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Received January 23, 2015
Accepted July 30, 2015
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Oxidation of ash-free coal from sub-bituminous and bituminous coals in a direct carbon fuel cell
Department of Chemical and Biological Engineering, Hanbat National University, 125, Dongseodae-ro, Yuseong-gu, Daejeon 305-719, Korea
leecg@hanbat.ac.kr
Korean Journal of Chemical Engineering, February 2016, 33(2), 507-513(7), 10.1007/s11814-015-0164-1
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Abstract
The present study proposes the production of ash-free coal (AFC) and its oxidation as a primary fuel in direct carbon fuel cells (DCFCs). The AFC was produced by the extraction of Arutmin sub-bituminous coal (AFC1) and Berau bituminous coal (AFC2) using polar solvents such as N-methyl-2-pyrrolidone (NMP), N,N-dimethylacetamide (DMA), N,N-dimethylformamide (DMF) and dimethyl sulfoxide (DMSO). It was carried out at a temperature of around 202 oC under atmospheric conditions and using a microwave irradiation method. Using NMP as the solvent showed the highest extraction yield, and the values of 23.53% for Arutmin coal and 33.80% for Berau coal were obtained. When NMP was added to DMSO, DMA and DMF, the extraction yield in the solvents was greatly increased. The yield of AFC from a sub-bituminous coal was slightly lower than that from a bituminous coal. The AFC was evaluated in a coin-type DCFC with a mixture of AFC and carbonate electrolyte (3 g/3 g) at 850 oC. The AFC and gaseous H2 fuels were compared using the electrochemical methods of steady-state polarisation and step chronopotentiometry. The DCFC ran successfully with the AFCs at 850 oC. The open-circuit voltages were about 1.35 V (AFC1) and 1.27 V (AFC2), and the voltages at 150 mA cm.2 were 0.61 V (AFC1) and 0.74 V (AFC2).
Keywords
References
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Dicks AL, J. Power Sources, 156(2), 128 (2006)
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Cherepy NJ, Krueger R, Fiet KJ, Jankowski AF, Cooper JF, J. Electrochem. Soc., 152(1), A80 (2005)
Peelen WHA, Olivry M, Au SF, Fehribach JD, Hemmes K, J. Appl. Electrochem., 30(12), 1389 (2000)
Lee GG, Fuel Cells, 12, 550 (2012)
Lee CG, Kim WK, Proc. 224th ECS meeting, San Francisco, No. 747 (2013).
Lei ZP, Wu L, Zhang YQ, Shui HF, Wang ZC, Pan CX, Li HP, Ren SB, Kang SG, Fuel, 95(1), 630 (2012)
Rahman M, Samanta A, Gupta R, Fuel Process. Technol., 115, 88 (2013)
Renganathan K, Zondlo JW, Fuel Sci. Technol. Int., 11, 677 (1993)
Ungar T, Gubicza J, Ribarik G, Pantea C, Zerda TW, Carbon, 40, 929 (2002)
Vishwakarma PN, Prasad V, Subramanyam SV, Ganesan V, Bull. Mat. Sci., 28, 609 (2005)
Zhang JB, Zhong ZP, Shen DK, Zhao JX, Zhang HY, Yang M, Li WL, Energy Fuels, 25(5), 2187 (2011)
Kim JP, Lim H, Jeon CH, Chang YJ, Koh KN, Choi SM, Song JH, J. Power Sources, 195(22), 7568 (2010)
Elleuch A, Boussetta A, Halouani K, J. Electroanal. Chem., 668, 99 (2012)
Ruflin J, Perwich AD, Brett C, Berner JK, Lux SM, J. Power Sources, 213, 275 (2012)
