Techno‐economics for conversion of lignocellulosic biomass to ethanol by indirect gasification and mixed alcohol synthesis

Dutta, Abhijit; Talmadge, Michael; Hensley, Jesse E.; Worley, M.; Dudgeon, D.; Barton, David G.; Groenendijk, Peter; Ferrari, Davide; Stears, B.; Searcy, Erin; Wright, Christopher T.; Hess, J. Richard

doi:10.1002/ep.10625

Cited by 51 publications

(59 citation statements)

References 21 publications

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“…Finally, Dutta et al (2014) presents the most recent update of the model which is based on the results of a combination of bench-and pilot-scale experiment performed by NREL, Dow Chemical, and Rentech. This analysis concludes that it is possible based on current technology to achieve the $3.33/gge ($0.88/lge) MFSP calculated by Dutta et al (2012), although it again assumes a 30-year biorefinery lifespan. Gonzalez et al (2012) uses a modified version of NREL's MAS pathway model to quantify the pathway's techno-economics under five lignocellulosic feedstock scenarios: loblolly pine, natural hardwood, eucalyptus, stover, and switchgrass.…”

Section: Mixed Alcohols Synthesismentioning

confidence: 92%

“…This model is adjusted slightly in a 2009 analysis to compare the MAS pathway with a biochemical pathway and calculates a MFSP of $1.98/gge ($0.52/lge) (Foust et al, 2009). Dutta et al (2012) updates the 2007 analysis to reflect new data and developments on feedstock costs, gasifier syngas yields, mixed alcohols synthesis, and capital and operating cost estimates. The updated model calculates a significantly higher TPI of $560 million and a MFSP of $3.33/ gge ($0.88/lge) with an assumed feedstock cost of $73.48/MT.…”

Section: Mixed Alcohols Synthesismentioning

confidence: 99%

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A techno-economic review of thermochemical cellulosic biofuel pathways

Brown

2015

Bioresource Technology

134

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Section: Mixed Alcohols Synthesismentioning

confidence: 92%

Section: Mixed Alcohols Synthesismentioning

confidence: 99%

A techno-economic review of thermochemical cellulosic biofuel pathways

Brown

2015

Bioresource Technology

134

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“…Other equipment costs, such as those of distillation columns, flash tanks, compressors and motors are calculated using ChemCAD built-in costing after sizing and the rest is obtained from publicallyavailable literature. 4,30,33,35,38,39 A fixed-factor method is used as described in Table 3 to obtain TPI from total purchased equipment cost (TPEC) in order to avoid the significant variances reported for individual equipment factors. 40 Lang factor multiplier represents TPI/TPEC.…”

Section: Techno-economicsmentioning

confidence: 99%

Mild catalytic pyrolysis of biomass for production of transportation fuels: a techno-economic analysis

Thilakaratne

Brown

et al. 2014

Green Chem.

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A techno-economic analysis of mild catalytic pyrolysis (CP) of woody biomass followed by upgrading of the partially deoxygenated pyrolysis liquid is performed to assess this pathway's economic feasibility for the production of hydrocarbon-based biofuels. The process achieves a fuel yield of 17.7 wt% and an energy conversion of 39%. Deoxygenation of the pyrolysis liquid requires 2.7 wt% hydrogen while saturation of aromatic rings in the pyrolysis liquid increases total hydrogen consumption to 6.4 wt%. Total project investment is $457 million with annual operating costs of $142 million for a 2000 metric ton per day facility. A minimum fuel selling price (MFSP) of $3.69/gal is estimated assuming 10% internal rate of return. Twentynine percent of the capital outlay is the result of including a co-generation system to consume heat generated from burning part of the off-gases from pyrolysis and upgrading and all of the coke during regeneration of catalysts. Forty-five percent of the MFSP arises from the cost of biomass feedstock. Hydrogen required for the upgrading process is generated using the balance of the process off-gases.The analysis reveals that an optimum design would include a cogeneration unit; however using natural gas for hydrogen generation is more favorable than using process off-gases as the feed. An uncertainty analysis indicates a probable fuel price of $3.03/gal, demonstrating the potential of the CP pathway as an alternative to petroleum-derived transportation fuels. AbstractA techno-economic analysis of mild catalytic pyrolysis (CP) of woody biomass followed by upgrading of the partially deoxygenated pyrolysis liquid is performed to assess this pathway's economic feasibility for the production of hydrocarbon-based biofuels. The process achieves a fuel yield of 17.7 wt% and an energy conversion of 39%. Deoxygenation of the pyrolysis liquid requires 2.7 wt% hydrogen while saturation of aromatic rings in the pyrolysis liquid increases total hydrogen consumption to 6.4 wt%.Total project investment is $457 million with annual operating costs of $142 million for a 2000 metric ton per day facility. A minimum fuel selling price (MFSP) of $3.69/gal is estimated assuming 10% internal rate of return. Twenty-nine percent of the capital outlay is the result of including a co-generation system to consume heat generated from burning part of the off-gases from pyrolysis and upgrading and all of the coke during regeneration of catalysts. Forty-five percent of the MFSP arises from the cost of biomass feedstock. Hydrogen required for the upgrading process is generated using the balance of the process off-gases.This is a manuscript of an article from Green Chemistry 16 (2014): 627, doi: 10.1039/C3GC41314D. Posted with permission. 2The analysis reveals that an optimum design would include a cogeneration unit; however using natural gas for hydrogen generation is more favorable than using process off-gases as the feed.An uncertainty analysis indicates a probable fuel price of $3.03/gal, demonstrating the potent...

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“…The abundant supply of ethanol from a variety of possible renewable sources makes it an attractive feedstock for the production of commodity chemicals, such as BD [6][7][8][9][10][11][12][13].…”

Section: Introductionmentioning

confidence: 99%