Research on Ethylene and Propylene Formation during Catalytic Pyrolysis of Methylcyclohexane 被引量：3

Research on Ethylene and Propylene Formation during Catalytic Pyrolysis of Methylcyclohexane

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摘要 The influence of operating parameters and type of zeolite catalysts on formation of ethylene and propylene during catalytic pyrolysis of methylcyclohexane (MCH) was studied in a laboratory fixed fluidized bed reactor. The results indicated that higher reaction temperature and lower WHSV tended to produce more ethylene and propylene, among which the reaction temperature was an important factor influencing the ethylene formation. Compared with the FAU and BEA type zeolites, the MFI structured zeolite catalyst, thanks to more acid sites and smaller pore diameter of the catalyst, was conducive to the formation of ethylene and propylene. The protonation occurred on different C—C bonds and C—H bonds in the carbon chain of MCH led to different product slates, and the protonation on C—C bonds located at naphthenic ring was favorable to the formation of ethylene and propylene. The influence of operating parameters and type of zeolite catalysts on formation of ethylene and propylene dur- ing catalytic pyrolysis of methylcyclohexane （MCH） was studied in a laboratory fixed fluidized bed reactor. The results indicated that higher reaction temperature and lower WHSV tended to produce more ethylene and propylene, among which the reaction temperature was an important factor influencing the ethylene formation. Compared with the FAU and BEA type zeolites, the MFI structured zeolite catalyst, thanks to more acid sites and smaller pore diameter of the catalyst, was con- ducive to the formation of ethylene and propylene. The protonation occurred on different C--C bonds and C--H bonds in the carbon chain of MCH led to different product slates, and the protonation on C---C bonds located at naphthenic ring was favorable to the formation of ethylene and propylene.

作者 Yu Shan Zhang Jiushun Wei Xiaoli

机构地区 Research Institute of Petroleum Processing

出处《China Petroleum Processing & Petrochemical Technology》 SCIE CAS 2012年第4期73-79,共7页 中国炼油与石油化工（英文版）

基金 the financial support of the National Key Technology R & D Program of China (NO.2012BAE05B01)

关键词甲基环己烷环乙烯丙烯催化裂解沸石催化剂流化床反应器反应温度催化热裂解 methylcyclohexane catalytic pyrolysis ethylene propylene reaction pathway

分类号 TQ221.21 [化学工程—有机化工]

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参考文献11

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Research on Ethylene and Propylene Formation during Catalytic Pyrolysis of Methylcyclohexane 被引量：3

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