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Received August 5, 2003
Accepted November 27, 2003
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Vacuum Swing Adsorption Process for the Separation of Ethylene/Ethane with AgNO3/Clay Adsorbent
Korea Institute of Energy Research, 71-2, Jangdong, Yusungku, Daejeon 305-343, Korea
soonhcho@kier.re.kr
Korean Journal of Chemical Engineering, January 2004, 21(1), 236-245(10), 10.1007/BF02705404
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Abstract
The performance of the 4-bed and 3-bed VSA process using AgNO3/clay adsorbent for the ethylene separation from C2 fractionator feed (83.56% C2H4, 16.44% C2H6) was investigated experimentally and theoretically. With the 4-bed VSA process, extremely high recovery of ethylene, over 99%, was obtained at ethylene purity of 99.8%. The recovery of the 3-bed process was lower about by 1% than that of the 4-bed VSA process. But, the productivity of the 3-bed VSA was higher about by 33% than that of the 4-bed VSA process. The productivity of the 3-bed VSA process was 3.7 mol/kg/hr at the ethylene purity of 99.8%. Effects of the rinse flow rate in the 3-bed VSA process were investigated by both experiment and simulation. The purity of ethylene was not significantly improved by the increase of the rinse flow rate after it reached 99.8%. At the rinse flow rate where the purity was 99.9%, the recovery became 70%. It might be attributed to the slow diffusion of ethane. According to the simulation, ethylene purity of over 99.9% could be obtained with recovery of over 90% only when the mass transfer rate of ethane is lower than 1.0 × 10-4 s-1 or higher than 0.2 s-1. The productivity of the process could be improved by increasing the feed flow rate at the expense of the recovery. According to the simulation, at the feed flow rate of 5,000 ml/min, the productivity of 5.2 mol/kg/hr was obtained at the ethylene purity of 99.5%.
Keywords
References
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Choi WK, Kwon TI, Yeo YK, Lee H, Song HK, Na BK, Korean J. Chem. Eng., 20(4), 617 (2003)
Choudary NV, Kumar P, Bhat TSG, Cho SH, Han SS, Kim JN, Ind. Eng. Chem. Res., 41(11), 2728 (2002)
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Gilliland ER, Bliss HL, Kip CE, J. Am. Chem. Soc., 63, 2088 (1941)
Han SS, Kim JN, Cho SH, Choudary NV, Kumar P, Bhat SGT, "Adsorbents for Light Alkane/Alkene Separation," The 8th APPChE Congress, Aug. 16-19, Seoul, Korea, 1777 (1999)
Hirai H, "Polymers Complex for the Separation of Carbon Monoxide and Ethylene," Polymers for Gas Separation, Chap. 7, Toshima, N. ed., VCH Publishers, New York, 221 (1992)
Hirai H, Hara S, Komiyama M, Angew. Makromol. Chem., 130, 207 (1985)
Ho WS, Doyle G, Savage DW, Pruett RL, Ind. Eng. Chem. Res., 27, 334 (1988)
Keller GE, Marcinkowsky AE, Verma SK, Williamson KD, "Olefin Recovery and Purification via Silver Complexation," Separation and Purification Technology, Chap. 3, Li, N.N. and Calo, J.M. eds., Dekker, New York (1992)
King CJ, "Separation Process Based on Reversible Chemical Complexation," Handbook of Separation Process Technology, Rousseau, R.W. ed., Chap. 15, Wiley, New York (1987)
Ramachandran R, Dao LH, Brook B, "Method Producing Unsaturated Hydrocarbons and Separating the Same from Saturated Hydrocarbons," U.S. Patent, 5,365,011 (1998)
Rege SU, Padin J, Yang RT, AIChE J., 44(4), 799 (1998)
Rege SU, Yang RT, Chem. Eng. Sci., 57(7), 1139 (2002)
Wu ZB, Han SS, Cho SH, Kim JN, Chue KT, Yang RT, Ind. Eng. Chem. Res., 36(7), 2749 (1997)
Yang RT, Kikkinides ES, AIChE J., 41(3), 509 (1995)
