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密闭环境下含铝炸药爆炸场温度与压力特征()

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《爆破器材》[ISSN:1001-8352/CN:32-1163/TJ]

卷:: 43
期数:: 2014年02

页码:: 1-4

栏目:: 基础理论

出版日期:: 2014-04-20

文章信息/Info

Title:: Characteristics of Blasting Temperature and Pressure of Aluminized Explosive in Confined Conditions

文章编号:: 4723

作者:: 李媛媛; 徐洪涛; 西安近代化学研究所(陕西西安,710065）

Author(s):: LI Yuanyuan; XU Hongtao; Xian Modern Chemistry Research Institute(Shaanxi Xian, 710065)

关键词:: 含铝炸药; 爆炸场; 温度; 压力

Keywords:: aluminized explosive; blast field; temperature; pressure

分类号:: TJ55；TJ530.6

DOI:: 10.3969/j.issn.1001-8352.2014.02.001

文献标志码:: A

摘要:: 通过对不同铝粉质量分数的炸药爆炸场温度、压力参数的测量，研究了在密闭条件下，炸药爆炸场温度、压力的响应特征及响应规律。结果表明，在密闭条件下，含铝炸药爆炸场温度高于理想单质炸药，铝粉质量分数的增加可提高爆炸场温度及延长温度持续时间。当铝粉质量分数为40%时，爆炸温度出现最大值，其值大约在850℃左右。相比之下，含铝炸药的爆炸场压力虽远不及理想单质炸药，但当铝粉质量分数为40%时，其超压存在一个较大值。

Abstract:: The temperature and pressure parameters of explosives at different aluminum contents in blast fields were measured, and the blast performance of explosive in terms of blast temperature,pressure response characteristic and response rules in confined condition was investigated. The results show that the blast temperature of aluminized explosive is much higher than that of ideal single explosive in confined condition, and the temperature is higher and the duration is longer when increasing the aluminum content. When the proportion of Al is 40%, the blasting temperature reaches a maximum value of about 850℃. On the other hand, the pressure of aluminized explosive is obviously low compared to the ideal single explosives, however,its overpressure can attain to a higher valuein the addition of 40% Al powder.

参考文献/References:

［1］Schaefer R A．Development and evaluation of new high blast explosives［C］//36th International ICTConference. Karlsruhe，Germany，2005．
［2］Hall S D, Davis A R. Detonation calorimeter charac-terization of various explosive compositions［C］//Thirty fifth International Pyrotechnics Seminar fort Collins. Colorado, 2008: 319-329.
［3］Hall S, Knowlton G D. Development, characterization and testing of high blast thermobaric compositions［C］//Proceedings of the 31th International Pyrotechnics Seminar. Fort Collins, 2004: 663-678.
［4］Johnson N, Carpenter P, Newman K. Evaluation of explosive candidates for a thermobaric M72 law shoulder launched weapon［C］//NDIA 39th Annual Gun & Ammunition/ Missiles & Rockets Conference, 2004.
［5］Smith D K T. Pressable thermobaric explosives. Aluminum containing compositions based on HMX and RDX［C］// 36th International ICTConference. Karlsruhe,Germany,2005:125.
［6］郑孟菊，俞统昌，张银亮．炸药的性能及测试技术［M］．北京：兵器工业出版社,1990.
［7］Davis A R, Hall S D, Knowlton G D. Detonation calorimeter: application and operation for thermobaric explosive characterization and evaluation ［C］ // Proceedings of the 36th North American Thermal Analysis Society Conference. 2009:1-12.
［8］姬建荣，苏建军，刘艳萍，等. 非理想炸药爆炸热作用的实验研究［J］. 火炸药学报，2010,33（4）：49-52.
Ji Jianrong, Su Jianjun, Liu Yanping, et al. Experimental study on explosive thermal effect of the nonideal explosive［J］. Chinese Journal of Explosives and Propellants. 2010, 33(3): 49-52.
［9］张守中. 爆炸基本原理［M］．北京：国防工业出版社,1988.
［10］李媛媛，王建灵，徐洪涛. Al-HMX混合炸药爆炸场温度的实验研究［J］.含能材料，2008,16(3):241-243. Li Yuanyuan，Wang Jianling，Xu Hongtao. Experimental study on blasting temperature of AIHMX compound explosive［J］. Chinese Journal of Energetic Materials, 2008,16(3):241-243.
［11］孙业斌,等.军用混合炸药［M］.北京：兵器工业出版社, 1995. 
［12］李芝绒，王胜强，殷俊兰. 不同气体环境中温压炸药爆炸特性的试验研究［J］. 火炸药学报，2013，36（3）:59-61.
Li Zhirong, Wang Shengqiang, Yin Junlan. Experiment study of blast performance of thermobaricexplosive under different gas environment.［J］. Chinese Journal of Explosives and Propellants, 2013, 36(3):59-61.

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备注/Memo

备注/Memo:: 收稿日期： 2013-10-19
基金项目：国防科技工业基础产品创新计划（火炸药基础专项）
作者简介：李媛媛（1981~），硕士，助理研究员，主要从事混合炸药配方及工艺研究。E-mail:liyuan204@126.com

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更新日期/Last Update: 2014-04-17