Simulation of Cumene Synthesis by Suspension Catalytic Distillation

Er Qiang Wang; Cheng Yue Li; Lang You Wen; Ze Xue Du; Yong Qiang Zhang

doi:10.4028/www.scientific.net/AMR.557-559.2243

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 557-559Simulation of Cumene Synthesis by Suspension...

Simulation of Cumene Synthesis by Suspension Catalytic Distillation

Abstract:

This paper deals with alkylation of benzene with propylene to produce cumene by Suspension Catalytic Distillation (SCD) which, as a new technology of process intensification, has been developed from traditional catalytic distillation. In this SCD process, the supported heteropolyacid catalysts are suspended inside the liquid phase on the column tray and flow with them, while in traditional catalytic distillation the catalyst pellets are generally fixed somewhere inside the column. SCD processes have been investigated for alkylation reaction of benzene with olefins in laboratorial scale. A pilot plant of SCD process for cumene synthesis had been run for several months. It has shown more advantageous characteristics for cumene synthesis compared with conventional process consisting of a reactor followed by distillation train. Based on experimental data and the reactive kinetic parameters of cumene synthesis using the supported heteropolyacid catalysts, numerical simulation of SCD process of the pilot plant was performed by an equilibrium stage model to study the effects of operation conditions on the process performance. The simulation results could agree, to a great extent, with the data acquired from the pilot plant experiment.

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Periodical:

Advanced Materials Research (Volumes 557-559)

Pages:

2243-2248

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.557-559.2243

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Online since:

July 2012

Authors:

Er Qiang Wang, Cheng Yue Li, Lang You Wen, Ze Xue Du, Yong Qiang Zhang

Keywords:

Alkylation, Cumene, Heteropoly Acid Catalyst, Simulation, Suspension Catalytic Distillation

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References

[1] Alberto de Angelis, Stefano Amarilli, Donatella Berti, Luciano Montanari, Carlo Perego. Alkylation of benzene catalysed by supported heteropolyacids. Journal of Molecular Catalysis A: Chemical. 1999; 146(1):37–44.

DOI: 10.1016/s1381-1169(99)00078-3

Google Scholar

[2] Geatti A., Lenarda M.1, Storaro L.,Ganzerla R., Perissinotto M. Solid acid catalysts from clays: Cumenesynthesis by benzene alkylation with propene catalyzed by cation exchanged aluminum pillared clays. Journal of Molecular Catalysis A: Chemical. 1997; 121(1): 111–118.

DOI: 10.1016/s1381-1169(96)00455-4

Google Scholar

[3] S. Siffert, L. Gaillard, B.-L.Su. Alkylation of benzene by propene on a series of Beta zeolites: toward a better understanding of the mechanisms. Journal of Molecular Catalysis A: Chemical. 2000;153(1):267–279.

DOI: 10.1016/s1381-1169(99)00357-x

Google Scholar

[4] Taylor, R., and Krishna, R. Modelling reactive distillation. Chem.Eng.Sci, 2000; 55: 5183–5229.

Google Scholar

[5] J. Chen, in: Worldside Solid Acid Processes Conference, Houston, TX, November 1–16, 1993.

Google Scholar

[6] Wen Langyou, Min Enze, and Pang Guici. Synthesis of cumene by suspension catalytic distillation process. Journal of Chemical Industry and Engineering (China).2000;1: 115-119.

Google Scholar

[7] Wang Er-qiang, Li Cheng-yue. Simulation of suspension catalytic distillation for synthesis of linear alkylbenzene. Chinese J. Chem. Eng. 2003; 11(5): 520-525.

Google Scholar

[8] Wang Erqiang, Li Chengyue. Study on Suspension Catalytic Distillation for Synthesis of Linear Alkylbenzene. AIChE.J. 2005; 51(3):845-853.

DOI: 10.1002/aic.10324

Google Scholar

[9] He Mingyuan, et al. Green Chemistry for Petroleum Refining and Synthesis of Basic Organic Chemicals. Beijing: China Petrochemical Press;(2006)

Google Scholar

[10] Robert C. Reid, John M. Prausnitz, Bruce E. Poling. The properties of gases and liquids. 4th ed., New York: McGraw-Hill; (1987)

Google Scholar

[11] Ma Peisheng. Handbook of Petrochemical Data. Beijing: Chemical Industry Press;(1993)

Google Scholar