Parameters Calculation of JWL EOS of FAE Detonation Products

被引:0
|
作者
Zhao X. [1 ]
Bai C. [1 ]
Yao J. [1 ]
Sun B. [1 ]
机构
[1] State Key Laboratory of Explosion Science and Technology, Beijing Institute of Technology, Beijing
来源
Binggong Xuebao/Acta Armamentarii | 2020年 / 41卷 / 10期
关键词
Back propagation neural network-based genetic algorithm; Fuel-air explosive; Jones-Wilkins-Lee equation of state; Parameter calculation;
D O I
10.3969/j.issn.1000-1093.2020.10.001
中图分类号
TP18 [人工智能理论];
学科分类号
081104 ; 0812 ; 0835 ; 1405 ;
摘要
The JWL EOS parameters of detonation products for high explosives are generally determined by the cylinder test. However, the cylinder test is not suitable for fuel air explosives (FAE), which is cloud-like in a macro state. A method for calculating the EOS parameters based on the experimental data of FAE detonation in external field is established to determine the JWL EOS parameters of FAE detonation products. A back propagation neural-based genetic algorithm (BPNN-GA) is introduced into the method. The calculated values are compared with the data from the single- and multi-source external field experiments. The research shows that the introduction of BPNN-GA can simplify the EOS parameter optimization process and also improve the speed and accuracy. Based on the obtained JWL EOS parameters of FAE, the single- and multi-source FAE cloud detonation models are established. The profile of shockwave front from the simulation is consistent with the morphology of actual detonation shockwave. The maximum deviations between simulated and experimental values of the ground peak overpressure at the 50 m measuring points from single- and multi-source are 9.0% and 11.1%, respectively. © 2020, Editorial Board of Acta Armamentarii. All right reserved.
引用
收藏
页码:1921 / 1929
页数:8
相关论文
共 24 条
  • [1] ZHANG Q, WANG Y X, LIAN Z., Explosion hazards of LPG-air mixtures in vented enclosure with obstacles, Journal of Hazar-dous Materials, 334, pp. 59-67, (2017)
  • [2] ZHU X C, ZHENG L G, YU S J, Et al., Effect of blocking ratio on aluminum powder explosion characteristics in vertical duct, Explosion and Shock Waves, 39, 10, pp. 161-170, (2019)
  • [3] ZHANG F, RIPLEY R C, YOSHINAKA A., Large-scale spray detonation and related particle jetting instability phenomenon, Shock Waves, 25, 3, pp. 239-254, (2015)
  • [4] BAI C H, LIANG H M, LI J P, Et al., Cloud detonation, pp. 4-12, (2012)
  • [5] WANG Y, BAI C H, LI J P., Formation and blasting field characteristics of moving cloud detonation, Chinese Journal of Energetic Materials, 25, 6, pp. 466-471, (2017)
  • [6] CHEN J C, MA X, MA Q J., Study on concentration and turbulence of solid-liquid FAE in dispersal process, Defense Technology, 14, 6, pp. 657-660, (2018)
  • [7] CHEN J C, ZHANG Q, MA Q J, Et al., Numerical simulation of dispersal process of solid-liquid mixed fuel, Acta Armamentarii, 35, 7, pp. 972-976, (2014)
  • [8] WANG T Z, XU J P, LIU D R, Et al., Engineering calculation for a fuel-air-explosive (FAE) explosion field, Acta Armamentarii, 15, 3, pp. 94-96, (1994)
  • [9] BENEDICK W B, TIESZEN S R, KNYSTAUTAS R, Et al., Detonation of unconfined large-scale fuel spray-air clouds, pp. 297-310, (1989)
  • [10] BAI C H, WANG Y, XUE K, Et al., Experimental study of detonation of large-scale powder-droplet-vapor mixtures, Shock Waves, 28, 3, pp. 599-611, (2018)
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