Inherently safer reactors and procedures to prevent reaction runaway

doi:10.1016/j.cjche.2018.03.017

Abstract

Abstract: Reaction runaway has longtime been an issue in chemical industry as it often leads to severe accidents if not controlled and inhibited properly. Herein we have reviewed several key considerations and procedures to prevent such phenomena, including inherently safer reactor design, thermal risk assessment and early warning detection of runaway, and pointed out that the basic principle underlying is necessary heat management and construction of resilient processes. For inherently safer reactor design, important factors such as heat removal, heat capacitance, flow behaviors and explosive behaviors have been investigated. The survey shows that heat exchanger (HEX) reactor and microreactor outperform traditional reactors. Meanwhile, we have looked into the effect of thermal risk ranking and safety operation region determining for thermal risk assessment, and the influence of runaway criteria and construction methods for early detection of reaction runaway as well. It shows that thermal risk assessment plays a key role on process design, and early warning detection system (EWDS) is preferable on prevention of reaction runaway. In the end, perspectives regarding inherently safer designs with the measures discussed above have been provided.

Key words: Reaction runaway, Safety, Chemical reactor, Heat transfer, Thermal risk assessment, Early warning detection

摘要： Reaction runaway has longtime been an issue in chemical industry as it often leads to severe accidents if not controlled and inhibited properly. Herein we have reviewed several key considerations and procedures to prevent such phenomena, including inherently safer reactor design, thermal risk assessment and early warning detection of runaway, and pointed out that the basic principle underlying is necessary heat management and construction of resilient processes. For inherently safer reactor design, important factors such as heat removal, heat capacitance, flow behaviors and explosive behaviors have been investigated. The survey shows that heat exchanger (HEX) reactor and microreactor outperform traditional reactors. Meanwhile, we have looked into the effect of thermal risk ranking and safety operation region determining for thermal risk assessment, and the influence of runaway criteria and construction methods for early detection of reaction runaway as well. It shows that thermal risk assessment plays a key role on process design, and early warning detection system (EWDS) is preferable on prevention of reaction runaway. In the end, perspectives regarding inherently safer designs with the measures discussed above have been provided.

关键词: Reaction runaway, Safety, Chemical reactor, Heat transfer, Thermal risk assessment, Early warning detection

Yi Fei, Bing Sun, Fan Zhang, Wei Xu, Ning Shi, Jie Jiang. Inherently safer reactors and procedures to prevent reaction runaway[J]. Chin.J.Chem.Eng., 2018, 26(6): 1252-1263.

Yi Fei, Bing Sun, Fan Zhang, Wei Xu, Ning Shi, Jie Jiang. Inherently safer reactors and procedures to prevent reaction runaway[J]. Chinese Journal of Chemical Engineering, 2018, 26(6): 1252-1263.

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