Reducing the energy demand of corn-based fuel ethanol through salt extractive distillation enabled by electrodialysis

The thermal energy demand for producing fuel ethanol from the fermentation broth of a contemporary corn‐to‐fuel ethanol plant in the U.S. is largely satisfied by combustion of fossil fuels, which impacts the possible economical and environmental advantages of bioethanol over fossil fuels. To reduce...

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Bibliographic Details
Published in:	AIChE journal Vol. 58; no. 1; pp. 163 - 172
Main Authors:	Hussain, Mohammed A. M., Anthony, Jennifer L., Pfromm, Peter H.
Format:	Journal Article
Language:	English
Published:	Hoboken Wiley Subscription Services, Inc., A Wiley Company 01-01-2012 Wiley American Institute of Chemical Engineers
Subjects:	Applied sciences bioethanol Biological and medical sciences Biotechnology Chemical engineering Demand Distillation electrodialytic concentration Ethanol ethanol distillation Ethyl alcohol Exact sciences and technology Fermentation Fossil fuels fuel ethanol Fuels Fundamental and applied biological sciences. Psychology Liquids Marketing Membrane separation (reverse osmosis, dialysis...) Methods. Procedures. Technologies Others salt extractive distillation Simulation Thermal energy Various methods and equipments United States > US USA fuel ethanol Extractive distillation salt extractive distillation electrodialytic concentration Spray drying Combustion Fermentation Modeling Electrodialysis Membrane separation Electrolyte ethanol distillation Fossil fuel Liquid vapor equilibrium bioethanol Phase equilibrium
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Summary:	The thermal energy demand for producing fuel ethanol from the fermentation broth of a contemporary corn‐to‐fuel ethanol plant in the U.S. is largely satisfied by combustion of fossil fuels, which impacts the possible economical and environmental advantages of bioethanol over fossil fuels. To reduce the thermal energy demand for producing fuel ethanol, a process integrating salt extractive distillation—enabled by a new scheme of electrodialysis and spray drying for salt recovery—in the water‐ethanol separation train of a contemporary corn‐to‐fuel ethanol plant is investigated. Process simulation using Aspen Plus® 2006.5, with the electrolyte nonrandom two liquid Redlich‐Kwong property method to model the vapor liquid equilibrium of the water‐ethanol‐salt system, was carried out. The integrated salt extractive distillation process may provide a thermal energy savings of about 30%, when compared with the contemporary process for separating fuel ethanol from the beer column distillate. © 2011 American Institute of Chemical Engineers AIChE J, 2012
Bibliography:	U.S. Department of Energy ark:/67375/WNG-J4M2VT22-F Center for Sustainable Energy at Kansas State University istex:B64D0A49A2FB8B588341A792D9EF649FD68DF746 ArticleID:AIC12577 U.S. Department of Transportation U.S. Department of Agriculture through the Sun Grant Initiative - No. Sub-Award #AB-5-61770-KSU1.01 ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23
ISSN:	0001-1541 1547-5905
DOI:	10.1002/aic.12577