feet per second at the top of the stack when operating at 100 percent load.

11. For line 11, What is the design flue gas velocity at the top of the stack at 50 percent load? Enter the design flue gas exit velocity in feet per second at the top of the stack when operating at 50 percent load.

12. For line 12, What is the average flue gas exit temperature for the summer season? Enter the seasonal average flue gas exit temperature in degrees Fahrenheit, based on the arithmetic mean of measurements during operating hours. Summer season includes June, July, and August.

13. For line 13, What is the average flue gas exit temperature for the winter season? Enter the seasonal average flue gas exit temperature in degrees Fahrenheit, based on the arithmetic mean of measurements during operating hours. Winter season includes December, January, and February (for example, when reporting for year 2013, use December 2012, January 2013 and February 2013).

14. For line 14, Were the average flue gas exit temperatures measures or estimated? Indicate whether the flue gas exit temperatures used to calculate the mean values reported on Lines 13 and 14 were measured or estimated.

SCHEDULE 7. COMMENTS

This schedule provides additional space for comments. Please identify schedule, part, and question and include identifying information (e.g., plant code, boiler id, generator id) for each comment. Use additional pages, if necessary.