About The Journal
  Aims and Scope
  Editorial Board
  Submit a Manuscript 
  Subscription Information
  Guidelines for Publication
  Ethics
Articles & Issues
  Search
  Issue
  Online First
  KJChE on
For Authors
  Instructions to Authors
  Ethical Responsibilities of
  Authors in KJChE
  Ethics in Publishing
  Peer Review Process
  Author's Checklist
  Copyright Transfer Form
Contact us
 
 
 
Issue
Korean Journal of Chemical Engineering,
Vol.39, No.12, 3204-3213, 2022
Process modeling of syngas conversion to ethanol and acetic acid via the production of dimethyl ether and its carbonylation
Kim SW, Jung HS, Lee WB, Bae JW, Park MJ
A process model was developed to simulate the generation of ethanol or acetic acid by selectively using syngas from coke oven gas as the carbon source. The simulation involved three reactors: the first reactor converts syngas into dimethyl ether over a hybrid Cu/ZnO/Al2O3/ferrierite catalyst; in the second reactor, carbonylation of dimethyl ether to methyl acetate takes place. The kinetic parameters for the carbonylation reaction were estimated by fitting the model to the experimental results. The third reactor uses the hydrogenation or hydrolysis of the methyl acetate to selectively synthesize ethanol or acetic acid, respectively. In the integrated process, a recycling loop was introduced, and its effects on the conversion, carbon molar yield, energy consumption, and capital and utility costs were evaluated. The results show that the recycling loop could enhance the carbon molar yield by approximately 20 times compared to that in the open-loop case owing to the high overall conversion (91-97%) of dimethyl ether in the second reactor.
Keywords: Carbonylation of Dimethyl Ether; Methyl Acetate; Kinetic Parameter Estimation; Process Modeling and Optimization
[References]
  1. Li Y, Huang S, Cheng Z, Wang S, Ge Q, Ma X, J. Catal., 365, 440, 2018
  2. Yue H, Ma X, Gong J, Acc. Chem. Res., 47, 1483, 2014
  3. Amao Y, Shuto N, Iwakuni H, Appl. Catal. B: Environ., 180, 403, 2016
  4. Zhou H, Zhu W, Shi L, Liu H, Liu S, Ni Y, Liu Y, He Y, Xu S, Li L, J. Mol. Catal. A-Chem., 417, 1, 2016
  5. Zhao N, Tian Y, Zhang L, Cheng Q, Lyu S, Ding T, Hu Z, Ma X, Li X, Chin. J. Catal., 40, 895, 2019
  6. Wang X, Li R, Yu C, Liu Y, Zhang L, Xu C, Zhou H, Fuel, 239, 794, 2019
  7. Liu Y, Murata K, Inaba M, Takahara I, Fuel Process. Technol., 110, 206, 2013
  8. Shen H, Li Y, Huang S, Cai K, Cheng Z, Lv J, Ma X, Catal. Today, 330, 117, 2019
  9. Subramani V, Gangwal SK, Energy Fuels, 22, 814, 2008
  10. Yoneda N, Kusano S, Yasui M, Pujado P, Wilcher S, Appl. Catal. A: Gen., 221, 253, 2001
  11. Pal P, Nayak J, Sep. Purif. Rev., 46, 44, 2017
  12. Wang Y, Zhao Y, Lv J, Ma X, ChemCatChem., 9, 2085, 2017
  13. Huang X, Ma M, Miao S, Zheng Y, Chen M, Shen W, Appl. Catal. A: Gen., 531, 79, 2017
  14. Zhang F, Chen Z, Fang X, Liu H, Liu Y, Zhu W, J. Energy Chem., 61, 203, 2021
  15. Shigematsu A, Yamada T, Kitagawa H, J. Am. Chem. Soc., 134, 13145, 2012
  16. Pulyalinа AY, Polotskaya GA, Veremeychik KY, Goikhman MY, Podeshvo IV, Toikka AM, Fuel Process. Technol., 139, 178, 2015
  17. Dong Y, Dai C, Lei Z, Ind. Eng. Chem., 57, 11167, 2018
  18. Pöpken T, Götze L, Gmehling J, Ind. Eng. Chem., 39, 2601, 2000
  19. Yu W, Hidajat K, Ray AK, Appl. Catal. A: Gen., 260, 191, 2004
  20. He T, Liu X, Xu S, Han X, Pan X, Hou G, Bao X, J. Phys. Chem. C, 120, 22526, 2016
  21. Zhan H, Huang S, Li Y, Lv J, Wang S, Ma X, Catal. Sci. Technol., 5, 4378, 2015
  22. Junlong L, Huifu X, Huang X, Pei-Hao W, Huang SJ, Shang-Bin L, Wenjie S, Chin. J. Catal., 31, 729, 2010
  23. Liu Y, Murata K, Inaba M, React. Kinet. Mech. Catal., 117, 223, 2016
  24. Sunley GJ, Watson DJ, Catal. Today, 58, 293, 2000
  25. Cheung P, Bhan A, Sunley GJ, Law DJ, Iglesia E, J. Catal., 245, 110, 2007
  26. Rasmussen DB, Christensen JM, Temel B, Studt F, Moses P, Rossmeisl J, Riisager A, Jensen AD, Catal. Sci. Technol., 7, 1141, 2017
  27. Zhan E, Xiong Z, Shen W, J. Energy Chem., 36, 51, 2019
  28. Park J, Woo Y, Jung HS, Yang H, Lee WB, Bae JW, Park MJ, Catal. Today, 388-389, 323, 2022
  29. Jun HJ, Park MJ, Baek SC, Bae JW, Ha KS, Jun KW, J. Nat. Gas Chem., 20, 9, 2011
  30. Park N, Park MJ, Lee YJ, Ha KS, Jun KW, Fuel Process. Technol., 125, 139, 2014
  31. Jung HS, Zafar F, Wang X, Nguyen TX, Hong CH, Hur YG, Choung JW, Park MJ, Bae JW, ACS Catal., 11, 14210, 2021
  32. Douglas JM, Conceptual design of chemical processes, Mc-Graw- Hill, New York (1988).
  33. Kim S, Kim Y, Oh SY, Park MJ, Lee WB, J. Nat. Gas Sci. Eng., 96, 104308, 2021
  34. Turton R, Bailie RC, Whiting WB, Shaeiwitz JA, Bhattacharyya D, Analysis, synthesis, and design of chemical processes, Prentice Hall, New Jersey (2018).
  35. Diemer RB, Luyben WL, Ind. Eng. Chem. Res., 49, 12224, 2010
  36. Ham H, Jung HS, Kim HS, Kim J, Cho SJ, Lee WB, Park MJ, Bae JW, ACS Catal., 10, 5135, 2020
참고문헌정보(참고문헌, 인용문헌)는 화학공학소재연구정보센터에 의해 제공되고 있습니다.