Facility Name:Natgasoline LLC
Facility Identifier:
Facility Reporting Year:2020
Facility Location:
Address: 2366 Sulphur Plant Road
City: Beaumont
State: TX
Postal Code: 77705

Facility Site Details:
CO2 equivalent emissions from facility subparts C-II, SS, and TT (metric tons):702,347.2
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:2020-01-01
GHG Report End Date:2020-12-31
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:325199
Second Primary NAICS Code:

Parent Company Details:
Parent Company Name:FIREWATER LLC
Address:2366 Sulphur Plant Road, Beaumont,  TX 77705
Percent Ownership Interest:100

Subpart C: General Stationary Fuel Combustion

Gas Information Details

Gas NameCarbon Dioxide
Gas Quantity369,519.8 (Metric Tons)
Own Result?

Gas NameBiogenic Carbon dioxide
Gas Quantity0 (Metric Tons)
Own Result?

Gas NameMethane
Gas Quantity10.02 (Metric Tons)
Own Result?

Gas NameNitrous Oxide
Gas Quantity1.477 (Metric Tons)
Own Result?

Unit Details:
Unit Name : B-14001
Unit Type : OB (Boiler, other)
Unit Description :
Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 950 (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 : 2020-01-01
Tier Methodology End Date : 2020-12-31

Fuel Emission Details :
Total CO2 emissionsTotal CH4 emissionsTotal N2O emissionsTotal CH4 emissions CO2eTotal N2O emissions CO2e
193948.9 (Metric Tons) 3.59 (Metric Tons) 0.359 (Metric Tons) 89.8 (Metric Tons) 107 (Metric Tons)

Carbon Content Substitute Data Information :
Total number of valid carbon content determinations : 47
Total number of carbon content substitute data values : 0
Frequency of carbon content determinations : Weekly
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 : 47
Total number of molecular weight substitute data values : 0
Frequency of molecular weight determinations : Weekly
Molar Volume Constant (MVC) used : 836.6 (scf/kg-mole)

Unit Name : CP20-B-01001
Unit Type : OCS (Other combustion source)
Unit Description :
Other Unit Name : Reformer
Individual Unit Details:
Use Ivt Indicator: Y
Maximum Rated Heat Input Capacity: 1550 (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 (Other (gas))
Tier Name : Tier 3 (Equation C-5, gaseous fuel)
Tier Methodology Start Date : 2020-01-01
Tier Methodology End Date : 2020-12-31

Fuel Emission Details :
Total CO2 emissionsTotal CH4 emissionsTotal N2O emissionsTotal CH4 emissions CO2eTotal N2O emissions CO2e
90311.2 (Metric Tons) 1.68 Y (Metric Tons) 0.168 Y (Metric Tons) 41.9 (Metric Tons) 50 (Metric Tons)

Carbon Content Substitute Data Information :
Total number of valid carbon content determinations : 47
Total number of carbon content substitute data values : 0
Frequency of carbon content determinations : Weekly
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 : 47
Total number of molecular weight substitute data values : 0
Frequency of molecular weight determinations : Weekly
Molar Volume Constant (MVC) used : 836.6 (scf/kg-mole)

Fuel : Natural Gas (Other (gas))
Tier Name : Tier 3 (Equation C-5, gaseous fuel)
Tier Methodology Start Date : 2020-01-01
Tier Methodology End Date : 2020-12-31

Fuel Emission Details :
Total CO2 emissionsTotal CH4 emissionsTotal N2O emissionsTotal CH4 emissions CO2eTotal N2O emissions CO2e
85259.7 (Metric Tons) 4.75 Y (Metric Tons) 0.950 Y (Metric Tons) 118.7 (Metric Tons) 283 (Metric Tons)

Carbon Content Substitute Data Information :
Total number of valid carbon content determinations : 47
Total number of carbon content substitute data values : 0
Frequency of carbon content determinations : Weekly
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 : 47
Total number of molecular weight substitute data values : 0
Frequency of molecular weight determinations : Weekly
Molar Volume Constant (MVC) used : 836.6 (scf/kg-mole)


Subpart X: Petrochemical Production


CEMS Monitoring Location (CML) Details for Subpart X

Gas Information Details

Gas NameCarbon Dioxide
Gas Quantity332,136.8 (Metric Tons)
Own Result?

Gas NameBiogenic Carbon dioxide
Gas Quantity0 (Metric Tons)
Own Result?

Gas NameMethane
Gas Quantity0 (Metric Tons)
Own Result?

Gas NameNitrous Oxide
Gas Quantity0 (Metric Tons)
Own Result?


Petrochemical Process Units

Petrochemical process units monitored using the mass balance methodology:

Name or ID:B-01001
Description:
Type:Petrochemical process unit
Identify combustion units:CP20-B-01001
AnnualCO2Emissions:332136.8 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: Flow Meter
Annual quantity of feedstock or product: 
If applicable, dates for each process change that reduced the composition to less than 99.5%:
MonthVolume for month based on missing data procedureVolume measurement methodOther volume measurement methodCarbon content or composition for month based on missing data procedureCarbon content or composition determination methodSpecify the practiceOther MethodName or title of the alternative carbon content determination methodExplanation as to why an alternative carbon content determination method was neededFile name of the copy of the alternative carbon content determination methodMolecular weight for month based on missing data procedure, if applicableMolecular weight determination method, if applicableOther methodName or title of the alternative molecular weight determination methodExplanation as to why an alternative molecular weight determination method was neededFile name of the copy of the alternative molecular weight determination methodTemperature at which volume was measured
January N Flow meter N Mass spectrometer analysis N Calculated based on chemical formula and atomic weights68 degrees Fahrenheit
February N Flow meter N Mass spectrometer analysis N Calculated based on chemical formula and atomic weights68 degrees Fahrenheit
March N Flow meter N Mass spectrometer analysis N Calculated based on chemical formula and atomic weights68 degrees Fahrenheit
April N Flow meter Y Mass spectrometer analysis Y Calculated based on chemical formula and atomic weights68 degrees Fahrenheit
May N Flow meter N Mass spectrometer analysis N Calculated based on chemical formula and atomic weights68 degrees Fahrenheit
June N Flow meter N Mass spectrometer analysis N Calculated based on chemical formula and atomic weights68 degrees Fahrenheit
July N Flow meter N Mass spectrometer analysis N Calculated based on chemical formula and atomic weights68 degrees Fahrenheit
August N Flow meter N Mass spectrometer analysis N Calculated based on chemical formula and atomic weights68 degrees Fahrenheit
September N Flow meter N Mass spectrometer analysis N Calculated based on chemical formula and atomic weights68 degrees Fahrenheit
October N Flow meter Y Mass spectrometer analysis Y Calculated based on chemical formula and atomic weights68 degrees Fahrenheit
November N Flow meter N Mass spectrometer analysis N Calculated based on chemical formula and atomic weights68 degrees Fahrenheit
December N Flow meter N Mass spectrometer analysis N Calculated based on chemical formula and atomic weights68 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: The total methanol production as made by level measurements is calculated by addition of the values based on Level Measurement Devices.
Annual quantity of feedstock or product: 
If applicable, dates for each process change that reduced the composition to less than 99.5%:
MonthVolume for month based on missing data procedureVolume measurement methodOther volume measurement methodCarbon content or composition for month based on missing data procedureCarbon content or composition determination methodSpecify the practiceOther MethodName or title of the alternative carbon content determination methodExplanation as to why an alternative carbon content determination method was neededFile name of the copy of the alternative carbon content determination methodMolecular weight for month based on missing data procedure, if applicableMolecular weight determination method, if applicableOther methodName or title of the alternative molecular weight determination methodExplanation as to why an alternative molecular weight determination method was neededFile name of the copy of the alternative molecular weight determination methodTemperature at which volume was measured
January N Tank level measurements N Mass spectrometer analysis N
February N Tank level measurements N Mass spectrometer analysis N
March N Tank level measurements N Mass spectrometer analysis N
April N Tank level measurements N Mass spectrometer analysis N
May N Tank level measurements N Mass spectrometer analysis N
June N Tank level measurements N Mass spectrometer analysis N
July N Tank level measurements N Mass spectrometer analysis N
August N Tank level measurements N Mass spectrometer analysis N
September N Tank level measurements N Mass spectrometer analysis N
October N Tank level measurements N Mass spectrometer analysis N
November N Tank level measurements N Mass spectrometer analysis N
December N Tank level measurements N Mass spectrometer analysis N