GHG Summary Report

CO2 equivalent emissions from facility subparts C-II, SS, and TT (metric tons):4,264,561.5
CO2 equivalent emissions from supplier subparts LL-QQ (metric tons):
Biogenic CO2 emissions from facility subparts C-II, SS, and TT (metric tons):0
Cogeneration Unit Emissions Indicator:N
GHG Report Start Date:2019-01-01
GHG Report End Date:2019-12-31
Description of Changes to Calculation Methodology:
Did you use an EPA-approved BAMM in this reporting year for Subpart C?
Did you use an EPA-approved BAMM in this reporting year for Subpart X?
Plant Code Indicator:N
Primary NAICS Code:325110
Second Primary NAICS Code:
Additional NAICS Codes: 325211
Parent Company Details:

Parent Company Name:DOW INC
Address:2030 Dow Center, Midland, MI 48674
Percent Ownership Interest:100

Subpart C: General Stationary Fuel Combustion

Gas Information Details

Gas Name	Carbon Dioxide
Gas Quantity	3,040,890.2 (Metric Tons)
Own Result?	Y

Gas Name	Biogenic Carbon dioxide
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	Methane
Gas Quantity	71.35 (Metric Tons)
Own Result?

Gas Name	Nitrous Oxide
Gas Quantity	8.859 (Metric Tons)
Own Result?

Unit Details:

Unit Name : PE6_F6510
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 73 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

Fuel : Natural Gas (Weighted U.S. Average)
Tier Name : Tier 2 (Equation C-2a)
Tier Methodology Start Date : 2019-01-01
Tier Methodology End Date : 2019-12-31
Frequency of HHV determinations : Quarterly

Tier 2 Monthly HHV Details :

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
1693.7 (Metric Tons)	0.03 (Metric Tons)	0.003 (Metric Tons)	0.8 (Metric Tons)	1 (Metric Tons)

Unit Name : USCP_TO850
Unit Type : TODF (Thermal oxidizer, direct fired, no heat recovery)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 10 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
643.4 (Metric Tons)	0.01 (Metric Tons)	0.001 (Metric Tons)	0.3 (Metric Tons)	0.4 (Metric Tons)

Unit Name : CP-LHC9 Furnaces
Unit Type : OCS (Other combustion source)
Unit Description :
Other Unit Name :

Common Pipe Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 599
Cumulative Maximum Rated Heat Input Capacity: 4787

Emission Details:
Annual Biogenic CO2 Emissions: 0 (metric tons)
Annual Fossil fuel based CO2 Emissions: 28230.6 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
27910.1 (Metric Tons)	0.53 (Metric Tons)	0.053 (Metric Tons)	13.2 (Metric Tons)	15.7 (Metric Tons)

Fuel : Fuel Gas
Tier Name : Tier 3 (Equation C-5, gaseous fuel)
Tier Methodology Start Date : 2019-01-01
Tier Methodology End Date : 2019-12-31

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
466.2 (Metric Tons)	0.26 (Metric Tons)	0.052 (Metric Tons)	6.5 (Metric Tons)	15.6 (Metric Tons)

Carbon Content Substitute Data Information :
Total number of valid carbon content determinations : 12
Total number of carbon content substitute data values : 0
Frequency of carbon content determinations : Monthly
Total number of operating hours in the reporting year for which missing data substitution was used for fuel usage : 0

Molecular Weight Information :
Total number of valid molecular weight determinations : 12
Total number of molecular weight substitute data values : 0
Frequency of molecular weight determinations : Monthly
Molar Volume Constant (MVC) used : 849.5 (scf/kg-mole)

Unit Name : H-575 Heater
Unit Type : PRH (Process Heater)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 6.5 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
78.0 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)

Unit Name : LHC9 OC2 TOX
Unit Type : TODF (Thermal oxidizer, direct fired, no heat recovery)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 11 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

Fuel : Natural Gas (Weighted U.S. Average)
Tier Name : Tier 3 (Equation C-5, gaseous fuel)
Tier Methodology Start Date : 2019-01-01
Tier Methodology End Date : 2019-12-31

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
1835.6 (Metric Tons)	0.04 (Metric Tons)	0.004 (Metric Tons)	0.9 (Metric Tons)	1.1 (Metric Tons)

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
573.7 (Metric Tons)	0.93 (Metric Tons)	0.186 (Metric Tons)	23.2 (Metric Tons)	55.4 (Metric Tons)

Unit Name : PMDI_F621
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 190 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
39210.6 (Metric Tons)	0.74 (Metric Tons)	0.074 (Metric Tons)	18.5 (Metric Tons)	22 (Metric Tons)

Unit Name : PMDI_TO BU520
Unit Type : TODF (Thermal oxidizer, direct fired, no heat recovery)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 25 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
3625.2 (Metric Tons)	0.07 (Metric Tons)	0.007 (Metric Tons)	1.7 (Metric Tons)	2 (Metric Tons)

Unit Name : LHC7_H1 Furnace
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 514 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
129155.1 (Metric Tons)	2.43 (Metric Tons)	0.243 (Metric Tons)	60.9 (Metric Tons)	72.5 (Metric Tons)

Unit Name : FTOB_Thermatrix
Unit Type : OCS (Other combustion source)
Unit Description :
Other Unit Name : Thermatrix

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 54 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
17005.3 (Metric Tons)	0.32 (Metric Tons)	0.032 (Metric Tons)	8 (Metric Tons)	9.6 (Metric Tons)

Unit Name : LHC8_Furnace 10
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 292 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
1084.8 (Metric Tons)	0.02 (Metric Tons)	0.002 (Metric Tons)	0.5 (Metric Tons)	0.6 (Metric Tons)

Unit Name : LHC7_H5 Furnace
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 514 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
142331.0 (Metric Tons)	2.68 (Metric Tons)	0.268 (Metric Tons)	67.1 (Metric Tons)	79.9 (Metric Tons)

Unit Name : LHC8_Furnace 3
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 413 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
462.5 (Metric Tons)	0.01 (Metric Tons)	0.001 (Metric Tons)	0.2 (Metric Tons)	0.3 (Metric Tons)

Unit Name : LHC7_H2 Furnace
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 514 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
134399.2 (Metric Tons)	2.53 (Metric Tons)	0.253 (Metric Tons)	63.3 (Metric Tons)	75.5 (Metric Tons)

Unit Name : LHC7_H3 Furnace
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 514 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
148855.9 (Metric Tons)	2.81 (Metric Tons)	0.281 (Metric Tons)	70.1 (Metric Tons)	83.6 (Metric Tons)

Unit Name : LHC7_H4 Furnace
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 514 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
110207.6 (Metric Tons)	2.08 (Metric Tons)	0.208 (Metric Tons)	51.9 (Metric Tons)	61.9 (Metric Tons)

Unit Name : LHC8_Furnace 1
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 413 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
1040.6 (Metric Tons)	0.02 (Metric Tons)	0.002 (Metric Tons)	0.5 (Metric Tons)	0.6 (Metric Tons)

Unit Name : LHC8_Furnace 2
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 413 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
880.2 (Metric Tons)	0.02 (Metric Tons)	0.002 (Metric Tons)	0.4 (Metric Tons)	0.5 (Metric Tons)

Unit Name : LHC8_Furnace 4
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 413 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
973.3 (Metric Tons)	0.02 (Metric Tons)	0.002 (Metric Tons)	0.5 (Metric Tons)	0.5 (Metric Tons)

Unit Name : LHC8_Furnace 5
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 413 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
452.1 (Metric Tons)	0.01 (Metric Tons)	0.001 (Metric Tons)	0.2 (Metric Tons)	0.3 (Metric Tons)

Unit Name : LHC8_Furnace 6
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 413 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
1014.3 (Metric Tons)	0.02 (Metric Tons)	0.002 (Metric Tons)	0.5 (Metric Tons)	0.6 (Metric Tons)

Unit Name : SDO_H628 Heater
Unit Type : PRH (Process Heater)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 1.2 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
93.8 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0 (Metric Tons)	0.1 (Metric Tons)

Unit Name : SDO_HDHT Heater
Unit Type : PRH (Process Heater)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 3.3 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
63.9 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)

Unit Name : SDO_HET1 Heater
Unit Type : PRH (Process Heater)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 12.8 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
496.2 (Metric Tons)	0.01 (Metric Tons)	0.001 (Metric Tons)	0.2 (Metric Tons)	0.3 (Metric Tons)

Unit Name : SDO_HET2 Heater
Unit Type : PRH (Process Heater)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 12.8 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
846.6 (Metric Tons)	0.02 (Metric Tons)	0.002 (Metric Tons)	0.4 (Metric Tons)	0.5 (Metric Tons)

Unit Name : SDO_HSBH Heater
Unit Type : PRH (Process Heater)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 6.6 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
225.3 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0.1 (Metric Tons)	0.1 (Metric Tons)

Unit Name : SDO_C-14 ICE
Unit Type : RICE (Reciprocating internal combustion engine)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 7.2 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
263.6 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0.1 (Metric Tons)	0.1 (Metric Tons)

Unit Name : LHC7_FS2 Flare
Unit Type : FLR (Flare)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 14 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
281.8 (Metric Tons)	0.01 (Metric Tons)	0.001 (Metric Tons)	0.1 (Metric Tons)	0.2 (Metric Tons)

Unit Name : LHC8_Ground Flare
Unit Type : FLR (Flare)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 4590 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
568.7 (Metric Tons)	0.01 (Metric Tons)	0.001 (Metric Tons)	0.3 (Metric Tons)	0.3 (Metric Tons)

Unit Name : PWR8_GT81
Unit Type : SCCT (CT (Turbine, simple cycle combustion))
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 1451 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
412748.3 (Metric Tons)	7.78 (Metric Tons)	0.778 (Metric Tons)	194.5 (Metric Tons)	231.8 (Metric Tons)

Unit Name : PWR8_GT82
Unit Type : SCCT (CT (Turbine, simple cycle combustion))
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 1451 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
497526.3 (Metric Tons)	9.38 (Metric Tons)	0.938 (Metric Tons)	234.4 (Metric Tons)	279.4 (Metric Tons)

Unit Name : PWR8_GT83
Unit Type : SCCT (CT (Turbine, simple cycle combustion))
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 1451 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
482085.8 (Metric Tons)	9.09 (Metric Tons)	0.909 (Metric Tons)	227.1 (Metric Tons)	270.8 (Metric Tons)

Unit Name : VER_WGB 500 Boiler
Unit Type : OB (Boiler, other)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 50 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
18648.4 (Metric Tons)	0.35 (Metric Tons)	0.035 (Metric Tons)	8.8 (Metric Tons)	10.5 (Metric Tons)

Unit Name : PWR9_GT96
Unit Type : SCCT (CT (Turbine, simple cycle combustion))
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 1800 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
517111.2 (Metric Tons)	9.75 (Metric Tons)	0.975 (Metric Tons)	243.6 (Metric Tons)	290.4 (Metric Tons)

Unit Name : LHC8_F1 Flare
Unit Type : FLR (Flare)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 142 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
142.2 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0.1 (Metric Tons)	0.1 (Metric Tons)

Unit Name : LHC7_FS1 Flare
Unit Type : FLR (Flare)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 2345 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
161.1 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0.1 (Metric Tons)	0.1 (Metric Tons)

Unit Name : LHC8_Furnace 8
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 292 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
1133.9 (Metric Tons)	0.02 (Metric Tons)	0.002 (Metric Tons)	0.5 (Metric Tons)	0.6 (Metric Tons)

Unit Name : LHC8_TO 1
Unit Type : TODF (Thermal oxidizer, direct fired, no heat recovery)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 15 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
2953.5 (Metric Tons)	0.06 (Metric Tons)	0.006 (Metric Tons)	1.4 (Metric Tons)	1.7 (Metric Tons)

Unit Name : LHC8_Vent Flare
Unit Type : FLR (Flare)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 374 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
28.4 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)

Unit Name : LHC8_Furnace 7
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 413 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
1060.3 (Metric Tons)	0.02 (Metric Tons)	0.002 (Metric Tons)	0.5 (Metric Tons)	0.6 (Metric Tons)

Unit Name : LHC8_Furnace 9
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 310 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
0 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)

Unit Name : LHC8_F902 Flare
Unit Type : FLR (Flare)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 10 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
28.4 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)

Unit Name : SDO_C-13 ICE
Unit Type : RICE (Reciprocating internal combustion engine)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 6.5 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
0 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)

Unit Name : GP-LPFG HEADER AGGREGATE
Unit Type : OCS (Other combustion source)
Unit Description :
Other Unit Name :

Small Unit Aggregation Details:
Use Ivt Indicator: Y
Highest Maximum Rated Heat Input Capacity: 120
Cumulative Maximum Rated Heat Input Capacity: 463

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)
Annual Fossil fuel based CO2 Emissions: 160014 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
160017.7 (Metric Tons)	3.02 (Metric Tons)	0.302 (Metric Tons)	75.4 (Metric Tons)	89.9 (Metric Tons)

Unit Name : GP-TIER I DIESEL ENGINE AGGREGATE
Unit Type : OCS (Other combustion source)
Unit Description :
Other Unit Name :

Small Unit Aggregation Details:
Use Ivt Indicator: Y
Highest Maximum Rated Heat Input Capacity: 1.55
Cumulative Maximum Rated Heat Input Capacity:

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)
Annual Fossil fuel based CO2 Emissions: 26.3 (metric tons)

Tier Fuel Details:

Fuel : Distillate Fuel Oil No. 2
Tier Name : Tier 1 (Equation C-1)
Tier Methodology Start Date : 2019-01-01
Tier Methodology End Date : 2019-12-31

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
26.3 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0 (Metric Tons)	0.1 (Metric Tons)

Unit Name : EOWD_A2500A
Unit Type : RICE (Reciprocating internal combustion engine)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 1.54 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
0.0 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)

Unit Name : EOWD_B2000
Unit Type : RICE (Reciprocating internal combustion engine)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 0.51 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
0.1 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)

Unit Name : USCP_TO 35
Unit Type : TODF (Thermal oxidizer, direct fired, no heat recovery)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 14 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
1415.8 (Metric Tons)	0.03 (Metric Tons)	0.003 (Metric Tons)	0.7 (Metric Tons)	0.8 (Metric Tons)

Unit Name : DPO_F61
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 10 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
2660.2 (Metric Tons)	0.05 (Metric Tons)	0.005 (Metric Tons)	1.3 (Metric Tons)	1.5 (Metric Tons)

Unit Name : DPO_F62
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 10 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
2506.6 (Metric Tons)	0.05 (Metric Tons)	0.005 (Metric Tons)	1.2 (Metric Tons)	1.4 (Metric Tons)

Unit Name : DPO_TO
Unit Type : TODF (Thermal oxidizer, direct fired, no heat recovery)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 6 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
912.4 (Metric Tons)	0.02 (Metric Tons)	0.002 (Metric Tons)	0.4 (Metric Tons)	0.5 (Metric Tons)

Unit Name : CP-PWR9 Boilers
Unit Type : OCS (Other combustion source)
Unit Description :
Other Unit Name :

Common Pipe Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 550
Cumulative Maximum Rated Heat Input Capacity: 2200

Emission Details:
Annual Biogenic CO2 Emissions: 0 (metric tons)
Annual Fossil fuel based CO2 Emissions: 43 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
5.3 (Metric Tons)	0.00 (Metric Tons)	0.000 (Metric Tons)	0 (Metric Tons)	0 (Metric Tons)

Fuel : Hydrogen (Other (gas))
Tier Name : Tier 3 (Equation C-5, gaseous fuel)
Tier Methodology Start Date : 2019-01-01
Tier Methodology End Date : 2019-12-31

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
37.7 (Metric Tons)	()	()	()	()

Unit Name : CP-PDH1 HEATERS
Unit Type : OCS (Other combustion source)
Unit Description :
Other Unit Name :

Common Pipe Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 230
Cumulative Maximum Rated Heat Input Capacity: 920

Emission Details:
Annual Biogenic CO2 Emissions: 0 (metric tons)
Annual Fossil fuel based CO2 Emissions: 168118.8 (metric tons)

Tier Fuel Details:

Fuel : Fuel Gas
Tier Name : Tier 3 (Equation C-5, gaseous fuel)
Tier Methodology Start Date : 2019-01-01
Tier Methodology End Date : 2019-12-31

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
170825.2 (Metric Tons)	14.21 (Metric Tons)	2.841 (Metric Tons)	355.2 (Metric Tons)	846.7 (Metric Tons)

Unit Name : PE5_Furnace 510
Unit Type : F (Furnace)
Unit Description :

Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 73 (mmBtu/hr)

Emission Details:
Annual CO₂ mass emissions from sorbent: 0 (Metric Tons)
Annual Biogenic CO2 Emissions: 0 (metric tons)

Tier Fuel Details:

January	February	March	April	May	June	July	August	September	October	November	December
N	N	N	N	N	N	N	N	N	N	N	N

Fuel Emission Details :

Total CO2 emissions	Total CH4 emissions	Total N2O emissions	Total CH4 emissions CO2e	Total N2O emissions CO2e
2116.8 (Metric Tons)	0.04 (Metric Tons)	0.004 (Metric Tons)	1 (Metric Tons)	1.2 (Metric Tons)

Subpart W: Petroleum and Natural Gas Systems

Gas Information Details

Gas Name	Carbon Dioxide
Gas Quantity	15.8 (Metric Tons)
Own Result?

Gas Name	Methane
Gas Quantity	546.64 (Metric Tons)
Own Result?

Gas Name	Nitrous Oxide
Gas Quantity	0 (Metric Tons)
Own Result?

SubpartWSummaryDetails:

Industry Segment Number	5
Industry Segment Name	Underground natural gas storage [98.230(a)(5)]
Total Reported CO2 Emissions (mt CO2)	15.8
Total CO2e Emissions (mt CO2e)	13681.8
Total Reported CH4 Emissions (mt CH4)	546.64
Total Reported N2O Emissions (mt N2O)	0.000

SubpartWSourceReportingFormRowDetails:

Source Reporting Form	Onshore Production [98.236(aa)(1)]
Required for Selected Industry Segment	No
Source Reporting Form	Facility Overview [98.236(aa)(2-11)]
Required for Selected Industry Segment	Yes
Source Reporting Form	Natural Gas Pneumatic Devices [98.236(b)]
Required for Selected Industry Segment	Yes
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Source Reporting Form	Natural Gas Driven Pneumatic Pumps [98.236(c)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Source Reporting Form	Acid Gas Removal Units [98.236(d)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Source Reporting Form	Dehydrators [98.236(e)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Total Reported N2O Emissions (mt N2O)	0.000
Source Reporting Form	Well Venting for Liquids Unloading [98.236(f)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Source Reporting Form	Completions and Workovers with Hydraulic Fracturing [98.236(g)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Total Reported N2O Emissions (mt N2O)	0.000
Source Reporting Form	Completions and Workovers without Hydraulic Fracturing [98.236(h)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Total Reported N2O Emissions (mt N2O)	0.000
Source Reporting Form	Blowdown Vent Stacks [98.236(i)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Source Reporting Form	Atmospheric Storage Tanks [98.236(j)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Total Reported N2O Emissions (mt N2O)	0.000
Source Reporting Form	Transmission Storage Tanks [98.236(k)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Total Reported N2O Emissions (mt N2O)	0.000
Source Reporting Form	Well Testing [98.236(l)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Total Reported N2O Emissions (mt N2O)	0.000
Source Reporting Form	Associated Gas Venting and Flaring [98.236(m)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Total Reported N2O Emissions (mt N2O)	0.000
Source Reporting Form	Flare Stacks [98.236(n)]
Required for Selected Industry Segment	Yes
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Total Reported N2O Emissions (mt N2O)	0.000
Source Reporting Form	Centrifugal Compressors [98.236(o)]
Required for Selected Industry Segment	Yes
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Source Reporting Form	Reciprocating Compressors [98.236(p)]
Required for Selected Industry Segment	Yes
Total Reported CO2 Emissions (mt CO2)	15.5
Total Reported CH4 Emissions (mt CH4)	537.29
Source Reporting Form	Equipment Leaks Surveys and Population Counts [98.236(q,r)]
Required for Selected Industry Segment	Yes
Total Reported CO2 Emissions (mt CO2)	0.3
Total Reported CH4 Emissions (mt CH4)	9.35
Source Reporting Form	Offshore Petroleum and Natural Gas Production [98.236(s)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Total Reported N2O Emissions (mt N2O)	0.000
Source Reporting Form	Enhanced Oil Recovery Injection Pumps [98.236(w)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Source Reporting Form	Enhanced Oil Recovery Hydrocarbon Liquids [98.236(x)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Source Reporting Form	Combustion Equipment at Onshore Petroleum and Natural Gas Production Facilities, Onshore Petroleum and Natural Gas Gathering and Boosting Facilities, and Natural gas Distribution Facilities [98.236(z)]
Required for Selected Industry Segment	No
Total Reported CO2 Emissions (mt CO2)	0.0
Total Reported CH4 Emissions (mt CH4)	0.00
Total Reported N2O Emissions (mt N2O)	0.000

FacilityOverviewDetails:

FacilityOverviewUndergroundNaturalGasRowDetails:

Quantity of gas injected into storage in the calendar year (thousand standard cubic feet) [98.236(aa)(5)(i)]	354632
Quantity of gas withdrawn from storage in the calendar year (thousand standard cubic feet) [98.236(aa)(5)(ii)]	294855
Total storage capacity (thousand standard cubic feet) [98.236(aa)(5)(iii)]	2003000

PneumaticDeviceVentingDetails:

mt CO2	0.0
mt CH4	0.00
Did the Facility have any continuous high-bleed pneumatic devices subject to reporting under 98.232 [98.236(b)]?	No
Did the Facility have any intermittent bleed pneumatic devices subject to reporting under 98.232 [98.236(b)]?	No
Did the Facility have any continuous low-bleed pneumatic devices subject to reporting under 98.232 [98.236(b)]?	No

PneumaticDeviceTypesRowDetails:

Type of Pneumatic Device	High-bleed Pneumatic Devices
Type of Pneumatic Device	Intermittent Bleed Pneumatic Devices
Type of Pneumatic Device	Low-Bleed Pneumatic Devices

FlareStacksDetails:

mt CO2	0.0
mt CH4	0.00
mt N2O	0.000
Did the facility have flare stacks subject to reporting under 98.232 [98.236(n)]?	No

CentrifugalCompressorsDetails:

mt CO2	0.0
mt CH4	0.00
Did the facility have any centrifugal compressors subject to reporting under 98.232 [98.236(o)]?	No

ReciprocatingCompressorsDetails:

mt CO2	15.5
mt CH4	537.29
Did the facility have any reciprocating compressors subject to reporting under 98.232 [98.236(p)]?	Yes
Were missing data procedures used for any parameters to calculate GHG emissions? [98.235]	No

ReciprocatingCompressorsActivityDataRowDetails:

Unique name or ID for reciprocating compressor [98.236(p)(1)(i)]	Compressor C14
Total time in operating-mode (hours) [98.236(p)(1)(ii)]	1075
Total time in standby-pressurized-mode (hours) [98.236(p)(1)(iii)]	2969
Total time in not-operating-depressurized-mode (hours) [98.236(p)(1)(iv)]	4716
Compressor measured in operating-mode? [98.236(p)(1)(v)]	Yes
Compressor measured in standby-pressurized-mode? [98.236(p)(1)(vi)]	No
Compressor measured in not-operating-depressurized-mode? [98.236(p)(1)(vii)]	Yes
Compressor had blind flanges installed? [98.236(p)(1)(xii)]	Yes
Dates for blind flange installation (mm/dd/yyyy - mm/dd/yyyy) [98.236(p)(1)(xii)]	10/14/2019 - 12/12/2019
Power output of compressor driver (hp) [98.236(p)(1)(xiii)]	1000
Compressor had scheduled depressurized shutdown during reporting year? [98.236(p)(1)(xiv)]	Yes

ReciprocatingCompressorSourceRowDetails:

Unique name or ID for reciprocating compressor [98.236(p)(2)(i)(A)]	Compressor C14
Reciprocating compressor source [98.236(p)(2)(i)(B)]	Blowdown valve
Unique Name or ID for leak or vent [98.236(p)(2)(i)(C)]	Station Vent Stack OPR
Unique name or ID for reciprocating compressor [98.236(p)(2)(i)(A)]	Compressor C14
Reciprocating compressor source [98.236(p)(2)(i)(B)]	Isolation valve
Unique Name or ID for leak or vent [98.236(p)(2)(i)(C)]	Station Vent Stack SHDN
Unique name or ID for reciprocating compressor [98.236(p)(2)(i)(A)]	Compressor C14
Reciprocating compressor source [98.236(p)(2)(i)(B)]	Rod packing
Unique Name or ID for leak or vent [98.236(p)(2)(i)(C)]	C14 Rod Packing Vent

ReciprocatingCompressorsLeakOrVentSampleDataRowDetails:

Unique Name or ID for leak or vent (Specify) [98.236(p)(2)(i)(C)] [98.236(p)(3)(i)(A)]	Station Vent Stack OPR
Measurement date (mm/dd/yyyy) [98.236(p)(3)(i)(B)]	2019-05-06
Measurement method [98.236(p)(3)(i)(C)]	Temporary meter
Measured flow rate (standard cubic feet/hour) [98.236(p)(3)(i)(D)]	4498
Is the measurement location prior to or after commingling with non-compressor emission sources? [98.236(p)(3)(i)(F)]	After commingling
Compressors in “Operating mode”	Compressor C14
Unique Name or ID for leak or vent (Specify) [98.236(p)(2)(i)(C)] [98.236(p)(3)(i)(A)]	Station Vent Stack SHDN
Measurement date (mm/dd/yyyy) [98.236(p)(3)(i)(B)]	2019-05-06
Measurement method [98.236(p)(3)(i)(C)]	Temporary meter
Measured flow rate (standard cubic feet/hour) [98.236(p)(3)(i)(D)]	4267
Is the measurement location prior to or after commingling with non-compressor emission sources? [98.236(p)(3)(i)(F)]	After commingling
Compressors in “Not-operating mode”	Compressor C14
Unique Name or ID for leak or vent (Specify) [98.236(p)(2)(i)(C)] [98.236(p)(3)(i)(A)]	C14 Rod Packing Vent
Measurement date (mm/dd/yyyy) [98.236(p)(3)(i)(B)]	2019-05-06
Measurement method [98.236(p)(3)(i)(C)]	Calibrated bagging
Measured flow rate (standard cubic feet/hour) [98.236(p)(3)(i)(D)]	0
Is the measurement location prior to or after commingling with non-compressor emission sources? [98.236(p)(3)(i)(F)]	Not manifolded
Compressors in “Operating mode”	Compressor C14

ReciprocatingCompressorsEmissionFactorsSampleDataRowDetails:

Compressor Mode [98.236(p)(3)(ii)(A)]	Operating
Compressor Source [98.236(p)(3)(ii)(A)]	Blowdown valve
Compressor mode-source combination reporter emission factor, EFs,m (standard cubic feet per hour) [98.236(p)(3)(ii)(B)]	1515.1333333
Total number of compressors measured in the compressor mode-source combination in current reporting year and preceding two reporting years, Countm [98.236(p)(3)(ii)(C)]	3
Is the reporter emission factor facility-specific or based on all of the reporter's applicable facilities? [98.236(p)(3)(ii)(D)]	Facility-specific
Compressor Mode [98.236(p)(3)(ii)(A)]	Operating
Compressor Source [98.236(p)(3)(ii)(A)]	Rod packing
Compressor mode-source combination reporter emission factor, EFs,m (standard cubic feet per hour) [98.236(p)(3)(ii)(B)]	0.0366667
Total number of compressors measured in the compressor mode-source combination in current reporting year and preceding two reporting years, Countm [98.236(p)(3)(ii)(C)]	3
Is the reporter emission factor facility-specific or based on all of the reporter's applicable facilities? [98.236(p)(3)(ii)(D)]	Facility-specific
Compressor Mode [98.236(p)(3)(ii)(A)]	Standby-pressurized
Compressor Source [98.236(p)(3)(ii)(A)]	Blowdown valve
Compressor mode-source combination reporter emission factor, EFs,m (standard cubic feet per hour) [98.236(p)(3)(ii)(B)]	1515.1333333
Total number of compressors measured in the compressor mode-source combination in current reporting year and preceding two reporting years, Countm [98.236(p)(3)(ii)(C)]	3
Is the reporter emission factor facility-specific or based on all of the reporter's applicable facilities? [98.236(p)(3)(ii)(D)]	Facility-specific
Compressor Mode [98.236(p)(3)(ii)(A)]	Not-operating-depressurized
Compressor Source [98.236(p)(3)(ii)(A)]	Isolation valve
Compressor mode-source combination reporter emission factor, EFs,m (standard cubic feet per hour) [98.236(p)(3)(ii)(B)]	1422.4066667
Total number of compressors measured in the compressor mode-source combination in current reporting year and preceding two reporting years, Countm [98.236(p)(3)(ii)(C)]	3
Is the reporter emission factor facility-specific or based on all of the reporter's applicable facilities? [98.236(p)(3)(ii)(D)]	Facility-specific

ReciprocatingCompressorsLeakOrVentDataRowDetails:

Unique Name or ID for leak or vent [98.236(p)(2)(i)(C)]	Station Vent Stack OPR
Leak or vent for a single compressor source or a manifolded group? [98.236(p)(2)(ii)(A)] [98.236(p)(1)(viii)]	Single
Where are leak or vent emissions released? [98.236(p)(2)(ii)(A)] [98.236(p)(1)(ix) through (xi)]	Atmosphere
Was an "as found" measurement conducted on the leak or vent? [98.236(p)(2)(ii)(B)]	Yes
Were continuous measurements conducted on the leak or vent? [98.236(p)(2)(ii)(C)]	No
CO2 Emissions vented to atmosphere (mt CO2) [98.236(p)(2)(ii)(D)(1)]	4.9095687
CH4 Emissions vented to atmosphere (mt CH4) [98.236(p)(2)(ii)(D)(2)]	170.248163
Unique Name or ID for leak or vent [98.236(p)(2)(i)(C)]	Station Vent Stack SHDN
Leak or vent for a single compressor source or a manifolded group? [98.236(p)(2)(ii)(A)] [98.236(p)(1)(viii)]	Single
Where are leak or vent emissions released? [98.236(p)(2)(ii)(A)] [98.236(p)(1)(ix) through (xi)]	Atmosphere
Was an "as found" measurement conducted on the leak or vent? [98.236(p)(2)(ii)(B)]	Yes
Were continuous measurements conducted on the leak or vent? [98.236(p)(2)(ii)(C)]	No
CO2 Emissions vented to atmosphere (mt CO2) [98.236(p)(2)(ii)(D)(1)]	10.5847885
CH4 Emissions vented to atmosphere (mt CH4) [98.236(p)(2)(ii)(D)(2)]	367.0466573
Unique Name or ID for leak or vent [98.236(p)(2)(i)(C)]	C14 Rod Packing Vent
Leak or vent for a single compressor source or a manifolded group? [98.236(p)(2)(ii)(A)] [98.236(p)(1)(viii)]	Single
Where are leak or vent emissions released? [98.236(p)(2)(ii)(A)] [98.236(p)(1)(ix) through (xi)]	Atmosphere
Was an "as found" measurement conducted on the leak or vent? [98.236(p)(2)(ii)(B)]	Yes
Were continuous measurements conducted on the leak or vent? [98.236(p)(2)(ii)(C)]	No
CO2 Emissions vented to atmosphere (mt CO2) [98.236(p)(2)(ii)(D)(1)]	0
CH4 Emissions vented to atmosphere (mt CH4) [98.236(p)(2)(ii)(D)(2)]	0

OtherEmissionsFromEquipmentLeaksDetails:

mt CO2	0.3
mt CH4	9.35
Did this facility use leak surveys to calculate emissions from equipment leaks in accordance with 98.232 [per 98.236(q)]?	Yes
Did this facility use population counts to calculate emissions from equipment leaks in accordance with 98.232 [per 98.236(r)]?	Yes
Did the facility elect to comply with 98.236(q) according to 98.233(q)(1)(iv) for any components at the facility [per 98.236(q)(1)(iv)]?	Yes
Were missing data procedures used for any parameters to calculate GHG emissions? [98.235]	No
Number of complete equipment leak surveys performed during the calendar year [98.236(q)(1)(i)]	1
Method 21 [98.234(a)(2)]	Yes

UndergroundStorageEmissionsFactorsRowDetails:

Component Type [98.236(q)(2)(i)]	Storage Station, Gas Service - Valve
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	2
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	4380
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0.0752171
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	2.43357
Component Type [98.236(q)(2)(i)]	Storage Station, Gas Service - Connector (other)
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	0
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	0
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	0
Component Type [98.236(q)(2)(i)]	Storage Station, Gas Service - Open-ended Line
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	0
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	0
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	0
Component Type [98.236(q)(2)(i)]	Storage Station, Gas Service - Pressure Relief Valve
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	0
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	0
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	0
Component Type [98.236(q)(2)(i)]	Storage Station, Gas Service - Meter and Instrument
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	0
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	0
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	0
Component Type [98.236(q)(2)(i)]	Storage Station, Gas Service - Other
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	0
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	0
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	0
Component Type [98.236(q)(2)(i)]	Storage Wellheads, Gas Service - Valve
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	0
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	0
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	0
Component Type [98.236(q)(2)(i)]	Storage Wellheads, Gas Service - Connector (other than flanges)
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	0
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	0
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	0
Component Type [98.236(q)(2)(i)]	Storage Wellheads, Gas Service - Flange
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	0
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	0
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	0
Component Type [98.236(q)(2)(i)]	Storage Wellheads, Gas Service - Open-Ended Line
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	0
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	0
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	0
Component Type [98.236(q)(2)(i)]	Storage Wellheads, Gas Service - Pressure Relief Valve
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	0
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	0
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	0
Component Type [98.236(q)(2)(i)]	Storage Wellheads, Gas Service - Other
Total number of surveyed component type identified as leaking, xp [98.236(q)(2)(ii)]	0
Average time the surveyed components are assumed to be leaking and operational, Tp,z (hours) [98.236(q)(2)(iii)]	0
CO2 Emissions (surveyed components identified as leaking only) (mt CO2) [98.236(q)(2)(iv)]	0
CH4 Emissions (surveyed components identified as leaking only) (mt CH4) [98.236(q)(2)(v)]	0

GasEstimatingEmissionsRowDetails:

Emission Source Type (Eq. W-32A) [98.232] [98.233(r)(1)]	Storage wellheads, Gas Service - Valves
Total number of emission source type, Counte [98.236(r)(1)(ii)]	278
Average estimated time that the emission source type was operational in the calendar year, Te (hours) [98.236(r)(1)(iii)]	8760
CO2 Emissions (mt CO2) [98.236(r)(1)(iv)]	0.1409053
CH4 Emissions (mt CH4) [98.236(r)(1)(v)]	4.5588442
Emission Source Type (Eq. W-32A) [98.232] [98.233(r)(1)]	Storage wellheads, Gas Service - Connector
Total number of emission source type, Counte [98.236(r)(1)(ii)]	1334
Average estimated time that the emission source type was operational in the calendar year, Te (hours) [98.236(r)(1)(iii)]	8760
CO2 Emissions (mt CO2) [98.236(r)(1)(iv)]	0.0676143
CH4 Emissions (mt CH4) [98.236(r)(1)(v)]	2.1875892
Emission Source Type (Eq. W-32A) [98.232] [98.233(r)(1)]	Storage wellheads, Gas Service - Open-ended line
Total number of emission source type, Counte [98.236(r)(1)(ii)]	0
Average estimated time that the emission source type was operational in the calendar year, Te (hours) [98.236(r)(1)(iii)]	8760
CO2 Emissions (mt CO2) [98.236(r)(1)(iv)]	0
CH4 Emissions (mt CH4) [98.236(r)(1)(v)]	0
Emission Source Type (Eq. W-32A) [98.232] [98.233(r)(1)]	Storage wellheads, Gas Service - Pressure Relief Valve
Total number of emission source type, Counte [98.236(r)(1)(ii)]	6
Average estimated time that the emission source type was operational in the calendar year, Te (hours) [98.236(r)(1)(iii)]	8760
CO2 Emissions (mt CO2) [98.236(r)(1)(iv)]	0.0051699
CH4 Emissions (mt CH4) [98.236(r)(1)(v)]	0.1672669

Subpart X: Petrochemical Production

CEMS Monitoring Location (CML) Details for Subpart X

Gas Information Details

Gas Name	Carbon Dioxide
Gas Quantity	1,084,533.3 (Metric Tons)
Own Result?

Gas Name	Biogenic Carbon dioxide
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	Methane
Gas Quantity	31.52 (Metric Tons)
Own Result?

Gas Name	Nitrous Oxide
Gas Quantity	0.093 (Metric Tons)
Own Result?

Petrochemical Process Units

Petrochemical process units monitored using the mass balance methodology:

Name or ID:LHC 7 Mass Balance
Description:
Type:Petrochemical process unit
Identify combustion units:GP-LPFG Header Aggregate LHC7_FS1 LHC7_FS2 LHC7_H1 thru H5 Furnaces
AnnualCO2Emissions:50184.0 Metric Tons
Type of petrochemical produced:
Annual quantity of the petrochemical produced:
Annual average carbon content of the wastewater:
Annual average flow of wastewater:
Unit of measure for average flow of wastewater:
Annual mass of carbon released in fugitive emissions not controlled with a combustion device:
Annual mass of carbon released in process vents not controlled with a combustion device:

Feedstocks/Products:

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Vortex
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

February

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

March

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

April

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

May

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

June

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

July

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

August

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

September

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

October

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

November

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

December

Flow meter

ASTM D1945-03

Other (specify)

GC Composition

68 degrees Fahrenheit

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Orifice
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Orifice
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Calibrated Tank Level Sight Glass
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

February

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

March

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

April

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

May

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

June

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

July

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

August

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

September

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

October

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

November

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

December

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Calibrated Tank Level Sight Glass
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

February

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

March

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

April

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

May

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

June

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

July

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

August

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

September

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

October

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

November

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

December

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Calibrated Tank Level Sight Glass
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

February

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

March

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

April

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

May

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

June

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

July

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

August

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

September

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

October

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

November

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

December

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Calibrated Tank Level Sight Glass
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

February

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

March

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

April

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

May

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

June

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

July

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

August

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

September

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

October

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

November

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

December

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Vendor Delivery Amounts
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

February

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

March

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

April

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

May

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

June

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

July

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

August

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

September

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

October

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

November

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

December

Other (specify)

Vendor Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Orifice
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Coriolis
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

February

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

March

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

April

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

May

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

June

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

July

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

August

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

September

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

October

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

November

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

December

Flow meter

ASTM D1945-03

Other (specify)

GC Analysis

68 degrees Fahrenheit

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Orifice
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Other (specify)

95% Pure Rule

February

Flow meter

Other (specify)

95% Pure Rule

March

Flow meter

Other (specify)

95% Pure Rule

April

Flow meter

Other (specify)

95% Pure Rule

May

Flow meter

Other (specify)

95% Pure Rule

June

Flow meter

Other (specify)

95% Pure Rule

July

Flow meter

Other (specify)

95% Pure Rule

August

Flow meter

Other (specify)

95% Pure Rule

September

Flow meter

Other (specify)

95% Pure Rule

October

Flow meter

Other (specify)

95% Pure Rule

November

Flow meter

Other (specify)

95% Pure Rule

December

Flow meter

Other (specify)

95% Pure Rule

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Orifice
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Coriolis
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Orifice
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Orifice
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

February

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

March

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

April

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

May

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

June

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

July

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

August

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

September

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

October

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

November

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

December

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

Name or ID:LHC 8 Mass Balance
Description:
Type:Petrochemical process unit
Identify combustion units:GP-LPFG Header Aggregate LHC8_F1 Flare LHC8_F902 Flare LHC8_Ground Flare LHC8_Vent Flare LHC8_TO1 LHC8_Furnace 1 thru Furnace 10 CP-PDH1 Heaters
AnnualCO2Emissions:1025056.5 Metric Tons
Type of petrochemical produced:
Annual quantity of the petrochemical produced:
Annual average carbon content of the wastewater:
Annual average flow of wastewater:
Unit of measure for average flow of wastewater:
Annual mass of carbon released in fugitive emissions not controlled with a combustion device:
Annual mass of carbon released in process vents not controlled with a combustion device:

Feedstocks/Products:

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Coriolis
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Venturi
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Venturi
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Venturi
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Coriolis
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

ASTM D5291-02 (Reapproved 2007)

February

Flow meter

ASTM D5291-02 (Reapproved 2007)

March

Flow meter

ASTM D5291-02 (Reapproved 2007)

April

Flow meter

ASTM D5291-02 (Reapproved 2007)

May

Flow meter

ASTM D5291-02 (Reapproved 2007)

June

Flow meter

ASTM D5291-02 (Reapproved 2007)

July

Flow meter

ASTM D5291-02 (Reapproved 2007)

August

Flow meter

ASTM D5291-02 (Reapproved 2007)

September

Flow meter

ASTM D5291-02 (Reapproved 2007)

October

Flow meter

ASTM D5291-02 (Reapproved 2007)

November

Flow meter

ASTM D5291-02 (Reapproved 2007)

December

Flow meter

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Coriolis
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Coriolis
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

ASTM D5291-02 (Reapproved 2007)

February

Flow meter

ASTM D5291-02 (Reapproved 2007)

March

Flow meter

ASTM D5291-02 (Reapproved 2007)

April

Flow meter

ASTM D5291-02 (Reapproved 2007)

May

Flow meter

ASTM D5291-02 (Reapproved 2007)

June

Flow meter

ASTM D5291-02 (Reapproved 2007)

July

Flow meter

ASTM D5291-02 (Reapproved 2007)

August

Flow meter

ASTM D5291-02 (Reapproved 2007)

September

Flow meter

ASTM D5291-02 (Reapproved 2007)

October

Flow meter

ASTM D5291-02 (Reapproved 2007)

November

Flow meter

ASTM D5291-02 (Reapproved 2007)

December

Flow meter

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Ultrasonic
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

ASTM D5291-02 (Reapproved 2007)

February

Flow meter

ASTM D5291-02 (Reapproved 2007)

March

Flow meter

ASTM D5291-02 (Reapproved 2007)

April

Flow meter

ASTM D5291-02 (Reapproved 2007)

May

Flow meter

ASTM D5291-02 (Reapproved 2007)

June

Flow meter

ASTM D5291-02 (Reapproved 2007)

July

Flow meter

ASTM D5291-02 (Reapproved 2007)

August

Flow meter

ASTM D5291-02 (Reapproved 2007)

September

Flow meter

ASTM D5291-02 (Reapproved 2007)

October

Flow meter

ASTM D5291-02 (Reapproved 2007)

November

Flow meter

ASTM D5291-02 (Reapproved 2007)

December

Flow meter

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock:
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

February

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

March

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

April

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

May

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

June

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

July

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

August

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

September

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

October

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

November

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

December

Other (specify)

Monthly Delivery Amounts

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Calibrated Sight Glass
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

February

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

March

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

April

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

May

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

June

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

July

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

August

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

September

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

October

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

November

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

December

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Calibrated Sight Glass
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

February

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

March

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

April

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

May

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

June

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

July

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

August

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

September

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

October

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

November

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

December

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Calibrated sight glass
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

February

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

March

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

April

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

May

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

June

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

July

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

August

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

September

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

October

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

November

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

December

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Calibrated sight glass
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

February

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

March

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

April

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

May

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

June

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

July

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

August

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

September

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

October

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

November

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

December

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: calibrated sight glass
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

February

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

March

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

April

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

May

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

June

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

July

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

August

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

September

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

October

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

November

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

December

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Calibration Sight Glass
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

February

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

March

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

April

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

May

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

June

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

July

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

August

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

September

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

October

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

November

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

December

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Ultrasonic
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

February

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

March

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

April

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

May

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

June

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

July

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

August

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

September

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

October

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

November

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

December

Flow meter

ASTM D1945-03

Other (specify)

GC Composition analysis

68 degrees Fahrenheit

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Calibrated Sight Glass
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

February

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

March

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

April

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

May

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

June

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

July

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

August

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

September

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

October

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

November

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

December

Tank level measurements

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Coriolis
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Coriolis
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

ASTM D5291-02 (Reapproved 2007)

February

Flow meter

ASTM D5291-02 (Reapproved 2007)

March

Flow meter

ASTM D5291-02 (Reapproved 2007)

April

Flow meter

ASTM D5291-02 (Reapproved 2007)

May

Flow meter

ASTM D5291-02 (Reapproved 2007)

June

Flow meter

ASTM D5291-02 (Reapproved 2007)

July

Flow meter

ASTM D5291-02 (Reapproved 2007)

August

Flow meter

ASTM D5291-02 (Reapproved 2007)

September

Flow meter

ASTM D5291-02 (Reapproved 2007)

October

Flow meter

ASTM D5291-02 (Reapproved 2007)

November

Flow meter

ASTM D5291-02 (Reapproved 2007)

December

Flow meter

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Venturi
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

February

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

March

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

April

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

May

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

June

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

July

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

August

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

September

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

October

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

November

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

December

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Venturi
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Venturi
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

February

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

March

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

April

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

May

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

June

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

July

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

August

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

September

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

October

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

November

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

December

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Orifice
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Other (specify)

95% Rule

February

Flow meter

Other (specify)

95% Rule

March

Flow meter

Other (specify)

95% Rule

April

Flow meter

Other (specify)

95% Rule

May

Flow meter

Other (specify)

95% Rule

June

Flow meter

Other (specify)

95% Rule

July

Flow meter

Other (specify)

95% Rule

August

Flow meter

Other (specify)

95% Rule

September

Flow meter

Other (specify)

95% Rule

October

Flow meter

Other (specify)

95% Rule

November

Flow meter

Other (specify)

95% Rule

December

Flow meter

Other (specify)

95% Rule

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Orifice
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Coriolis
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

ASTM D5291-02 (Reapproved 2007)

February

Flow meter

ASTM D5291-02 (Reapproved 2007)

March

Flow meter

ASTM D5291-02 (Reapproved 2007)

April

Flow meter

ASTM D5291-02 (Reapproved 2007)

May

Flow meter

ASTM D5291-02 (Reapproved 2007)

June

Flow meter

ASTM D5291-02 (Reapproved 2007)

July

Flow meter

ASTM D5291-02 (Reapproved 2007)

August

Flow meter

ASTM D5291-02 (Reapproved 2007)

September

Flow meter

ASTM D5291-02 (Reapproved 2007)

October

Flow meter

ASTM D5291-02 (Reapproved 2007)

November

Flow meter

ASTM D5291-02 (Reapproved 2007)

December

Flow meter

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Wedge Meter
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

ASTM D5291-02 (Reapproved 2007)

February

Flow meter

ASTM D5291-02 (Reapproved 2007)

March

Flow meter

ASTM D5291-02 (Reapproved 2007)

April

Flow meter

ASTM D5291-02 (Reapproved 2007)

May

Flow meter

ASTM D5291-02 (Reapproved 2007)

June

Flow meter

ASTM D5291-02 (Reapproved 2007)

July

Flow meter

ASTM D5291-02 (Reapproved 2007)

August

Flow meter

ASTM D5291-02 (Reapproved 2007)

September

Flow meter

ASTM D5291-02 (Reapproved 2007)

October

Flow meter

ASTM D5291-02 (Reapproved 2007)

November

Flow meter

ASTM D5291-02 (Reapproved 2007)

December

Flow meter

ASTM D5291-02 (Reapproved 2007)

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Coriolis
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

February

Flow meter

Chromatographic analysis

March

Flow meter

Chromatographic analysis

April

Flow meter

Chromatographic analysis

May

Flow meter

Chromatographic analysis

June

Flow meter

Chromatographic analysis

July

Flow meter

Chromatographic analysis

August

Flow meter

Chromatographic analysis

September

Flow meter

Chromatographic analysis

October

Flow meter

Chromatographic analysis

November

Flow meter

Chromatographic analysis

December

Flow meter

Chromatographic analysis

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Orifice
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

February

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

March

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

April

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

May

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

June

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

July

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

August

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

September

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

October

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

November

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

December

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Venturi
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

February

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

March

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

April

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

May

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

June

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

July

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

August

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

September

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

October

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

November

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

December

Flow meter

Other (specify)

95% Rule

Calculated based on chemical formula and atomic weights

68 degrees Fahrenheit

Type:
State of Feedstock or product:
Identify each method (i.e., method number, title or other description) used to determine the flow or mass of each carbon-containing product or feedstock: Venturi
Annual quantity of feedstock or product:
If applicable, dates for each process change that reduced the composition to less than 99.5%:

Month

Volume for month based on missing data procedure

Volume measurement method

Other volume measurement method

Carbon content or composition for month based on missing data procedure

Carbon content or composition determination method

Specify the practice

Other Method

Name or title of the alternative carbon content determination method

Explanation as to why an alternative carbon content determination method was needed

File name of the copy of the alternative carbon content determination method

Molecular weight for month based on missing data procedure, if applicable

Molecular weight determination method, if applicable

Other method

Name or title of the alternative molecular weight determination method

Explanation as to why an alternative molecular weight determination method was needed

File name of the copy of the alternative molecular weight determination method

Temperature at which volume was measured

January

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

February

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

March

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

April

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

May

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

June

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

July

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

August

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

September

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

October

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

November

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

December

Flow meter

Chromatographic analysis

Other (specify)

GC Composition Analysis

68 degrees Fahrenheit

Petrochemical process units monitored using the ethylene combustion methodology:

Name or ID:LHC9 Alternative Method
Description:
Type:Petrochemical process unit
Type of petrochemical produced:Ethylene
Annual quantity of ethylene produced:

Subpart C stationary combustion units

The unit name or identifier of Subpart C stationary combustion unit	The fraction of the total emissions attributable to the ethylene process unit
CP-LHC9 FURNACES	0.017
LHC9 OC2 TOX	0.233

Carbon-containing feedstocks

The type of carbon-containing feedstock fed to the ethylene process unit	The annual quantity of the carbon-containing feedstock (Metric Tons)

Flare Gas Details

Name or ID: LHC9 LP FLARE
Description:
Type: Flare
Is the flare serviced by a flare gas recovery system ? N
Type of flare: Air-assisted
Other Flare type:

Flare service type: Unit flare
Other Flare service type:

Basis for the fraction of carbon in the flare gas contributed by methane value: Chromatographic analysis: manufacturer's instructions
Other Basis for the fraction of carbon in the flare gas contributed by methane value:

Emissions Details

CO2 Emissions Calculation Method: 98.253(b)(1)(ii)(A) - Equation Y-1a Gas Composition Monitored

Name	Value	Own Result?
CO2Emissions	2013.5 (Metric Tons)	N

Name	Value	Own Result?
CH4Emissions	8.47 (Metric Tons)	N

Name	Value	Own Result?
N2OEmissions	0.020 (Metric Tons)	N

Y1a Equation Details

Were flare gas data used as inputs to Equation Y-1a collected on a mass or volumetric basis: Volumetric basis
Frequency of measurement data: Daily
Annual volume of flare gas combusted: 49501935.88 scf
Specific consensus-based standard method or describe the procedure specified by the flow meter manufacturer: Annual periodic in-situ three point verification by testing sound and gas velocity against theoretical sound and gas velocity.
Number of days missing data procedures were used for annual volume of flare gas combusted: 0
Annual average molecular weight: 18.6 kg/kg-mole
Method(s) used to determine the molecular weight of the flare gas:

Chromatographic analysis: manufacturer's instructions

Number of days missing data procedures were used for annual average molecular weight of the flare gas: 0
Annual average carbon content of the flare gas: 0.56 decimal fraction; kg carbon/kg flare gas
Method(s) used to determine the carbon content of the flare gas:

Chromatographic analysis: manufacturer's instructions

Number of days missing data procedures were used for average carbon content of the flare gas: 0

Name or ID: LHC9 MPG FLARE
Description:
Type: Flare
Is the flare serviced by a flare gas recovery system ? N
Type of flare: Air-assisted
Other Flare type:

Flare service type: Unit flare
Other Flare service type:

Basis for the fraction of carbon in the flare gas contributed by methane value: Chromatographic analysis: manufacturer's instructions
Other Basis for the fraction of carbon in the flare gas contributed by methane value:

Emissions Details

CO2 Emissions Calculation Method: 98.253(b)(1)(ii)(A) - Equation Y-1a Gas Composition Monitored

Name	Value	Own Result?
CO2Emissions	7279.3 (Metric Tons)	N

Name	Value	Own Result?
CH4Emissions	23.05 (Metric Tons)	N

Name	Value	Own Result?
N2OEmissions	0.073 (Metric Tons)	N

Y1a Equation Details

Were flare gas data used as inputs to Equation Y-1a collected on a mass or volumetric basis: Volumetric basis
Frequency of measurement data: Daily
Annual volume of flare gas combusted: 204138552.17 scf
Specific consensus-based standard method or describe the procedure specified by the flow meter manufacturer: Annual periodic in-situ three point verification by testing sound and gas velocity against theoretical sound and gas velocity.
Number of days missing data procedures were used for annual volume of flare gas combusted: 0
Annual average molecular weight: 20.24 kg/kg-mole
Method(s) used to determine the molecular weight of the flare gas:

Chromatographic analysis: manufacturer's instructions

Number of days missing data procedures were used for annual average molecular weight of the flare gas: 0
Annual average carbon content of the flare gas: 0.42 decimal fraction; kg carbon/kg flare gas
Method(s) used to determine the carbon content of the flare gas:

Chromatographic analysis: manufacturer's instructions

Number of days missing data procedures were used for average carbon content of the flare gas: 0

Subpart DD: Electrical Transmission and Distribution Equipment Use

Gas Information Details

Gas Name	Sulfur hexafluoride
Gas CAS Registry Number	2551-62-4
Gas Linear Chemical Formula	SF6
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	PFC-218 (Perfluoropropane)
Gas CAS Registry Number	76-19-7
Gas Linear Chemical Formula	C3F8
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	PFC-3-1-10 (Perfluorobutane)
Gas CAS Registry Number	355-25-9
Gas Linear Chemical Formula	C4F10
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	Perfluorocyclopropane
Gas CAS Registry Number	931-91-9
Gas Linear Chemical Formula	C-C3F6
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	PFC-9-1-18
Gas CAS Registry Number	306-94-5
Gas Linear Chemical Formula	C10F18
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	PFC-14 (Perfluoromethane)
Gas CAS Registry Number	75-73-0
Gas Linear Chemical Formula	CF4
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	PFC-4-1-12 (Perfluoropentane)
Gas CAS Registry Number	678-26-2
Gas Linear Chemical Formula	C5F12
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	PFC-116 (Perfluoroethane)
Gas CAS Registry Number	76-16-4
Gas Linear Chemical Formula	C2F6
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	PFC-5-1-14 (Perfluorohexane)
Gas CAS Registry Number	355-42-0 (a)
Gas Linear Chemical Formula	C6F14
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	Perfluorocyclobutane
Gas CAS Registry Number	115-25-3
Gas Linear Chemical Formula	C-C4F8
Gas Quantity	0 (Metric Tons)
Own Result?

SubpartDDSummaryDetails:

Length of transmission lines carrying voltages above 35 kilovolts (miles) [98.306(b)]	28.22
Were missing data methods used for the length of transmission lines carrying voltages above 35 kilovolts [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Length of distribution lines carrying voltages at or below 35 kilovolts (miles) [98.306(c)]	400
Were missing data methods used for the length of distribution lines carrying voltages at or below 35 kilovolts [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]

FacilityTerritoryLiesRowDetails:

State(s) or territory in which the facility lies [98.306(m)]

Texas

GHGDDSpecificInformationDetails:

MissingDataMethodsForEachApplicableGasRowDetails:

SF6 or PFC	Sulfur hexafluoride
Select whether the following GHGs are estimated for this facility [§98.3(c)(4)]	Yes
Beginning Nameplate Capacity, excluding hermetically sealed-pressure switchgear (pounds) [98.306(a)(1)]	24703.5
Were missing data methods used for nameplate capacity of new hermetically sealed-pressure switchgear during the year? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for nameplate capacity of new equipment other than hermetically sealed-pressure switchgear during the year? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the nameplate capacity of retired hermetically sealed-pressure switchgear during the year? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for nameplate capacity of retired equipment other than hermetically sealed-pressure switchgear during the year? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the number of new hermetically sealed-pressure switchgear? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the number of new equipment other than hermetically sealed-pressure switchgear? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the number of retired hermetically sealed-pressure switchgear? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the number of retired equipment other than hermetically sealed-pressure switchgear? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the quantity of the GHG stored in containers, but not in energized equipment, at the beginning of the year? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the quantity of the GHG stored in containers, but not in energized equipment, at the end of the year? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the quantity of the GHG purchased in bulk from chemical producers or distributors? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the quantity of the GHG purchased from equipment manufacturers or distributors with or inside equipment, including hermetically sealed-pressure switchgear? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the quantity of the GHG returned to facility after off-site recycling? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the quantity of the GHG in bulk and contained in equipment sold to other entities? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the quantity of the GHG returned to suppliers? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the quantity of the GHG sent off-site for recycling? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
Were missing data methods used for the quantity of the GHG sent off-site for destruction? [98.3(c)(8)]	No
If yes, report the reason the data were missing [98.3(c)(8)]
If yes, report the method used for estimating missing data [98.3(c)(8)]
SF6 or PFC	PFC-14 (Perfluoromethane)
Select whether the following GHGs are estimated for this facility [§98.3(c)(4)]
SF6 or PFC	PFC-116 (Perfluoroethane)
Select whether the following GHGs are estimated for this facility [§98.3(c)(4)]
SF6 or PFC	PFC-218 (Perfluoropropane)
Select whether the following GHGs are estimated for this facility [§98.3(c)(4)]
SF6 or PFC	Perfluorocyclopropane
Select whether the following GHGs are estimated for this facility [§98.3(c)(4)]
SF6 or PFC	PFC-3-1-10 (Perfluorobutane)
Select whether the following GHGs are estimated for this facility [§98.3(c)(4)]
SF6 or PFC	Perfluorocyclobutane
Select whether the following GHGs are estimated for this facility [§98.3(c)(4)]
SF6 or PFC	PFC-4-1-12 (Perfluoropentane)
Select whether the following GHGs are estimated for this facility [§98.3(c)(4)]
SF6 or PFC	PFC-5-1-14 (Perfluorohexane)
Select whether the following GHGs are estimated for this facility [§98.3(c)(4)]
SF6 or PFC	PFC-9-1-18
Select whether the following GHGs are estimated for this facility [§98.3(c)(4)]

CalculateDecreaseInSF6AndPFCRowDetails:

SF6 or PFC	Sulfur hexafluoride
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the beginning of the year [98.306(d)]	165
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the end of the year [98.306(e)]	165
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-14 (Perfluoromethane)
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the beginning of the year [98.306(d)]
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the end of the year [98.306(e)]
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-116 (Perfluoroethane)
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the beginning of the year [98.306(d)]
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the end of the year [98.306(e)]
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-218 (Perfluoropropane)
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the beginning of the year [98.306(d)]
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the end of the year [98.306(e)]
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	Perfluorocyclopropane
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the beginning of the year [98.306(d)]
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the end of the year [98.306(e)]
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-3-1-10 (Perfluorobutane)
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the beginning of the year [98.306(d)]
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the end of the year [98.306(e)]
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	Perfluorocyclobutane
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the beginning of the year [98.306(d)]
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the end of the year [98.306(e)]
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-4-1-12 (Perfluoropentane)
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the beginning of the year [98.306(d)]
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the end of the year [98.306(e)]
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-5-1-14 (Perfluorohexane)
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the beginning of the year [98.306(d)]
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the end of the year [98.306(e)]
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-9-1-18
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the beginning of the year [98.306(d)]
Pounds of SF6 or PFC stored in containers, but not in energized equipment, at the end of the year [98.306(e)]
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)

CalculateAcquisitionsOfSF6AndPFCRowDetails:

SF6 or PFC	Sulfur hexafluoride
Pounds of SF6 or PFC purchased from chemical producers or distributors in bulk [98.306(f)]	0
Pounds of SF6 or PFC purchased from equipment manufacturers or distributors with or inside equipment, including hermetically sealed-pressure switchgear [98.306(g)]	507
Pounds of SF6 or PFC returned to facility after off-site recycling [98.306(h)]	0
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	507 (N)
SF6 or PFC	PFC-14 (Perfluoromethane)
Pounds of SF6 or PFC purchased from chemical producers or distributors in bulk [98.306(f)]
Pounds of SF6 or PFC purchased from equipment manufacturers or distributors with or inside equipment, including hermetically sealed-pressure switchgear [98.306(g)]
Pounds of SF6 or PFC returned to facility after off-site recycling [98.306(h)]
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-116 (Perfluoroethane)
Pounds of SF6 or PFC purchased from chemical producers or distributors in bulk [98.306(f)]
Pounds of SF6 or PFC purchased from equipment manufacturers or distributors with or inside equipment, including hermetically sealed-pressure switchgear [98.306(g)]
Pounds of SF6 or PFC returned to facility after off-site recycling [98.306(h)]
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-218 (Perfluoropropane)
Pounds of SF6 or PFC purchased from chemical producers or distributors in bulk [98.306(f)]
Pounds of SF6 or PFC purchased from equipment manufacturers or distributors with or inside equipment, including hermetically sealed-pressure switchgear [98.306(g)]
Pounds of SF6 or PFC returned to facility after off-site recycling [98.306(h)]
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	Perfluorocyclopropane
Pounds of SF6 or PFC purchased from chemical producers or distributors in bulk [98.306(f)]
Pounds of SF6 or PFC purchased from equipment manufacturers or distributors with or inside equipment, including hermetically sealed-pressure switchgear [98.306(g)]
Pounds of SF6 or PFC returned to facility after off-site recycling [98.306(h)]
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-3-1-10 (Perfluorobutane)
Pounds of SF6 or PFC purchased from chemical producers or distributors in bulk [98.306(f)]
Pounds of SF6 or PFC purchased from equipment manufacturers or distributors with or inside equipment, including hermetically sealed-pressure switchgear [98.306(g)]
Pounds of SF6 or PFC returned to facility after off-site recycling [98.306(h)]
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	Perfluorocyclobutane
Pounds of SF6 or PFC purchased from chemical producers or distributors in bulk [98.306(f)]
Pounds of SF6 or PFC purchased from equipment manufacturers or distributors with or inside equipment, including hermetically sealed-pressure switchgear [98.306(g)]
Pounds of SF6 or PFC returned to facility after off-site recycling [98.306(h)]
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-4-1-12 (Perfluoropentane)
Pounds of SF6 or PFC purchased from chemical producers or distributors in bulk [98.306(f)]
Pounds of SF6 or PFC purchased from equipment manufacturers or distributors with or inside equipment, including hermetically sealed-pressure switchgear [98.306(g)]
Pounds of SF6 or PFC returned to facility after off-site recycling [98.306(h)]
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-5-1-14 (Perfluorohexane)
Pounds of SF6 or PFC purchased from chemical producers or distributors in bulk [98.306(f)]
Pounds of SF6 or PFC purchased from equipment manufacturers or distributors with or inside equipment, including hermetically sealed-pressure switchgear [98.306(g)]
Pounds of SF6 or PFC returned to facility after off-site recycling [98.306(h)]
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-9-1-18
Pounds of SF6 or PFC purchased from chemical producers or distributors in bulk [98.306(f)]
Pounds of SF6 or PFC purchased from equipment manufacturers or distributors with or inside equipment, including hermetically sealed-pressure switchgear [98.306(g)]
Pounds of SF6 or PFC returned to facility after off-site recycling [98.306(h)]
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)

CalculateDisbursementsOfSF6AndPFCRowDetails:

SF6 or PFC	Sulfur hexafluoride
Pounds of SF6 or PFC in bulk and contained in equipment that is sold to other entities [98.306(i)]	0
Pounds of SF6 or PFC returned to suppliers [98.306(j)]	0
Pounds of SF6 or PFC sent off-site for recycling [98.306(k)]	0
Pounds of SF6 or PFC sent off-site for destruction [98.306(l)]	0
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-14 (Perfluoromethane)
Pounds of SF6 or PFC in bulk and contained in equipment that is sold to other entities [98.306(i)]
Pounds of SF6 or PFC returned to suppliers [98.306(j)]
Pounds of SF6 or PFC sent off-site for recycling [98.306(k)]
Pounds of SF6 or PFC sent off-site for destruction [98.306(l)]
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-116 (Perfluoroethane)
Pounds of SF6 or PFC in bulk and contained in equipment that is sold to other entities [98.306(i)]
Pounds of SF6 or PFC returned to suppliers [98.306(j)]
Pounds of SF6 or PFC sent off-site for recycling [98.306(k)]
Pounds of SF6 or PFC sent off-site for destruction [98.306(l)]
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-218 (Perfluoropropane)
Pounds of SF6 or PFC in bulk and contained in equipment that is sold to other entities [98.306(i)]
Pounds of SF6 or PFC returned to suppliers [98.306(j)]
Pounds of SF6 or PFC sent off-site for recycling [98.306(k)]
Pounds of SF6 or PFC sent off-site for destruction [98.306(l)]
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	Perfluorocyclopropane
Pounds of SF6 or PFC in bulk and contained in equipment that is sold to other entities [98.306(i)]
Pounds of SF6 or PFC returned to suppliers [98.306(j)]
Pounds of SF6 or PFC sent off-site for recycling [98.306(k)]
Pounds of SF6 or PFC sent off-site for destruction [98.306(l)]
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-3-1-10 (Perfluorobutane)
Pounds of SF6 or PFC in bulk and contained in equipment that is sold to other entities [98.306(i)]
Pounds of SF6 or PFC returned to suppliers [98.306(j)]
Pounds of SF6 or PFC sent off-site for recycling [98.306(k)]
Pounds of SF6 or PFC sent off-site for destruction [98.306(l)]
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	Perfluorocyclobutane
Pounds of SF6 or PFC in bulk and contained in equipment that is sold to other entities [98.306(i)]
Pounds of SF6 or PFC returned to suppliers [98.306(j)]
Pounds of SF6 or PFC sent off-site for recycling [98.306(k)]
Pounds of SF6 or PFC sent off-site for destruction [98.306(l)]
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-4-1-12 (Perfluoropentane)
Pounds of SF6 or PFC in bulk and contained in equipment that is sold to other entities [98.306(i)]
Pounds of SF6 or PFC returned to suppliers [98.306(j)]
Pounds of SF6 or PFC sent off-site for recycling [98.306(k)]
Pounds of SF6 or PFC sent off-site for destruction [98.306(l)]
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-5-1-14 (Perfluorohexane)
Pounds of SF6 or PFC in bulk and contained in equipment that is sold to other entities [98.306(i)]
Pounds of SF6 or PFC returned to suppliers [98.306(j)]
Pounds of SF6 or PFC sent off-site for recycling [98.306(k)]
Pounds of SF6 or PFC sent off-site for destruction [98.306(l)]
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-9-1-18
Pounds of SF6 or PFC in bulk and contained in equipment that is sold to other entities [98.306(i)]
Pounds of SF6 or PFC returned to suppliers [98.306(j)]
Pounds of SF6 or PFC sent off-site for recycling [98.306(k)]
Pounds of SF6 or PFC sent off-site for destruction [98.306(l)]
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)

CalculateNetIncreaseInTotalNameplateCapacityRowDetails:

SF6 or PFC	Sulfur hexafluoride
Nameplate Capacity of new hermetically sealed-pressure switchgear (pounds) [98.306(a)(2)]	0
Nameplate Capacity of new equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(3)]	507
Nameplate Capacity of retired hermetically sealed-pressure switchgear (pounds) [98.306(a)(4)]	0
Nameplate Capacity of retired equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(5)]	0
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	507 (N)
SF6 or PFC	PFC-14 (Perfluoromethane)
Nameplate Capacity of new hermetically sealed-pressure switchgear (pounds) [98.306(a)(2)]
Nameplate Capacity of new equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(3)]
Nameplate Capacity of retired hermetically sealed-pressure switchgear (pounds) [98.306(a)(4)]
Nameplate Capacity of retired equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(5)]
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-116 (Perfluoroethane)
Nameplate Capacity of new hermetically sealed-pressure switchgear (pounds) [98.306(a)(2)]
Nameplate Capacity of new equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(3)]
Nameplate Capacity of retired hermetically sealed-pressure switchgear (pounds) [98.306(a)(4)]
Nameplate Capacity of retired equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(5)]
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-218 (Perfluoropropane)
Nameplate Capacity of new hermetically sealed-pressure switchgear (pounds) [98.306(a)(2)]
Nameplate Capacity of new equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(3)]
Nameplate Capacity of retired hermetically sealed-pressure switchgear (pounds) [98.306(a)(4)]
Nameplate Capacity of retired equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(5)]
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	Perfluorocyclopropane
Nameplate Capacity of new hermetically sealed-pressure switchgear (pounds) [98.306(a)(2)]
Nameplate Capacity of new equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(3)]
Nameplate Capacity of retired hermetically sealed-pressure switchgear (pounds) [98.306(a)(4)]
Nameplate Capacity of retired equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(5)]
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-3-1-10 (Perfluorobutane)
Nameplate Capacity of new hermetically sealed-pressure switchgear (pounds) [98.306(a)(2)]
Nameplate Capacity of new equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(3)]
Nameplate Capacity of retired hermetically sealed-pressure switchgear (pounds) [98.306(a)(4)]
Nameplate Capacity of retired equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(5)]
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	Perfluorocyclobutane
Nameplate Capacity of new hermetically sealed-pressure switchgear (pounds) [98.306(a)(2)]
Nameplate Capacity of new equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(3)]
Nameplate Capacity of retired hermetically sealed-pressure switchgear (pounds) [98.306(a)(4)]
Nameplate Capacity of retired equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(5)]
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-4-1-12 (Perfluoropentane)
Nameplate Capacity of new hermetically sealed-pressure switchgear (pounds) [98.306(a)(2)]
Nameplate Capacity of new equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(3)]
Nameplate Capacity of retired hermetically sealed-pressure switchgear (pounds) [98.306(a)(4)]
Nameplate Capacity of retired equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(5)]
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-5-1-14 (Perfluorohexane)
Nameplate Capacity of new hermetically sealed-pressure switchgear (pounds) [98.306(a)(2)]
Nameplate Capacity of new equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(3)]
Nameplate Capacity of retired hermetically sealed-pressure switchgear (pounds) [98.306(a)(4)]
Nameplate Capacity of retired equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(5)]
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)
SF6 or PFC	PFC-9-1-18
Nameplate Capacity of new hermetically sealed-pressure switchgear (pounds) [98.306(a)(2)]
Nameplate Capacity of new equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(3)]
Nameplate Capacity of retired hermetically sealed-pressure switchgear (pounds) [98.306(a)(4)]
Nameplate Capacity of retired equipment other than hermetically sealed-pressure switchgear (pounds) [98.306(a)(5)]
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] --- Reported Value (User Override? (Y/N))	0 (N)

Sf6PfcEquipmentCategoriesRowDetails:

SF6 or PFC	Sulfur hexafluoride
New hermetically sealed-pressure switchgear [98.306(n)(1)]	0
New equipment other than hermetically sealed-pressure switchgear [98.306(n)(2)]	1
Retired hermetically sealed-pressure switchgear [98.306(n)(3)]	0
Retired equipment other than hermetically sealed-pressure switchgear [98.306(n)(4)]	0
SF6 or PFC	PFC-14 (Perfluoromethane)
New hermetically sealed-pressure switchgear [98.306(n)(1)]
New equipment other than hermetically sealed-pressure switchgear [98.306(n)(2)]
Retired hermetically sealed-pressure switchgear [98.306(n)(3)]
Retired equipment other than hermetically sealed-pressure switchgear [98.306(n)(4)]
SF6 or PFC	PFC-116 (Perfluoroethane)
New hermetically sealed-pressure switchgear [98.306(n)(1)]
New equipment other than hermetically sealed-pressure switchgear [98.306(n)(2)]
Retired hermetically sealed-pressure switchgear [98.306(n)(3)]
Retired equipment other than hermetically sealed-pressure switchgear [98.306(n)(4)]
SF6 or PFC	PFC-218 (Perfluoropropane)
New hermetically sealed-pressure switchgear [98.306(n)(1)]
New equipment other than hermetically sealed-pressure switchgear [98.306(n)(2)]
Retired hermetically sealed-pressure switchgear [98.306(n)(3)]
Retired equipment other than hermetically sealed-pressure switchgear [98.306(n)(4)]
SF6 or PFC	Perfluorocyclopropane
New hermetically sealed-pressure switchgear [98.306(n)(1)]
New equipment other than hermetically sealed-pressure switchgear [98.306(n)(2)]
Retired hermetically sealed-pressure switchgear [98.306(n)(3)]
Retired equipment other than hermetically sealed-pressure switchgear [98.306(n)(4)]
SF6 or PFC	PFC-3-1-10 (Perfluorobutane)
New hermetically sealed-pressure switchgear [98.306(n)(1)]
New equipment other than hermetically sealed-pressure switchgear [98.306(n)(2)]
Retired hermetically sealed-pressure switchgear [98.306(n)(3)]
Retired equipment other than hermetically sealed-pressure switchgear [98.306(n)(4)]
SF6 or PFC	Perfluorocyclobutane
New hermetically sealed-pressure switchgear [98.306(n)(1)]
New equipment other than hermetically sealed-pressure switchgear [98.306(n)(2)]
Retired hermetically sealed-pressure switchgear [98.306(n)(3)]
Retired equipment other than hermetically sealed-pressure switchgear [98.306(n)(4)]
SF6 or PFC	PFC-4-1-12 (Perfluoropentane)
New hermetically sealed-pressure switchgear [98.306(n)(1)]
New equipment other than hermetically sealed-pressure switchgear [98.306(n)(2)]
Retired hermetically sealed-pressure switchgear [98.306(n)(3)]
Retired equipment other than hermetically sealed-pressure switchgear [98.306(n)(4)]
SF6 or PFC	PFC-5-1-14 (Perfluorohexane)
New hermetically sealed-pressure switchgear [98.306(n)(1)]
New equipment other than hermetically sealed-pressure switchgear [98.306(n)(2)]
Retired hermetically sealed-pressure switchgear [98.306(n)(3)]
Retired equipment other than hermetically sealed-pressure switchgear [98.306(n)(4)]
SF6 or PFC	PFC-9-1-18
New hermetically sealed-pressure switchgear [98.306(n)(1)]
New equipment other than hermetically sealed-pressure switchgear [98.306(n)(2)]
Retired hermetically sealed-pressure switchgear [98.306(n)(3)]
Retired equipment other than hermetically sealed-pressure switchgear [98.306(n)(4)]

CalculatedValueOfUserEmissionsPerGasRowDetails:

SF6 or PFC	Sulfur hexafluoride
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] [F2=B4 or B6]	0
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F3=C5 or C7]	507
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F4=D6 or D8]	0
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] [F5=E6 or E8]	507
User Emissions (pounds, rounded) [98.303(a)/(b) and 98.3(c)(4)(iii)] --- Output of Eq. DD-1 [F6=F2+F3−F4−F5]	0
SF6 or PFC	PFC-14 (Perfluoromethane)
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] [F2=B4 or B6]	0
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F3=C5 or C7]	0
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F4=D6 or D8]	0
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] [F5=E6 or E8]	0
User Emissions (pounds, rounded) [98.303(a)/(b) and 98.3(c)(4)(iii)] --- Output of Eq. DD-1 [F6=F2+F3−F4−F5]	0
SF6 or PFC	PFC-116 (Perfluoroethane)
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] [F2=B4 or B6]	0
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F3=C5 or C7]	0
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F4=D6 or D8]	0
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] [F5=E6 or E8]	0
User Emissions (pounds, rounded) [98.303(a)/(b) and 98.3(c)(4)(iii)] --- Output of Eq. DD-1 [F6=F2+F3−F4−F5]	0
SF6 or PFC	PFC-218 (Perfluoropropane)
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] [F2=B4 or B6]	0
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F3=C5 or C7]	0
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F4=D6 or D8]	0
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] [F5=E6 or E8]	0
User Emissions (pounds, rounded) [98.303(a)/(b) and 98.3(c)(4)(iii)] --- Output of Eq. DD-1 [F6=F2+F3−F4−F5]	0
SF6 or PFC	Perfluorocyclopropane
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] [F2=B4 or B6]	0
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F3=C5 or C7]	0
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F4=D6 or D8]	0
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] [F5=E6 or E8]	0
User Emissions (pounds, rounded) [98.303(a)/(b) and 98.3(c)(4)(iii)] --- Output of Eq. DD-1 [F6=F2+F3−F4−F5]	0
SF6 or PFC	PFC-3-1-10 (Perfluorobutane)
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] [F2=B4 or B6]	0
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F3=C5 or C7]	0
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F4=D6 or D8]	0
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] [F5=E6 or E8]	0
User Emissions (pounds, rounded) [98.303(a)/(b) and 98.3(c)(4)(iii)] --- Output of Eq. DD-1 [F6=F2+F3−F4−F5]	0
SF6 or PFC	Perfluorocyclobutane
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] [F2=B4 or B6]	0
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F3=C5 or C7]	0
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F4=D6 or D8]	0
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] [F5=E6 or E8]	0
User Emissions (pounds, rounded) [98.303(a)/(b) and 98.3(c)(4)(iii)] --- Output of Eq. DD-1 [F6=F2+F3−F4−F5]	0
SF6 or PFC	PFC-4-1-12 (Perfluoropentane)
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] [F2=B4 or B6]	0
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F3=C5 or C7]	0
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F4=D6 or D8]	0
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] [F5=E6 or E8]	0
User Emissions (pounds, rounded) [98.303(a)/(b) and 98.3(c)(4)(iii)] --- Output of Eq. DD-1 [F6=F2+F3−F4−F5]	0
SF6 or PFC	PFC-5-1-14 (Perfluorohexane)
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] [F2=B4 or B6]	0
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F3=C5 or C7]	0
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F4=D6 or D8]	0
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] [F5=E6 or E8]	0
User Emissions (pounds, rounded) [98.303(a)/(b) and 98.3(c)(4)(iii)] --- Output of Eq. DD-1 [F6=F2+F3−F4−F5]	0
SF6 or PFC	PFC-9-1-18
Decrease in SF6 or PFC Inventory (pounds, rounded) [98.303(a)/(b)] [F2=B4 or B6]	0
Acquisitions of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F3=C5 or C7]	0
Disbursements of SF6 or PFC (pounds, rounded) [98.303(a)/(b)] [F4=D6 or D8]	0
Net Increase in Total Nameplate Capacity of Equipment Operated (pounds, rounded) [98.303(a)/(b)] [F5=E6 or E8]	0
User Emissions (pounds, rounded) [98.303(a)/(b) and 98.3(c)(4)(iii)] --- Output of Eq. DD-1 [F6=F2+F3−F4−F5]	0

Subpart TT: Industrial Waste Landfills

Gas Information Details

Gas Name	Carbon Dioxide
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	Biogenic Carbon dioxide
Gas Quantity	0 (Metric Tons)
Own Result?

Gas Name	Methane
Gas Quantity	4,808.67 (Metric Tons)
Own Result?

Gas Name	Nitrous Oxide
Gas Quantity	0 (Metric Tons)
Own Result?

Landfill Details:

Was the landfill open or closed

Open

First year the landfill accepted waste

1975

If the landfill is open, the estimated year of landfill closure

2036

Landfill Capacity

4462443 (Metric Tons)

Does the landfill have a landfill gas collection system

Passive vents and/or flares are present (vents or flares that are not considered part of the gas collection system)

An indication of whether leachate recirculation was used during the reporting year

The typical frequency of use of leachate recirculation over the past ten (10) years

Not used for the past ten (10) years

Each type of cover material used and Landfill surface area containing waste

Clay cover

64000 (Square Meters)

Number of waste streams

Annual modeled methane generation TT1

5342.97 (Metric Tons)

Annual modeled methane generation TT1 user overrided value

Equation TT-1 Details:

The fraction of CH4 in landfill gas (F), is it based on a measured value or default value	Default
Fraction by volume of CH4 in landfill gas	()
An MCF value other than the default of 1 was used	N

Waste Stream For Method3 Details:

Capacity of the landfill used (or the total quantity of waste-in-place) at the end of the "YrData" from design drawings or engineering estimates	1124933 (Metric Tons)
Are waste quantity data available?	Waste quantity data are available for some years
The year prior to the year when waste disposal data are first available(YrData)	1993
Do you know the year when the landfill opened?	Yes
The year the landfill first received waste from company records, or 1960 (whichever is more recent)	1975

Waste Stream For Method4 Details:

Do you know the year when the landfill opened?

Methane Generation and Emissions for Landfills without LFG Collection Systems

Methane Oxidation Fraction

Methane Oxidation Fraction TT-6

0.10

Gas Collection Systems details

Methane Generation Equation TT6

4808.67 (Metric Tons)

Waste Stream Summary:

Stream Identification and Method(s) used to determine historical waste stream quantity for TXOP_Construction & Demo

Stream Name

TXOP_Construction & Demo

Stream Description

contaminated soil, lined pipe, building material and rubble

Type(s) Of Waste Present In The Waste Stream

construction and demolition

Range of years for which both disposal and production data were used in Equation TT-2 to calculate the average waste disposal factor for the landfill

1994-2005

First year this waste stream was placed in the landfill

1975

Last year this waste stream was placed in the landfill

2019

Method(s) used to determine historical waste stream quantity

Reporting Year	Method #1	Method #2	Method #3	Method #4	Decayrate	Waste disposed quantity (UOM)	Waste stream DOC value (UOM)	Is defaulted value from table TT1	Is value measured using 60 day anaerobic biodegradation test	Is based on total volatile solids measurements
1975	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1976	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1977	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1978	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1979	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1980	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1981	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1982	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1983	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1984	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1985	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1986	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1987	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1988	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1989	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1990	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1991	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1992	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1993	N	N	Y	N	0.04	947 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1994	N	Y	N	N	0.04	1199 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1995	N	Y	N	N	0.04	1325 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1996	N	Y	N	N	0.04	1373 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1997	N	Y	N	N	0.04	1418 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1998	N	Y	N	N	0.04	1392 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
1999	N	Y	N	N	0.04	1456 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2000	N	Y	N	N	0.04	1541 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2001	N	Y	N	N	0.04	1412 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2002	N	Y	N	N	0.04	1381 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2003	N	Y	N	N	0.04	1537 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2004	N	Y	N	N	0.04	1625 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2005	N	Y	N	N	0.04	1496 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2006	Y	N	N	N	0.04	1249 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2007	Y	N	N	N	0.04	1065 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2008	Y	N	N	N	0.04	2332 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2009	Y	N	N	N	0.04	498 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2010	Y	N	N	N	0.04	1330 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2011	Y	N	N	N	0.04	1214 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2012	Y	N	N	N	0.04	33077 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2013	Y	N	N	N	0.04	57479 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2014	Y	N	N	N	0.04	33935 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2015	Y	N	N	N	0.04	31654 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2016	Y	N	N	N	0.04	51679 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2017	Y	N	N	N	0.04	47513 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2018	Y	N	N	N	0.04	21087 (Metric Tons)	0.08 (Metric Tons)	Y	N	N
2019	Y	N	N	N	0.04	13327 (Metric Tons)	0.08 (Metric Tons)	Y	N	N

Stream Identification and Method(s) used to determine historical waste stream quantity for TXOP_Inert Waste Streams

Stream Name

TXOP_Inert Waste Streams

Stream Description

Asbestos, insulation,transite type material and UNCONTAMINATED soil & rubble

Type(s) Of Waste Present In The Waste Stream

inert waste

Range of years for which both disposal and production data were used in Equation TT-2 to calculate the average waste disposal factor for the landfill

1994-2005

First year this waste stream was placed in the landfill

1975

Last year this waste stream was placed in the landfill

2019

Method(s) used to determine historical waste stream quantity

Reporting Year	Method #1	Method #2	Method #3	Method #4	Waste disposed quantity (UOM)	Waste stream DOC value (UOM)	Is defaulted value from table TT1	Is value measured using 60 day anaerobic biodegradation test	Is based on total volatile solids measurements
1975	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1976	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1977	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1978	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1979	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1980	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1981	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1982	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1983	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1984	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1985	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1986	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1987	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1988	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1989	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1990	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1991	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1992	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1993	N	N	Y	N	2901 (Metric Tons)	0 (Metric Tons)	Y	N	N
1994	N	Y	N	N	3631 (Metric Tons)	0 (Metric Tons)	Y	N	N
1995	N	Y	N	N	4058 (Metric Tons)	0 (Metric Tons)	Y	N	N
1996	N	Y	N	N	4202 (Metric Tons)	0 (Metric Tons)	Y	N	N
1997	N	Y	N	N	4344 (Metric Tons)	0 (Metric Tons)	Y	N	N
1998	N	Y	N	N	4262 (Metric Tons)	0 (Metric Tons)	Y	N	N
1999	N	Y	N	N	4459 (Metric Tons)	0 (Metric Tons)	Y	N	N
2000	N	Y	N	N	4719 (Metric Tons)	0 (Metric Tons)	Y	N	N
2001	N	Y	N	N	4323 (Metric Tons)	0 (Metric Tons)	Y	N	N
2002	N	Y	N	N	4229 (Metric Tons)	0 (Metric Tons)	Y	N	N
2003	N	Y	N	N	4708 (Metric Tons)	0 (Metric Tons)	Y	N	N
2004	N	Y	N	N	4975 (Metric Tons)	0 (Metric Tons)	Y	N	N
2005	N	Y	N	N	4583 (Metric Tons)	0 (Metric Tons)	Y	N	N
2006	Y	N	N	N	6694 (Metric Tons)	0 (Metric Tons)	Y	N	N
2007	Y	N	N	N	3908 (Metric Tons)	0 (Metric Tons)	Y	N	N
2008	Y	N	N	N	3873 (Metric Tons)	0 (Metric Tons)	Y	N	N
2009	Y	N	N	N	1494 (Metric Tons)	0 (Metric Tons)	Y	N	N
2010	Y	N	N	N	2666 (Metric Tons)	0 (Metric Tons)	Y	N	N
2011	Y	N	N	N	5489 (Metric Tons)	0 (Metric Tons)	Y	N	N
2012	Y	N	N	N	4252 (Metric Tons)	0 (Metric Tons)	Y	N	N
2013	Y	N	N	N	1220 (Metric Tons)	0 (Metric Tons)	Y	N	N
2014	Y	N	N	N	941 (Metric Tons)	0 (Metric Tons)	Y	N	N
2015	Y	N	N	N	1990 (Metric Tons)	0 (Metric Tons)	Y	N	N
2016	Y	N	N	N	2445 (Metric Tons)	0 (Metric Tons)	Y	N	N
2017	Y	N	N	N	4485 (Metric Tons)	0 (Metric Tons)	Y	N	N
2018	Y	N	N	N	2972 (Metric Tons)	0 (Metric Tons)	Y	N	N
2019	Y	N	N	N	265.3 (Metric Tons)	0 (Metric Tons)	Y	N	N

Stream Identification and Method(s) used to determine historical waste stream quantity for TXOP_Other Industrial Solid Waste

Stream Name

TXOP_Other Industrial Solid Waste

Stream Description

Non burnable trash, biosolids, contaminated filters and other plant wastes

Type(s) Of Waste Present In The Waste Stream

other industrial solid waste

Range of years for which both disposal and production data were used in Equation TT-2 to calculate the average waste disposal factor for the landfill

1994-2005

First year this waste stream was placed in the landfill

1975

Last year this waste stream was placed in the landfill

2019

Method(s) used to determine historical waste stream quantity

Reporting Year	Method #1	Method #2	Method #3	Method #4	Decayrate	Waste disposed quantity (UOM)	Waste stream DOC value (UOM)	Is defaulted value from table TT1	Is value measured using 60 day anaerobic biodegradation test	Is based on total volatile solids measurements
1975	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1976	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1977	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1978	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1979	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1980	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1981	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1982	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1983	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1984	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1985	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1986	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1987	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1988	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1989	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1990	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1991	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1992	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1993	N	N	Y	N	0.06	53760 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1994	N	Y	N	N	0.06	68017 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1995	N	Y	N	N	0.06	75195 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1996	N	Y	N	N	0.06	77895 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1997	N	Y	N	N	0.06	80489 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1998	N	Y	N	N	0.06	78984 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
1999	N	Y	N	N	0.06	82633 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2000	N	Y	N	N	0.06	87447 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2001	N	Y	N	N	0.06	80107 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2002	N	Y	N	N	0.06	78365 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2003	N	Y	N	N	0.06	87237 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2004	N	Y	N	N	0.06	92195 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2005	N	Y	N	N	0.06	84919 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2006	Y	N	N	N	0.06	71048 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2007	Y	N	N	N	0.06	69590 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2008	Y	N	N	N	0.06	64300 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2009	Y	N	N	N	0.06	56383 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2010	Y	N	N	N	0.06	78087 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2011	Y	N	N	N	0.06	109054 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2012	Y	N	N	N	0.06	102742 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2013	Y	N	N	N	0.06	91228 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2014	Y	N	N	N	0.06	76554 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2015	Y	N	N	N	0.06	74854 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2016	Y	N	N	N	0.06	80559 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2017	Y	N	N	N	0.06	74086 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2018	Y	N	N	N	0.06	88535 (Metric Tons)	0.2 (Metric Tons)	Y	N	N
2019	Y	N	N	N	0.06	66473 (Metric Tons)	0.2 (Metric Tons)	Y	N	N

Stream Identification and Method(s) used to determine historical waste stream quantity for TXOP_Pulp and Paper Wastes

Stream Name

TXOP_Pulp and Paper Wastes

Stream Description

Paper products

Type(s) Of Waste Present In The Waste Stream

pulp and paper wastes not segregated into separate streams

pulp and paper manufacturing wastes, general

Range of years for which both disposal and production data were used in Equation TT-2 to calculate the average waste disposal factor for the landfill

1994-2005

First year this waste stream was placed in the landfill

1975

Last year this waste stream was placed in the landfill

2019

Method(s) used to determine historical waste stream quantity

Reporting Year	Method #1	Method #2	Method #3	Method #4	Decayrate	Waste disposed quantity (UOM)	Waste stream DOC value (UOM)	Is defaulted value from table TT1	Is value measured using 60 day anaerobic biodegradation test	Is based on total volatile solids measurements
1975	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1976	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1977	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1978	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1979	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1980	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1981	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1982	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1983	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1984	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1985	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1986	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1987	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1988	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1989	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1990	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1991	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1992	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1993	N	N	Y	N	0.04	18 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1994	N	Y	N	N	0.04	22 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1995	N	Y	N	N	0.04	25 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1996	N	Y	N	N	0.04	26 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1997	N	Y	N	N	0.04	27 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1998	N	Y	N	N	0.04	26 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
1999	N	Y	N	N	0.04	27 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2000	N	Y	N	N	0.04	29 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2001	N	Y	N	N	0.04	26 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2002	N	Y	N	N	0.04	26 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2003	N	Y	N	N	0.04	29 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2004	N	Y	N	N	0.04	30 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2005	N	Y	N	N	0.04	28 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2006	Y	N	N	N	0.04	32 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2007	Y	N	N	N	0.04	32 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2008	Y	N	N	N	0.04	23 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2009	Y	N	N	N	0.04	34 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2010	Y	N	N	N	0.04	17 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2011	Y	N	N	N	0.04	11 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2012	Y	N	N	N	0.04	13 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2013	Y	N	N	N	0.04	8 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2014	Y	N	N	N	0.04	11 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2015	Y	N	N	N	0.04	11 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2016	Y	N	N	N	0.04	8 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2017	Y	N	N	N	0.04	7 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2018	Y	N	N	N	0.04	0.4 (Metric Tons)	0.15 (Metric Tons)	Y	N	N
2019	Y	N	N	N	0.04	4.4 (Metric Tons)	0.15 (Metric Tons)	Y	N	N

Stream Identification and Method(s) used to determine historical waste stream quantity for TXOP_Wood and Wood Products

Stream Name

TXOP_Wood and Wood Products

Stream Description

UNCONTAMINATED / UNTREATED WOOD

Type(s) Of Waste Present In The Waste Stream

wood and wood product

Range of years for which both disposal and production data were used in Equation TT-2 to calculate the average waste disposal factor for the landfill

1994-2005

First year this waste stream was placed in the landfill

1975

Last year this waste stream was placed in the landfill

2019

Method(s) used to determine historical waste stream quantity

Reporting Year	Method #1	Method #2	Method #3	Method #4	Decayrate	Waste disposed quantity (UOM)	Waste stream DOC value (UOM)	Is defaulted value from table TT1	Is value measured using 60 day anaerobic biodegradation test	Is based on total volatile solids measurements
1975	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1976	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1977	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1978	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1979	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1980	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1981	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1982	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1983	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1984	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1985	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1986	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1987	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1988	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1989	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1990	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1991	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1992	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1993	N	N	Y	N	0.04	1658 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1994	N	Y	N	N	0.04	2097 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1995	N	Y	N	N	0.04	2319 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1996	N	Y	N	N	0.04	2402 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1997	N	Y	N	N	0.04	2482 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1998	N	Y	N	N	0.04	2436 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
1999	N	Y	N	N	0.04	2548 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2000	N	Y	N	N	0.04	2697 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2001	N	Y	N	N	0.04	2470 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2002	N	Y	N	N	0.04	2417 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2003	N	Y	N	N	0.04	2690 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2004	N	Y	N	N	0.04	2843 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2005	N	Y	N	N	0.04	2619 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2006	Y	N	N	N	0.04	2187 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2007	Y	N	N	N	0.04	2321 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2008	Y	N	N	N	0.04	2161 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2009	Y	N	N	N	0.04	1839 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2010	Y	N	N	N	0.04	2612 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2011	Y	N	N	N	0.04	2498 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2012	Y	N	N	N	0.04	2573 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2013	Y	N	N	N	0.04	2840 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2014	Y	N	N	N	0.04	2314 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2015	Y	N	N	N	0.04	4862 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2016	Y	N	N	N	0.04	7054 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2017	Y	N	N	N	0.04	4891 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2018	Y	N	N	N	0.04	3282 (Metric Tons)	0.43 (Metric Tons)	Y	N	N
2019	Y	N	N	N	0.04	2064.4 (Metric Tons)	0.43 (Metric Tons)	Y	N	N

Method #1: Used one of the waste quantity measurement methods specified in 98.463(a)(2)(i): direct mass measurements, direct volume measurements multiplied by waste stream density, mass balance procedures (difference between the mass of process inputs and the mass of process outputs), or the number of loads multiplied by the mass of waste per load based on the working capacity of the vehicle or container.
Method #2: Calculated the average waste disposal rate per Equation TT-2 and calculated the waste disposal quantities for historic years in which direct waste disposal measurements are not available using historical production data per Equation TT-3.
Method #3: Calculated an average annual bulk waste disposal quantity for historic years when waste quantity data as determined by other methods are available consecutively for the most recent disposal years (Equation TT-4a).
Method #4: Calculated an average annual bulk waste disposal quantity for historic years when waste quantity data as determined by other methods are available for sporadic (non-consecutive) years (Equation TT-4b).