BioFuels: Difference between revisions
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The results of this pathway have been evaluated against the GREET1_2011 Excel spreadsheet for all available types of allocation both for Extraction and Transesterification, however the displacement options have not been validated yet. The results obtained with GREET.net are showing an error between 0.1% and 1.06% compared to the excel spreadsheet. We are still investigating those errors. | The results of this pathway have been evaluated against the GREET1_2011 Excel spreadsheet for all available types of allocation both for Extraction and Transesterification, however the displacement options have not been validated yet. The results obtained with GREET.net are showing an error between 0.1% and 1.06% compared to the excel spreadsheet. We are still investigating those errors. | ||
====Total Energy Calculations==== | |||
The total energy is calculated in GREET1_2011 as this : | |||
<math>(OH(Fa&Tr) + HV(SyBn)) \cdot y_1 + OH(OlEx) - HV(SyOl) \cdot af_1 + OH(OlTr) + HV(SyOl) \cdot y_2</math> | |||
===BioDiesel production=== | ===BioDiesel production=== |
Revision as of 20:02, April 20, 2012
Biomass Farming
The bio-masses used for the bio-fuels pathways are:
- Soybean Farming
- Palm FFB Farming
- Rapeseed Farming
- Jatropha Farming
- Camelina Farming
All those farming processes are implemented in GREET. They are using regular US averages fertilizer production and Diesel for non road engine to power the farming tractors and other stationary engines used (pumps, conveyors...)
The products are assumed to be transported dried so there is no need to specify the moisture content of those materials in the transportation processes after those farming processes.
Fuel Production
Bio-fuels production generates a lot of valuable co-products such as SBM, Fuel Gas or Glycerine. In the Excel spreadsheet options are offered on the main page to switch between system level allocation or process level allocation/displacement.
For the process level allocation/displacement method we create two distinct processes Oil Extraction and Transesterification. Each of them have their set of inputs and a definition of the co-products. It is therefore allowed to perform an displacement on the first process and a market allocation on the transeterification process, the co-products treatment method chosen for each process is independent.
For system level allocations, the extraction and transesterification processes are modeled as a single process with two co-products. They are aggregated in a single process to make abstraction of the vegetable oil link between the extraction and trans. processes, thus making them a single system.
Renewable Diesel II Production
Here are the assumptions used for this pathway :
- Yield for oil extraction : 4.7lb of dry soybeans for 1 lb of oil
- Coproducts for oil extraction : 3.7lb of SBM for 1 lb of oil
- Yield for transesterification : 1.17lb of Vegetable Oil for 1lb or Renewable Gasoline II
- Coproducts for transesterification : 0.059lb of Propane fuel gas per 1 lb of Renewable Gasoline II
The structure of the pathway is exactly the same as shown above, the pathway can be found under : LDV Fuels -> Diesel -> Renewable Diesel II -> From Soy Oil
The results of this pathway have been evaluated against the GREET1_2011 Excel spreadsheet for all available types of allocation both for Extraction and Transesterification, however the displacement options have not been validated yet. The results obtained with GREET.net are showing an error between 0.1% and 1.06% compared to the excel spreadsheet. We are still investigating those errors.
Total Energy Calculations
The total energy is calculated in GREET1_2011 as this : Failed to parse (syntax error): {\displaystyle (OH(Fa&Tr) + HV(SyBn)) \cdot y_1 + OH(OlEx) - HV(SyOl) \cdot af_1 + OH(OlTr) + HV(SyOl) \cdot y_2}
BioDiesel production
Biodiesel from Soybeans (Process Level Allocation)
Description of the biodiesel from soybeans pathways using process level allocation/displacement in GREET.