Process hazard and decomposition mechanism of benzoyl peroxide in the presence of incompatible substances

•The effect of impurities on the thermal stability of benzoyl peroxide was investigated.•The decomposition kinetics of benzoyl peroxide as well as mixed with impurities was modeled.•The thermal runaway behavior of benzoyl peroxide was predicted under different scenarios.•The decomposition pathways o...

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Bibliographic Details
Published in:Journal of molecular liquids 2023-02, Vol.372, p.121146, Article 121146
Main Authors: Yu, Andong, Zhou, Nengcheng, Liang, Xinmiao, Hua, Min, Pan, Xuhai, Jiang, Yiming, Jiang, Juncheng
Format: Article
Language:English
Subjects:
Benzoyl peroxide
Impurities
Reaction mechanism
Thermal hazard
Thermal runaway
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Summary:•The effect of impurities on the thermal stability of benzoyl peroxide was investigated.•The decomposition kinetics of benzoyl peroxide as well as mixed with impurities was modeled.•The thermal runaway behavior of benzoyl peroxide was predicted under different scenarios.•The decomposition pathways of benzoyl peroxide in the presence of impurities were proposed. Benzoyl peroxide (BPO) is a hazardous chemical, which is incompatible with many substances. Due to its high thermal sensitivity, it reacts violently with organic chemicals and can cause serious explosions when heated. Toluene and sodium hydroxide (NaOH) are incompatible substances frequently encountered in the production and utilization of BPO. Therefore, it is necessary to investigate the thermal decomposition behavior of BPO and its reaction mechanism under the effect of impurities. In this paper, thermal decomposition behavior of BPO, the mixture of BPO and toluene, and the mixture of BPO and NaOH were studied using differential scanning calorimetry and adiabatic calorimetry under different conditions. The decomposition kinetic models were obtained to simulate thermal runaway behavior in actual package. Chromatography-Mass Spectrometry experiments were performed to examine the composition of thermal decomposition products in different systems. The results show that NaOH improves the thermal stability of BPO and toluene makes it easier for BPO decomposition. Both NaOH and toluene change the decomposition path of BPO. The consumption of benzoic acid radicals is accelerated by NaOH. Toluene makes the decomposition of BPO follow an n-order reaction by consuming phenyl radicals generated by the decomposition of BPO. This study is important for understanding thermal hazards of BPO at the reaction mechanism level and ensuring process safety in industrial processes.
ISSN:0167-7322
1873-3166
DOI:10.1016/j.molliq.2022.121146