Investigation on detonation velocity of aluminized explosives based on disequilibrium multiphase model

被引:0
|
作者
Pei, Hong-Bo [1 ]
Nie, Jian-Xin [1 ]
Qin, Jian-Feng [1 ]
机构
[1] State Key Laboratory of Explosion Science and Technology, Beijing Institute of Technology, Beijing 100081, China
来源
Baozha Yu Chongji/Explosion and Shock Waves | 2013年 / 33卷 / 03期
关键词
Relaxation time;
D O I
暂无
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
Based on the calculations on the powdered aluminum pressure and temperature relaxation times in the detonation zone, the conventional CJ model was improved to propose a new multiphase flow model by considering the multiphase detonation products as well as the thermal disequilibrium in them. The proposed model was applied to calculate the detonation velocities of several aluminized explosives. The calculated results were compared with the existent experimental ones. And the corresponding error is less than 2%. So the calculated results by the new model are better than those by the conventional CJ model.
引用
收藏
页码:311 / 314
相关论文
共 50 条
  • [31] Research on the quasi-isentropic driving model of aluminized explosives in the detonation wave propagation direction
    Hongfu Wang
    Yan Liu
    Fan Bai
    Chao He
    Yingliang Xu
    Qiang Zhou
    Chuan Xiao
    Fenglei Huang
    [J]. Defence Technology, 2024, 32 (02) : 596 - 618
  • [32] Detonation velocity of precompressed emulsion explosives
    Sumiya, F
    Hirosaki, Y
    Kato, Y
    [J]. PROCEEDINGS OF THE TWENTY-EIGHTH ANNUAL CONFERENCE ON EXPLOSIVES AND BLASTING TECHNIQUE, VOL II, 2002, : 253 - 263
  • [33] Influence of overdriven detonation on the energy release of aluminized explosives in underwater explosion
    Shan, Feng
    Jiao, Jun-jie
    Wang, Han-cheng
    Wang, Jia-xing
    Qi, Yanjie
    Gao, Zhan-bo
    Chen, Peng
    Fang, Zhong
    Pan, Xu-chao
    He, Yong
    [J]. PHYSICS OF FLUIDS, 2023, 35 (09)
  • [34] The cylinder test and JWL equation of state detonation product of aluminized explosives
    Chen, L.
    Feng, C.
    Huang, Y.
    [J]. Huozhayao Xuebao/Chinese Journal of Explosives and Propellants, 2001, 24 (03): : 13 - 15
  • [35] Algorithm and Computer Code for Predicting Detonation Wave Parameters of Aluminized Explosives
    Trung, Toan Nguyen
    Trung, Huu Hoang
    Quang, Sang Dam
    [J]. DEFENCE SCIENCE JOURNAL, 2022, 72 (04) : 526 - 532
  • [36] Simple Model for Predicting the Detonation Velocity of Organic, Inorganic, and Mixed Explosives
    Sivapirakasam, S. P.
    Kumar, N. Venu
    Jeyabalaganesh, G.
    Nagarjuna, K.
    [J]. COMBUSTION EXPLOSION AND SHOCK WAVES, 2021, 57 (06) : 726 - 735
  • [37] Simple Model for Predicting the Detonation Velocity of Organic, Inorganic, and Mixed Explosives
    S. P. Sivapirakasam
    N. Venu Kumar
    G. Jeyabalaganesh
    K. Nagarjuna
    [J]. Combustion, Explosion, and Shock Waves, 2021, 57 : 726 - 735
  • [38] A non-isentropic model and the method of characteristic line for the post-detonation expansion of aluminized explosives
    Yuan, Xiaoxia
    Wu, Cheng
    An, Fengjiang
    Liao, Shasha
    Zhou, Mingxue
    Xue, Dongyu
    [J]. JOURNAL OF APPLIED PHYSICS, 2019, 125 (06)
  • [39] PHENOMENON OF LOW VELOCITY DETONATION IN MOLECULAR EXPLOSIVES
    MOHAN, VK
    [J]. SPECULATIONS IN SCIENCE AND TECHNOLOGY, 1979, 2 (05) : 521 - 526
  • [40] Detonation velocity of emulsion explosives containing cenospheres
    Anshits, AG
    Anshits, NN
    Deribas, AA
    Karakhanov, SM
    Kasatkina, NS
    Plastinin, AV
    Reshetnyak, AY
    Sil'vestrov, VV
    [J]. COMBUSTION EXPLOSION AND SHOCK WAVES, 2005, 41 (05) : 591 - 598
12345