Simulation of fixed bed reactor for dimethyl ether synthesis

Shin Beom Lee; Wonjun Cho; Dal Keun Park; En Sup Yoon

Korean Journal of Chemical Engineering, Vol.23, No.4, 522-530, July, 2006

DOI10.1007/BF02706789 Export Citation

Simulation of fixed bed reactor for dimethyl ether synthesis

Shin Beom Lee, Wonjun Cho¹, Dal Keun Park , and En Sup Yoon^†

School of Chemical Engineering, Seoul National University, San 56-1 Sillim-dong, Gwanak-gu, Seoul 151-742, Korea
¹LNG Technology Research Center, KOGAS, Dongchun-dong, Yeonsu-gu, Incheon 406-130, Korea

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Dimethyl Ether (DME) is considered as one of the most promising candidates for a substitute for LPG and diesel fuel. We analyzed one-step DME synthesis from syngas in a shell and tube type fixed bed reactor with consideration of the heat and mass transfer between catalyst pellet and reactants gas and effectiveness factor of catalysts together with reactor cooling through reactor wall. Simulation results showed strong effects of pore diffusion. We compared two different arrangements of catalysts, mixture of catalyst pellets (methanol synthesis catalyst and methanol dehydration catalyst) and hybrid catalyst. Hybrid catalyst gave better performance than a mixture of pellets in terms of CO conversion and DME productivity, but more difficulties with reactor temperature control. Use of inert pellets and inter-cooling was also simulated as a means of controlling maximum reactor temperature.

Keywords:Reactor;Modelling;Dimethyl Ether;DME;Fixed Bed;Simulation;Effectiveness Factor

[References]

Bercic G, Levec J, Ind. Eng. Chem. Res., 31, 1035 (1992)
Cengel, Heat transfer a practical approach, McGrawHill (1998)
Kunii D, Levenspiel O, Fluidization engineering, 2nd, Wiley (1990)
Lu WZ, Teng LH, Xiao WD, Chem. Eng. Sci., 59(22-23), 5455 (2004)
McCabe WL, Smith JC, Harriott P, Unit operations of chemical engineering, 5th, McGrawHill (1995)
Ng KL, Chadwick D, Toseland BA, Chem. Eng. Sci., 54(15-16), 3587 (1999)
Riggs JM, An introduction to numerical methods for chemical engineers, Texas Tech University Press (1994)
Satterfield CN, Mass transfer in heterogeneous catalysis, M.I.T. Press (1970)
Stull DR, Westrum EF, Sinke GC, The chemical thermodynamics of organic compounds, John Wiley & Sons Inc (1969)
Twigg MV, Catalyst handbook, 2nd, Wolfe (1986)
Vandenbussche KM, Froment GF, J. Catal., 161(1), 1 (1996)
Welty JR, Wicks CE, Wilson RE, Fundamentals of momentum, heat and mass transfer, 3rd, Wiley (1976)

[Referenced By]

[Related Articles]

[1] Bercic G, Levec J, Ind. Eng. Chem. Res., 31, 1035 (1992)

[2] Cengel, Heat transfer a practical approach, McGrawHill (1998)

[3] Kunii D, Levenspiel O, Fluidization engineering, 2nd, Wiley (1990)

[4] Lu WZ, Teng LH, Xiao WD, Chem. Eng. Sci., 59(22-23), 5455 (2004)

[5] McCabe WL, Smith JC, Harriott P, Unit operations of chemical engineering, 5th, McGrawHill (1995)

[6] Ng KL, Chadwick D, Toseland BA, Chem. Eng. Sci., 54(15-16), 3587 (1999)

[7] Riggs JM, An introduction to numerical methods for chemical engineers, Texas Tech University Press (1994)

[8] Satterfield CN, Mass transfer in heterogeneous catalysis, M.I.T. Press (1970)

[9] Stull DR, Westrum EF, Sinke GC, The chemical thermodynamics of organic compounds, John Wiley & Sons Inc (1969)

[10] Twigg MV, Catalyst handbook, 2nd, Wolfe (1986)

[11] Vandenbussche KM, Froment GF, J. Catal., 161(1), 1 (1996)

[12] Welty JR, Wicks CE, Wilson RE, Fundamentals of momentum, heat and mass transfer, 3rd, Wiley (1976)