Isomerization of n-pentane catalyzed by amide-AlCl3-based ionic liquid analogs with various additives

doi:10.1016/j.cjche.2019.04.018

Abstract

Abstract: The isomerization of n-pentane to generate high-quality blending components for clean gasoline was catalyzed by several amide-AlCl₃-based ionic liquid (IL) analogs with various amides as donor molecules. The catalytic performance of these IL analogs was evaluated in a magnetic agitated autoclave operated in batch mode. IL analog based n-methylacetamide (NMA)-AlCl₃ with the amide/AlCl₃ molar ratio of 0.65 showed excellent performance toward n-pentane isomerization because 0.65NMA-1.0AlCl₃ had a low viscosity and bidentate coordination structure. The influences of reaction time, reaction temperature, and stirring speed on the catalytic performance were also investigated. Optimal reaction conditions comprised the reaction time of 1 h, the reaction temperature of 40℃, and the stirring speed of 1500 r·min^-1. Under optimal condition, the n-C5 conversion, research octane number (RON) increment, total liquids yield, and isoparaffin yield in isomerized oil were 56.80%, 13.51, 89.90 wt%, and 44.32 wt%, respectively. A new mathematical model was constructed to predict the relationships among RON increment, RON increment/n-C5 conversion ratio, and n-C5 conversion. The new model indicated that an appropriate conversion per pass of n-C5 did not exceed 50%-55%. Various cycloparaffin additives were used to improve the catalytic performance of 0.65NMA-1.0AlCl₃. The n-C5 conversion increased from 56.80% to 67.32%. The RON increment, total liquids yield, and isoparaffin yield reached 17.83, 97.36 wt%, and 63.74 wt%, respectively.

Key words: Isomerization, Ionic liquid analogs, n-Pentane, Mathematical model, Additives

摘要： The isomerization of n-pentane to generate high-quality blending components for clean gasoline was catalyzed by several amide-AlCl₃-based ionic liquid (IL) analogs with various amides as donor molecules. The catalytic performance of these IL analogs was evaluated in a magnetic agitated autoclave operated in batch mode. IL analog based n-methylacetamide (NMA)-AlCl₃ with the amide/AlCl₃ molar ratio of 0.65 showed excellent performance toward n-pentane isomerization because 0.65NMA-1.0AlCl₃ had a low viscosity and bidentate coordination structure. The influences of reaction time, reaction temperature, and stirring speed on the catalytic performance were also investigated. Optimal reaction conditions comprised the reaction time of 1 h, the reaction temperature of 40℃, and the stirring speed of 1500 r·min^-1. Under optimal condition, the n-C5 conversion, research octane number (RON) increment, total liquids yield, and isoparaffin yield in isomerized oil were 56.80%, 13.51, 89.90 wt%, and 44.32 wt%, respectively. A new mathematical model was constructed to predict the relationships among RON increment, RON increment/n-C5 conversion ratio, and n-C5 conversion. The new model indicated that an appropriate conversion per pass of n-C5 did not exceed 50%-55%. Various cycloparaffin additives were used to improve the catalytic performance of 0.65NMA-1.0AlCl₃. The n-C5 conversion increased from 56.80% to 67.32%. The RON increment, total liquids yield, and isoparaffin yield reached 17.83, 97.36 wt%, and 63.74 wt%, respectively.

关键词: Isomerization, Ionic liquid analogs, n-Pentane, Mathematical model, Additives

Pengcheng Hu, Jingwei Zheng, Wei Jiang, Lijuan Zhong, Shufeng Zhou. Isomerization of n-pentane catalyzed by amide-AlCl₃-based ionic liquid analogs with various additives[J]. Chinese Journal of Chemical Engineering, 2020, 28(1): 152-157.

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Isomerization of n-pentane catalyzed by amide-AlCl₃-based ionic liquid analogs with various additives

Isomerization of n-pentane catalyzed by amide-AlCl₃-based ionic liquid analogs with various additives

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