蓝肖颖

• 1:国营长虹机械厂

摘要(Abstract)：

相较于常规惰性破片仅以动能毁伤目标,含能破片内含能材料释放的化学能可以提高其对目标的毁伤效果,因此含能破片应用于防空反导技术已成为未来的发展趋势。从试验研究、理论研究、数值仿真三个方面,综述了含能破片毁伤效应的研究情况,分析了目前相关研究的不足,并提出了未来研究含能破片战斗部的几点思考。

关键词(KeyWords)： 含能破片;毁伤效应;冲击反应

Abstract:

Keywords:

基金项目(Foundation):

作者(Author): 蓝肖颖

DOI: 10.16338/j.issn.1009-1319.20200105

参考文献(References)：

• [1] Moussa N A. The potential for fuel tank fire and hydrodynamic ram from uncontained aircraft engine debris. 1997
• [2] Hill R,Hughes W J. A review of the flammability hazard of jet a fuel vapor in civil transport aircraft fuel tanks.Federal Aviation Administration,Office of Aviation Research,1998
• [3] Wang H,Xie J,Ge C,et al. Experimental investigation on enhanced damage to fuel tanks by reactive projectiles impact. Defence Technology,2020
• [4] Ji Y,Li X,Zhou L,et al. Experimental and numerical study on the cumulative damage of water-filled containers impacted by two projectiles. Thin-Walled Structures,2019(135)
• [5] Sorensen B. High-velocity impact of encased Al/PTFE projectiles on structural aluminum armor. Procedia Eng,2015(103)
• [6] Lee R J,Mock Jr W,Carney J R,et al. Reactive materials studies. AIP Conference Proceedings. American Institute of Physics,2006,845(1)
• [7] Xu F,Geng B,Zhang X,et al. Experimental study on behind-plate overpressure effect by reactive material projectile. Propellants, Explosives, Pyrotechnics, Wiley Online Library,2017,42(2)
• [8] Cagle C,Hill K J,Woodruff C,et al. Target penetration and impact analysis of intermetallic projectiles. International Journal of Impact Engineering,2020(136)
• [9] Lu D,Wang H,Lei M,et al. Enhanced initiation behavior of reactive material projectiles impacting covered explosives. Propellants,Explosives,Pyrotechnics,2017,42(9)
• [10]何源．含能破片作用机制及其毁伤效应实验研究．南京:南京理工大学学位论文，2011
• [11] Grudza M E,Jann D,Forsyth C. Explosive launch studies for reactive material fragments. 4th Joint Classified Bombs/Warheads and Ballistics Symposium,2001
• [12] Wang L,Jiang J,Li M,et al. Improving the damage potential of W-Zr reactive structure material under extreme loading condition. Defence Technology,2020
• [13] Church P,Claridge R,Ottley P,et al. Investigation of a nickel-aluminum reactive shaped charge liner. Journal of Applied Mechanics,American Society of Mechanical Engineers Digital Collection,2013,80(3)
• [14] Walters W P,Kecskes L J,Pritchett J E. Investigation of a bulk metallic glass as a shaped charge liner material. Army Research Lab Aberdeen Proving Ground MD,2006
• [15] Daniels A S,Baker E L,De Fisher S E,et al. Bam bam:large scale unitary demolition warheads. Proceedings of the 23rd International Symposium on Ballistics,2007
• [16] Guo H,Zheng Y,Yu Q,et al. Penetration behavior of reactive liner shaped charge jet impacting thick steel plates. International Journal of Impact Engineering,Elsevier,2019(126)
• [17] Wang H,Guo H,Geng B,et al. Application of PTFE/Al reactive materials for double-layered liner shaped charge. Materials,Multidisciplinary Digital Publishing Institute,2019,12(17)
• [18] Steven N. Energetic materials to meet warfighter requirements:an overview of selected US Army RDECOMARDEC energetic materials programs. 42nd Annual Armament Systems:Gun and Missile Systems Conference,2007
• [19] Ames R. Vented chamber calorimetry for impact-initiated energetic materials. 43rd AIAA Aerospace sciences meeting and exhibit,2005
• [20] Bratton K R,Hill K J,Woodruff C,et al. High velocity impact testing of intermetallic projectiles. Journal of Dynamic Behavior of Materials,2020
• [21] Klomfass A,Sauer M,Heilig G,et al. Mesoscale mechanics of reactive materials for enhanced target rffects.Fraunhofer-Institut für Kurzzeitdynamik Ernst-Mach-Institut,EMI,2013
• [22] Ren K,Chen R,Lin Y,et al. Probing the impact energy release behavior of Al/Ni-based reactive metals with experimental and numerical methods. Metals,Multidisciplinary Digital Publishing Institute,2019,9(5)