Overdriven Detonation and Its Application in Shaped Charges 被引量：1

Overdriven Detonation and Its Application in Shaped Charges

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摘要 Overdriven detonation（ODD）in high explosives can be generated by Mach reflection of conical detonation waves propagating quasi-steadily in a co-axial double layer cylindrical charge.The inner core of the charge consists of lower detonation velocity explosive with higher detonation velocity explosive for the outer core.The calculated pressures and detonation velocities in the ODD regime are compared with available results in the literature.The application of this technique to design a double layer shaped charge（DLSC）is numerically studied.It was discovered that the use of lower density-lower detonation velocity explosive in the inner core of DLSC can also yield similar results to those obtained with high density lower detonation velocity explosive.By analyzing previous experimental results and comparing with present simulations,it is demonstrated that ordinary shaped charges have some advantages over DLSC under certain conditions. Overdriven detonation（ODD）in high explosives can be generated by Mach reflection of conical detonation waves propagating quasi-steadily in a co-axial double layer cylindrical charge.The inner core of the charge consists of lower detonation velocity explosive with higher detonation velocity explosive for the outer core.The calculated pressures and detonation velocities in the ODD regime are compared with available results in the literature.The application of this technique to design a double layer shaped charge（DLSC）is numerically studied.It was discovered that the use of lower density-lower detonation velocity explosive in the inner core of DLSC can also yield similar results to those obtained with high density lower detonation velocity explosive.By analyzing previous experimental results and comparing with present simulations,it is demonstrated that ordinary shaped charges have some advantages over DLSC under certain conditions.

作者 Tariq Hussain Yan Liu Fenglei Huang

机构地区 State Key Laboratory of Explosion Science and Technology

出处《Journal of Beijing Institute of Technology》 EI CAS 2017年第1期9-15,共7页 北京理工大学学报（英文版）

基金 Supported by the National Natural Science Foundation of China(11272059,11221202) Program for New Century Excellent Talents in University(NCET-12-0037)

关键词 overdriven detonation double-layer shaped charge jet formation overdriven detonation double-layer shaped charge jet formation

分类号 O381 [理学—流体力学]

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参考文献1

1张先锋,丁建宝,赵晓宁.夹层聚能装药作用过程的数值模拟[J].爆炸与冲击,2009,29(6):617-624. 被引量：25

二级参考文献16

1Held M.Behavior of dual composition explosive[C] ∥Masson P.6th International Congress of Pyrotechnics,EUROPYRO.Tours,1995:185-191.
2李福金.夹层聚能装药的破甲试验研究与分析[C] ∥丁世用.破甲技术文集.北京:兵器工业出版社,1992:97-98.
3步相东.新型破甲弹技术-T式装药结构研究[D].北京:北京理工大学,2002.
4Kato H,Murata K,Itoh S,et al.Application of overdriven detonation in high density explosive to shaped charge[C] ∥Francisco GáLvez 23rd International Symposium on Ballistics Tarragona,2007:223-230.
5Liu Z,Nagano S,Itoh S.Overdriven detonation phenomenon in high explosive[J].Shock Compression of Condensed Matter,1999,16:227-230.
6LIU Zhi-yue,Tanaka K,Itoh S.A method for producing extra-high dynamic pressure due to the efficient use of high explosive[J].Journal of Pressure Vessel Technology,2004,126:264-268.
7LIU Zhi-yue,kubota S,Itoh S.Numerical study on hypervelocity acceleration of flyer plates by overdriven detonation of high explosive[J].International Journal of Impact Engineering,2001,26:443-452.
8Otsuka M,Hida E,Morimoto H.Effective using for overdriven detonation in high explosives[C] ∥Cavailler C,Graham P.Haddleton,Manfred Hugenschmidt 25th International Congress on High-Speed Photography and Photonics.France:SPIE,2003:464-469.
9Itoh S.Visualization of an overdriven detonation phenomenon in a high explosive[J].Journal of Flow Visualization and Image Processing,1999,6(4):295-302.
10LIU Zhi-yue.Overdriven detonation phenomenon and its application to ultra-high pressure generation[D].Japan:Kumamoto University,2001.

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2孙华,王志军,刘强,任海.带壳炸药穿而不爆数值模拟与分析[J].火工品,2012(2):40-43. 被引量：4
3孙华,王志军,王向东.低密度射流对带壳炸药穿而不爆数值研究[J].工程爆破,2012,18(3):17-20. 被引量：2
4王智慧,纪伟,侯圣英,郭领,胡丽萍,满红.AUTODYN中接触算法对穿甲问题仿真结果的影响[J].兵器材料科学与工程,2014,37(4):8-11. 被引量：6
5赵春龙,王志军,崔斌,苏尧.玻璃射流冲击带壳装药的数值模拟[J].兵器材料科学与工程,2015,38(3):93-96. 被引量：3
6王利侠,谷鸿平,丁刚,刘丰旺,孙兴昀.聚能射流对带壳浇注PBX装药的撞击响应[J].含能材料,2015,23(11):1067-1072. 被引量：12
7赵春龙,王志军,崔斌,董方栋.钛射流冲击带壳装药的仿真研究[J].兵工学报,2014,35(S2):294-297. 被引量：1
8赵鹏铎,贾子健,王志军,赵飞扬,张磊.双层药型罩对反应装甲穿而不爆及后效作用研究[J].兵工学报,2018,39(A01):37-44. 被引量：2
9韩克华,任西,李慧,张玉若,褚恩义.冲击片雷管多点同步起爆爆轰波压力的数值模拟和试验[J].含能材料,2016,24(1):38-44. 被引量：8
10潘建,张先锋,何勇,邓启斌.带隔板装药爆轰波马赫反射理论研究和数值模拟[J].爆炸与冲击,2016,36(4):449-456. 被引量：6

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