Steam Gasification of Coal with Salt Mixture of Potassium and Nickel in a Fluidized Bed Reactor

Woon-Jae Lee; Sang-Done Kim; Byung-Ho Song

Korean Journal of Chemical Engineering, Vol.18, No.5, 640-645, September, 2001

DOI10.1007/BF02706380 Export Citation

Steam Gasification of Coal with Salt Mixture of Potassium and Nickel in a Fluidized Bed Reactor

Woon-Jae Lee, Sang-Done Kim^{1, †}, and Byung-Ho Song²

Energy/Coal and Chemical Process Research Team, Research Institute of Industrial Science and Technology, Pohang 790-330, Korea
¹Department of Chemical Engineering and Energy & Environment Research Center, Korea Advanced Institute of Science and Technology, Daejeon 305-701, Korea
²Department of Chemical Engineering, Kunsan National Univ., Kunsan 573-701, Korea

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Australian coal loaded with a mixed catalyst of K2SO4+Ni(NO3)2 has been gasified with steam in a fluidized bed reactor of 0.1 m inside diameter at atmospheric pressure. The effects of gas velocity (2-5 U(g)/U(mf)), reaction temperature (750-900 ℃), air/coal ratio (1.6-3.2), and steam/coal ratio (0.63-1.26) on gas compositions, gas yield and gas calorific value of the product gas and carbon conversion have been determined. The product gas quality and carbon conversion can be greatly improved by applying the catalyst; they can also be enhanced by increasing gas velocity and temperature. Up to 31% of the catalytic increment in gas calorific value could be obtained at higher temperatures. In the experimental runs with variation of steam/coal ratio, the catalytic increments were 16-38% in gas calorific value, 14-57% in carbon conversion, 5-46% in gas yield, and 7-44% in cold gas efficiency. With increasing fluidization gas velocity and reaction temperature, the unburned carbon fraction of cyclone fine for catalytic gasification decreased 4-18% and 13-16%, respectively, compared to that for non-catalytic gasification.

Keywords:Coal Gasification;Catalyst;Fluidized Bed;Calorific Value

[References]

Choi KH, Lee WY, Rhee HK, Moon SH, Lee HI, Korean J. Chem. Eng., 10(2), 78 (1993)
Dhirendra MV, Awasthi SK, Pandey GN, Energy, 11, 563 (1986)
Foong SK, Cheng G, Watkinson AP, Can. J. Chem. Eng., 59, 625 (1981)
Gutierrez LA, Watkinson AP, Fuel, 61, 133 (1982)
Kikuchi K, Suzuki A, Mochizuki T, Endo S, Imai E, Tanji Y, Fuel, 64, 368 (1985)
Kim JJ, Park MH, Kim C, Korean J. Chem. Eng., 18(1), 94 (2001)
Lee WJ, Kim SD, Fuel, 74, 1387 (1995)
Nahas NC, Fuel, 62, 1564 (1983)
Riley RK, Judd MR, Chem. Eng. Commun., 62, 151 (1987)
Saffer MOA, Ferrell JK, Int. Chem. Eng., 28, 46 (1988)
Song BH, Kim SD, Fuel, 72(6), 797 (1993)
Sue-A-Quan TA, Watkinson AP, Gaikward RP, Ferris BR, Fuel Process. Technol., 27, 67 (1991)
Tomita A, Watanabe Y, Takarada T, Ohtsuka Y, Tamai Y, Fuel, 64, 795 (1985)
Watkinson AP, Cheng G, Lim CJ, Can. J. Chem. Eng., 65, 791 (1987)
Wathinson AP, Cheng G, Prakash CB, Can. J. Chem. Eng., 61, 468 (1983)

[Referenced By]

[Related Articles]

[1] Choi KH, Lee WY, Rhee HK, Moon SH, Lee HI, Korean J. Chem. Eng., 10(2), 78 (1993)

[2] Dhirendra MV, Awasthi SK, Pandey GN, Energy, 11, 563 (1986)

[3] Foong SK, Cheng G, Watkinson AP, Can. J. Chem. Eng., 59, 625 (1981)

[4] Gutierrez LA, Watkinson AP, Fuel, 61, 133 (1982)

[5] Kikuchi K, Suzuki A, Mochizuki T, Endo S, Imai E, Tanji Y, Fuel, 64, 368 (1985)

[6] Kim JJ, Park MH, Kim C, Korean J. Chem. Eng., 18(1), 94 (2001)

[7] Lee WJ, Kim SD, Fuel, 74, 1387 (1995)

[8] Nahas NC, Fuel, 62, 1564 (1983)

[9] Riley RK, Judd MR, Chem. Eng. Commun., 62, 151 (1987)

[10] Saffer MOA, Ferrell JK, Int. Chem. Eng., 28, 46 (1988)

[11] Song BH, Kim SD, Fuel, 72(6), 797 (1993)

[12] Sue-A-Quan TA, Watkinson AP, Gaikward RP, Ferris BR, Fuel Process. Technol., 27, 67 (1991)

[13] Tomita A, Watanabe Y, Takarada T, Ohtsuka Y, Tamai Y, Fuel, 64, 795 (1985)

[14] Watkinson AP, Cheng G, Lim CJ, Can. J. Chem. Eng., 65, 791 (1987)

[15] Wathinson AP, Cheng G, Prakash CB, Can. J. Chem. Eng., 61, 468 (1983)