有机过氧化物分解机理及热危害

doi:10.3969/j.issn.0438-1157.2012.08.014

化工学报 ›› 2012, Vol. 63 ›› Issue (8): 2431-2436.DOI: 10.3969/j.issn.0438-1157.2012.08.014

• 催化、动力学与反应器 • 上一篇下一篇

有机过氧化物分解机理及热危害

孙峰1，薛岩1，谢传欣2，金满平2，黄飞2

1中国石油化工股份有限公司青岛安全工程研究院，山东青岛 266071；2国家安监局化学品登记中心，山东青岛 266071

收稿日期:2012-01-12 修回日期:2012-05-10 出版日期:2012-08-05 发布日期:2012-08-05
通讯作者: 孙峰
基金资助:
973课题：化学品储运安全基础研究

Decomposition kinetics and thermal hazard of organic peroxides

SUN Feng1，XUE Yan1，XIE Chuanxin2，JIN Manping2，HUANG Fei2

Received:2012-01-12 Revised:2012-05-10 Online:2012-08-05 Published:2012-08-05

摘要/Abstract

摘要： 为了预防及控制有机过氧化物的分解爆炸事故，需要对其热危害进行必要的评估。利用塞塔姆C80微量热仪对不同种类的9种有机过氧化物进行热扫描测试，并分别利用n级反应模型及自催化反应模型对扫描曲线进行拟合，准确得到了这些物质的分解热及分解机理。根据反应动力学数据，采用Semenov爆炸模型及联合国H.3-等温储存试验原理，得到了9种有机过氧化物的临界温度及自加速分解温度（SADT）。结果表明，大部分有机过氧化物分解遵循n级反应模型，反应级数在1左右，少部分有机过氧化物分解时有一定的自催化效应。所得的SADT数据与文献值符合较好，证明本文动力学模拟及SADT计算方法的科学性。

关键词: 有机过氧化物, 自加速分解温度, 热危害, 反应机理, 自催化

Abstract: The thermal hazard of organic peroxides should be assessed to predict and avoid runaway decomposition.In this paper，the Setaram C80 was used to investigate thermal decomposition of several organic peroxides such as cumene hydroperoxide(CHP)，tert-butyl hydroperoxide(TBHP)，dicumyl peroxide(DCP)，di-tert-butyl peroxide(DTBP)，benzoyl peroxide(BPO)，tert-butyl peroxybenzoate(TBPB)，methyl ethyl ketone peroxide(MEKP)，2,5-dimethyl-2,5-di(tert-butylperoxy)hexane(DHBP)and 1,1-di-(tert-butylperoxy)-3,3,5-trimethylcyclohexane(TMCH).Decomposition heat of the organic peroxides was calculated from isothermal scanning curves.The nth-order or autocatalytic reaction kinetics model was established for these organic peroxides，and self accelerating decomposition temperature(SADT)was derived by using Semenov model.The results showed that decomposition of the organic peroxides mostly followed nth-order model with approximate reaction order of 1，however，some of them preferred to autocatalytic model.The SADT of the organic peroxides calculated was in good agreement with values from literatures，demonstrating reaction kinetics fitting and SADT calculating in this paper are of scientific.

Key words: organic peroxide, self accelerating decomposition temperature, thermal hazard, reaction kinetics, autocatalytic

中图分类号:

TQ047

孙峰1，薛岩1，谢传欣2，金满平2，黄飞2. 有机过氧化物分解机理及热危害[J]. 化工学报, 2012, 63(8): 2431-2436.

SUN Feng1，XUE Yan1，XIE Chuanxin2，JIN Manping2，HUANG Fei2. Decomposition kinetics and thermal hazard of organic peroxides[J]. CIESC Journal, 2012, 63(8): 2431-2436.

参考文献 15

[1]	Duh Y,Wu X,Kao C. Hazard ratings for organic peroxides[J]. Process Safety Progress,2008,27(2): 89-99.
[2]	Fu Zhimin,Li Xinrui,Hiroshi K. Evaluation on thermal hazard of methyl ethyl ketone peroxide by using adiabatic method[J]. Journal of Loss Prevention in the Process Industries,2003,16: 389-393.
[3]	Filippis P,Giavarini C,Silla R. Thermal hazard in a batch process involving hydrogen peroxide[J]. Journal of Loss Prevention in the Process Industries,2002,15: 449-453.
[4]	United Nations. Recommendations on the transport of dangerous goods- manual of tests and criteria[M]. New York and Geneva,United Nations Publication,2009.
[5]	Kossoy A. A,Sheinman I. Ya. Comparative analysis of the methods for SADT determination[J]. Journal of Hazardous Materials,2006,
[6]	Malow M,Wehrstedt K.D. Prediction of the self-accelerating decomposition temperature(SADT) for liquid organic peroxides from differential scanning calorimetry (DSC) measurements[J]. Journal of Hazardous Materials,2005,A120: 21-24.
[7]	Yang D,Koseki H,Hasegawa K. Predicting the self-accelerating decomposition temperature (SADT) of organic peroxides based on non-isothermal decomposition behavior[J]. Journal of Loss Prevention in the Process Industries,2003,16: 411-416.
[8]	SUN Zhanhui（孙占辉）,WANG Yu（王瑜）,SUN Jinhua（孙金华）. Evaluation of autoignition of organic peroxides with small sample mass[J]. Chinese Journal of Applied Chemistry,2005,22(1): 1-4.
[9]	Sun Jinhua,Li Yongfu,Hasegawa K. A study of self-accelerating decomposition temperature (SADT) using reaction calorimetry[J]. Journal of Loss Prevention in the Process Industries,2001,14: 331-336.
[10]	Li Xinrui,Koseki H. SADT prediction of autocatalytic material using isothermal calorimetry analysis[J]. Thermochimica Acta,2005,431: 113-116.
[11]	Li Xinrui,Koseki H. Thermal decomposition kinetic of liquid organic peroxides[J]. Journal of Loss Prevention in the Process Industries,2005,18: 460-464.
[12]	DING Li(丁立),ZHANG Lijing(张礼敬),SHENG Yingxia(生迎夏),et al. SADT calculation of solid organic peroxides based on small sample mass of heterogeneous reaction[J]. CIESC Journal,2009,60(4): 1062-1067.
[13]	SUN Jinhua(孙金华),LU Shouxiang(陆守香),SUN Zhanhui(孙占辉). Study on thermal risk evaluation of reactive substance[J]. China Safety Science Journal,2003,13(4): 44-47.
[14]	J?rg Pastré,Udo W?rsd?rfer,Andreas Keller,et al. Comparison of different methods for estimating TMRad from dynamic DSC measurements with ADT24 values obtained from adiabatic Dewar experiments[J]. Journal of Loss Prevention in the Process Industries,2007,13(1): 7-17.
[15]	United initiators. Safety data sheet[EB/OL]. http://www.united-initiators.com/

有机过氧化物分解机理及热危害

Decomposition kinetics and thermal hazard of organic peroxides

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