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Pressure Swing Adsorption Process in Coal to Fischer-Tropsch Fuels with CO2 Capture

Title
Pressure Swing Adsorption Process in Coal to Fischer-Tropsch Fuels with CO2 Capture
Type
Article in International Scientific Journal
Year
2012
Authors
Ana M. Ribeiro
(Author)
FEUP
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João C. Santos
(Author)
Other
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Alírio E. Rodrigues
(Author)
FEUP
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Sebastien Rifflart
(Author)
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Journal
Title: Energy & FuelsImported from Authenticus Search for Journal Publications
Vol. 26 No. 2
Pages: 1246-1253
ISSN: 0887-0624
Other information
Authenticus ID: P-002-DAF
Abstract (EN): The carbon dioxide capture by pressure swing adsorption in a coal to Fischer-Tropsch process is addressed. The simulations results show that a (hydrogen + carbon monoxide) product with required composition for Fischer-Tropsch synthesis, H-2/CO ratio of 2.22, and inerts content of 3.90% can be obtained. Additionally, the PSA process produces high purity carbon dioxide of 95.16% with high recovery of 91.6%. This CO2 stream is compressed to 110 bar for transportation and storage. The power consumption requirement was calculated to be 311 kW.h/ton(CO2) (191 kW.h/ton(CO2) for separation and 120 kW.h/ton(CO2) for compression), which is too high for competitive operation of the PSA process when compared to absorbent based processes. A modification of the PSA process operation procedure involving the introduction of a number of tanks to collect fractions of the blowdown stream drastically reduces the power consumption to 129 kW.h/ton(CO2) (including separation and compression to 110 bar) without affecting the products specifications.
Language: English
Type (Professor's evaluation): Scientific
No. of pages: 8
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