| REVIEW PAPER |
|
|
|
|
|
| Research Progress on Composite Materials and Structures Used for Protection Against Damage Effect of Projectile Explosion |
| YIN Dejun1,ZHENG Jian1,XIONG Chao1,YIN Junhui1,LIU Yunfeng2
|
1 Shijiazhuang Campus of Army Engineering University, Shijiazhuang 050003;
2 Military Representative Office in 9804 Factory, Military Representative Bureau of Army in Chongqing, Qujing 655000 |
|
|
|
|
Abstract The army ground equipment upgraded to shelter has been an irreversible trend. Because of the structure characteristic of military shelter, its protection capability is very weak. In order to improve the survival ability of shelters in the war, the research of composite materials and structures based on damage effect of projectile explosion has been attached great importance and integrated development in the world military powers. The damage effect of projectile explosion mainly includes high speed fragment penetration and shock wave damage. This paper reviews the development history of military shelter. The development and application on the fragment penetration, shock wave damage and composite damage effect of the composite materials and structures are summarized.
|
|
Published: 10 March 2018
Online: 2018-03-10
|
|
|
|
|
1 Zhang Zejiang. Study on fire-protection layer of blastproof and bulletproof square cabin for military use [J].Journal of Safety Science and Technology,2007,3(2):55(in Chinese).
张泽江.防爆防弹军用方舱防火保护层技术探讨[J].中国安全生产科学技术,2007,3(2):55.
2 Yan Guoqing. Corrosion resistance ability of military shelter[J].New Technology & New Process,2015(7):137(in Chinese).
闫国庆.浅谈军用方舱的抗腐蚀性能[J].新技术新工艺,2015(7):137.
3 Wei Rubin, Zhai Wen, Li Feng, et al. Application of high efficiency impact resistant composites in bulletproof and explosion proof shelter[J].Engineering Plastics Application,2016(4):131(in Chinese).
魏汝斌,翟文,李锋,等.高效抗冲击复合材料在防弹防爆方舱中的应用[J].工程塑料应用,2016(4):131.
4 Dai Youbin, Zhou Zaosheng, Zhang Shanggen, et al. Ultimate bea-ring capacity calculation and reinforcement analysis of square cabin under explosive impact load[J].Journal of Vibration and Shock,2006,25(3):127(in Chinese).
戴佑斌,周早生,张尚根,等.爆炸冲击载荷作用下方舱的极限承载力计算与加固分析[J].振动与冲击,2006,25(3):127.
5 Yin C, Chen Y Q, Zhong S M. Fractional-order sliding mode based extremum seeking control of a class of nonlinear system[J].Automatica,2014,50:3173.
6 Yue Tong, Hu Jing, Song Yu, et al. Hydraulic system design for a military shelter wall-plate display and closed[J].Machinery,2016(1):60(in Chinese).
岳通,胡靖,宋玉,等.某军用方舱车壁板展收液压系统设计[J].机械,2016(1):60.
7 Hu Qiushi, Zhao Feng. Spall control in the projectile explosive dri-ving[J].Chinese Journal of High Pressure Physics,2014(6):655(in Chinese).
胡秋实,赵锋.弹丸爆炸驱动过程中层裂控制的研究[J].高压物理学报,2014(6):655.
8 Huang X G, Zhang L, Zhao Z M, et al. Microstructure transformation and mechanical properties of TiC-TiB2 ceramics prepared by combustion synthesis in high gravity field[J].Materials Science and Engineering A,2012,553:105.
9 La Peiqing, Zhang Xiuping, Lu Xuefeng. Research status of nanocomposite ceramics fabrication techniques[J].Materials Review A:Review Papers,2009,23(7):25(in Chinese).
喇培清,张秀萍,卢学峰.纳米复相陶瓷制备技术的研究现状[J].材料导报:综述篇,2009,23(7):25.
10 Qiu H L, Zhang J, Zhu H M. Properties of Si3N4/BN composite ceramics by spark plasma sintering[J].China’s Refractories,2012,21(1):36.
11 Klement R, Rolc S, Mikulikova R, et al. Transparent armour materials[J].Journal of the European Ceramic Society,2008,28:1091.
12 Liu Sheng, Lv Panke, Zhang Yanpeng. Structural design of ceramic composite armor[J].Ordnance Material Science and Engineering,2011(6):84.
刘胜,吕攀珂,张艳朋.陶瓷复合装甲的结构设计研究[J].兵器材料科学与工程,2011(6):84.
13 Wang Heping, Wang Zhihui. Influence of ceramic confined effect on ballistic performance of composite armor[J].Ordnance Material Science and Engineering,2008(2):61.
王和平,王智慧.陶瓷约束效应对复合装甲抗弹性能的影响[J].兵器材料科学与工程,2008(2):61.
14 Zhang Yu. Development of sandwich armor and aluminum alloy armor materials[J].Science & Technology of Baotou Steel,2011(5):4(in Chinese).
张煜.“三明治装甲”与铝合金装甲材料发展[J].包钢科技,2011(5):4.
15 Wang Yuanbo. Research on ballistics resistance and failure mechanism of fiber-reinforced laminate[D].Hefei:University of Science and Technology of China, 2006(in Chinese).
王元博.纤维增强层合材料的抗弹性能和破坏机理研究[D].合肥:中国科学技术大学,2006.
16 Cai Liang, Jiang Weifeng, Zhang Taihua. Viscoplastic property of shear-thickening gel under shear and the modification of its mechanical property[J].Journal of Functional Materials,2017(8):8181(in Chinese).
蔡亮,蒋伟峰,张泰华.剪切增稠胶剪切条件下的粘弹性能及其力学性能改性[J].功能材料,2017(8):8181.
17 Hassan T A. Synthesis, processing and characterization of shear thickening fluid (STF) impregnated fabric composites[J].Materials Science and Engineering A,2010,527:2892.
18 Decker M J. Stab resistance of shear thickening fluid (STF)-treated fabrics[J].Composites Science and technology,2007,67:565.
19 Fernández D, Zaera R. A new tool based on artificial neural networks for the design of lightweight ceramic-metal armour against high-velocity impact of solids[J].International Journal of Solids and Structures,2008,45:6369.
20 Goncalves D P, Melo F C L, Klein A N. Analysis and investigation of ballistic impact on ceramic metal composite armour[J].International Journal of Machine Tools & Manufacture,2004,44:307.
21 Lee M, Yoo Y H. Analysis of ceramic metal armour systems[J].International Journal of Impact Engineering,2001,25:819.
22 Zhang X Q, Yang G T, Huang X Q. Analytical model of ceramic metal armor impacted by deformable projectile[J].Applied Mathematics and Mechanics(English Edition),2006,27(3):287.
23 Shen Zhiqiang. Investigation of mechanisms of ceramic composite target under noncentral impact of armour-piercing projectile[D].Changsha:National University of Defense Technology,2006(in Chinese).
申志强.穿甲子弹偏心入射陶瓷复合靶板的侵彻机理研究[D].长沙:国防科学技术大学,2006.
24 Du Zhonghua. Mechanics research on penetration of KE-projectile to ceramic composite amour[D].Nanjing:Nanjing University of Science and Technology,2002(in Chinese).
杜忠华.动能弹侵彻陶瓷复合装甲机理[D].南京:南京理工大学,2002.
25 Zouheir F, Kamran B, Yigui X. Optimum design of two-component composite armors against high-speed impact [J].Composite Structures,2006,73:253.
26 Zaera R. Modelling of the adhesive layer in mixed ceramic/metal armours subjected to impact [J].Composites:Part A,2000,31:823.
27 Goncalves D P, Melo F C L, Klein A N. Analysis and investigation of ballistic impact on ceramic/metal composite armour[J].International Journal of Machine Tools and Manufacturing,2004,44:307.
28 Han Hui, Li Nan. Research progress in metal encapsulating ceramic composite armors[J].Ordnance Material Science and Engineering,2008,31(4):79(in Chinese).
韩辉,李楠.金属封装陶瓷复合装甲研究进展[J].兵器材料科学与工程,2008,31(4):79.
29 Lundberg P, Renstrom R, Lundberg B. Impact of metallic projectiles on ceramic targets: Transition between interface defeat and penetration[J].International Journal of Impact Engineering,2000,24:259.
30 Chocron I S, Benloulo V, Sanchez G. A new analytical model to simulate impact onto ceramic composite armors[J].International Journal of Impact Engineering,1998,21(6):461.
31 Shokrieh M M, Javadpour G H. Penetration analysis of a projectile in ceramic composite armor[J].Composite Structures,2008,82:269.
32 Yang Wei. Bullet-proof mechanism of ceramics/composites combined armor panels[J].Aerospace Materials & Technology,2000,30(5):70(in Chinese).
杨威.陶瓷/复合材料装甲板防弹机理分析[J].宇航材料工艺,2000,30(5):70.
33 Zhang Z, Shen J, Zhong W, et al. A dynamic model of ceramic fibre-reinforced plastic hybrid composites under projectile striking[J]. Proceedings of the Institution of Mechanical Engineers,Part G:Journal of Aerospace Engineering,2002,216:325.
34 Mines R A W. A one-dimensional stress wave analysis of a lightweight composite armour[J].Composite Structures,2004,64:55.
35 Fawaz Z, Zheng W, Behdinan K. Numerical simulation of normal and oblique ballistic impact on ceramic composite armours[J].Composite Structures,2004:63 387.
36 Feli S, Asgari M R. Finite element simulation of ceramic composite armor under ballistic impact[J].Composites:Part B,2011,42:771.
37 Su Y, Wu C Q, Griffith M. Mitigation of blast effects on aluminum foam protected masonry walls[J].Transactions of Tianjin University,2008,14(s1):558.
38 Ashby M F, Evans A G, Fleck N A, et al. Metal foams: A design guide[M].Butterworth-Heinemann,2000.
39 Tian Jie. The shock wave attenuation and anti-detonation property of aluminum foam[D].Hefei:University of Science and Technology of China,2006(in Chinese).
田杰.泡沫铝的冲击波衰减和抗爆震特性研究[D].合肥:中国科学技术大学,2006.
40 Hosun C, Jaeung C. Damage and penetration behavior of aluminum foam at various impacts[J].Journal of Central South University,2014,21(9):3442.
41 Yang Donghui, He Deping, Yang Shangrun. Compressive and energy absorption properties of cellular AlCu5Mn alloy foams[J].The Chinese Journal of Nonferrous Metals,2009,19(11):1934(in Chinese).
杨东辉,何德坪,杨上闰.胞状AlCu5Mn合金泡沫的压缩性能和能量吸收特性[J].中国有色金属学报,2009,19(11):1934.
42 Cheng Tao, Xiang Yu, Ma Xiaoqiang. Brief review of the research of strain rate effect of metal foams[J].Metal Materials and Metallurgy Engineering,2008,36(3):60(in Chinese).
程涛,向宇,马小强.泡沫金属应变率效应研究概述[J].金属材料与冶金工程,2008,36(3):60.
43 Tedesco J W, Ross C A, Kufunen S T. Strain rate effects on the compressive strength of shock-mitigation foams[J].Journal of Sound and Vibration,1993,165:376.
44 Gabriel W, Soliman M, Dijkstra K. Microstructure and phase beha-vior of block copoly (ether ester) thermoplastic elastomeres[J].Macromolecules,2001,34:1685.
45 Wang Baozhen, Hu Shisheng. Mechanical properties of flexible pol-yurethane foams under impact loading[J].Polymer Materials Science & Engineering,2009,25(12):48(in Chinese).
王宝珍,胡时胜.软质聚氨酯泡沫的冲击力学性能[J].高分子材料科学与工程,2009,25(12):48.
46 Cai Junfeng, Yi Jianzheng, Zhao Ran. Structural design and anti-explosion experiment of UHMWPE-PUF composite[J].Polymer Materials Science & Engineering,2012(5):69(in Chinese).
蔡军锋,易建政,赵然.UHMWPE-PUF复合材料结构设计与隔爆实验[J].高分子材料科学与工程,2012(5):69.
47 Huang Li, Deng Hua, Wang Chen. Mechanical properties of rigid polyurethane foam used in metal composite roof panels[J]. Journal of Building Materials,2014,179(2):320.
黄莉,邓华,王宸.金属复合屋面板用硬质聚氨酯泡沫的力学性能[J].建筑材料学报,2014,179(2):320.
48 Guan Bowen, Liu Kaiping, Zhao Xiufeng. Progress in study and application of foamed concrete[J].Guangdong Building Materials,2008(2):19(in Chinese).
关博文,刘开平,赵秀峰.泡沫混凝土研究及应用新进展[J].广东建材,2008(2):19.
49 Cheng H F, Han F S. Compressive behavior and energy absorbing characteristic of open cell aluminum foam lled with silicate rubber[J].Scripta Materialia,2003,49:583.
50 Manu K J. A self-healing smart syntactic foam based grid stiffened sandwich structure[D].Baton Rouge:Graduate Faculty of Louisiana State University and Agricultural and Mechanical College,2009.
51 Dong Y X, Feng S S, Jin J. Analysis on dynamic response of hard-soft-hard sandwich panel under blast loading[J].Transaction of Tianjin University,2006(12):233.
52 Liang X X, Wang Z Q, Wang R N. Deformation model and perfor-mance optimization research of composite blast resistant wall subjected to blast loading[J].Journal of Loss Prevention in the Process Industries,2017,49(9):326.
53 Bian Xiaohua, Shi Shaoqing, Kang Jiangong, et al. Research on attenuation characteristics of blast wave for a new projective structure [J].Journal of Logistical Engineering University,2005(4):39(in Chinese).
边小华,石少卿,康建功,等.一种新型防护结构对爆炸冲击波衰减特性的研究[J].后勤工程学院学报,2005(4):39.
54 Ren Zhigang, Lou Menglin, Tian Zhimin. Analysis of antidetonational property of sandwich panel of ployurethane foam[J].Journal of Tongji University,2003,31(1):6(in Chinese).
任志刚,楼梦麟,田志敏.聚氨酯泡沫复合夹层板抗爆特性分析[J].同济大学学报,2003,31(1):6.
55 Dharmasena K P, Wadley H N G, Xue Z Y, et al. Mechanical response of metallic honeycomb sandwich panel structures to high-intensity dynamic loading[J].International Journal of Impact Enginee-ring,2008,35(9):1063.
56 Qian L,Qu M,Feng G. Study on terminal effects of dense fragment cluster impact on armor plate. Part I: Analytical model[J].International Journal of Impact Engineering,2005,31(6):755.
57 Sun Jie, Zhu Lixin, Zhong Bing, et al. Study on blast resistance of GFRP honeycomb sandwich composite[J].Engineering Plastics Application,2003,31(3):40(in Chinese).
孙杰,朱立新,钟兵,等.玻璃钢蜂窝夹层复合材料抗爆性能研究[J].工程塑料应用,2003,31(3):40.
58 Haydn N G,Kumar P,Doug T,et al.Dynamic compression of square honeycomb structures during underwater impulsive loading[J].Journal of Mechanics of Materials and structures,2007,2(10):23.
59 Zhang Yanchang, Wang Zili. Study on crashworthiness of honeycomb sandwich panel under lateral dynamic load[J].Journal of Jiangsu University of Science and Technology(Natural Science Edition),2007,21(3):1(in Chinese).
张延昌,王自力.蜂窝式夹层板耐撞性能研究[J].江苏科技大学学报(自然科学版),2007,21(3):1.
60 Yang Yongxiang, Zhang Yanchang. Numerical simulation of honeycomb core structure under lateral impact load[J].Journal of Jiangsu University of Science and Technology(Natural Science Edition),2007,21(4):7(in Chinese).
杨永祥,张延昌.蜂窝式夹芯层结构横向耐撞性能数值仿真研究[J].江苏科技大学学报(自然科学版),2007,21(4):7.
61 Song Hongwei, Yu Gang, Fan Zijie. Interaction effect in energy absorption of porous material filled thin-walled structure[J].Acta Mechanica Sinica,2005,37(6):697(in Chinese).
(下转第827页)
宋宏伟,虞刚,范子杰,等.多孔材料填充薄壁结构吸能的相互作用效应[J].力学学报,2005,37(6):697.
62 Huang Xicheng, Chen Yuze, Jiang Jiaqiao, et al. Energy absorption of foamed aluminum-filled structures subjected to explosive and impact loadings[J].Journal of PLA University of Science and Technology,2007,8(5):470(in Chinese).
黄西成,陈裕泽,蒋家桥,等.撞击作用下泡沫铝填充结构吸能特征[J].解放军理工大学学报,2007,8(5):470.
63 Chen X, Kong X G, Venkata K, et al. Energy absorption perfor-mance of steel tubes enhanced by a nanoporous material functionalized liquid[J].Applied Physics Letters,2006,89:241918.
64 Lv Xiaocong, Xu Jinyu, Bai Erlei, et al. Analysis of coupling between shrapnel and blast shock wave[J].Journal of PLA University of Science and Technology,2007,8(6):640(in Chinese).
吕晓聪,许金余,白二雷,等.弹片与爆炸冲击波耦合作用分析[J].解放军理工大学学报,2007,8(6):640.
65 Michael W, Bernhard M, Michael A Morgan. Shock fragmentation model for gravitational collapse[J].Research in Astronomy and Astrophysics,2011,11(5):545.
66 Wierzbicki T. Petalling of plates under explosive and impact loading[J].International Journal of Impact Engineering,1999,22(9):935.
67 Dean J, S-Fallah A, Brown P M, et al. Energy absorption during projectile perforation of lightweight sandwich panels with metallic fibre cores[J].Composite Structures,2011,93(3):1089.
68 Gebuer K. Performance, tolerance and cost of TiAl passenger car valves[J].Intermetallics,2006,14(4):355.
宋宏伟,虞刚,范子杰,等.多孔材料填充薄壁结构吸能的相互作用效应[J].力学学报,2005,37(6):697.
62 Huang Xicheng, Chen Yuze, Jiang Jiaqiao, et al. Energy absorption of foamed aluminum-filled structures subjected to explosive and impact loadings[J].Journal of PLA University of Science and Techno-logy,2007,8(5):470(in Chinese).
黄西成,陈裕泽,蒋家桥,等.撞击作用下泡沫铝填充结构吸能特征[J].解放军理工大学学报,2007,8(5):470.
63 Chen X, Kong X G, Venkata K, et al. Energy absorption perfor-mance of steel tubes enhanced by a nanoporous material functiona-lized liquid[J].Applied Physics Letters,2006,89:241918.
64 Lv Xiaocong, Xu Jinyu, Bai Erlei, et al. Analysis of coupling between shrapnel and blast shock wave[J].Journal of PLA University of Science and Technology,2007,8(6):640(in Chinese).
吕晓聪,许金余,白二雷,等.弹片与爆炸冲击波耦合作用分析[J].解放军理工大学学报,2007,8(6):640.
65 Michael W, Bernhard M, Michael A Morgan. Shock fragmentation model for gravitational collapse[J].Research in Astronomy and Astrophysics,2011,11(5):545.
66 Wierzbicki T. Petalling of plates under explosive and impact loading[J].International Journal of Impact Engineering,1999,22(9):935.
67 Dean J, S-Fallah A, Brown P M, et al. Energy absorption during projectile perforation of lightweight sandwich panels with metallic fibre cores[J].Composite Structures,2011,93(3):1089.
68 Gebuer K. Performance, tolerance and cost of TiAl passenger car valves[J].Intermetallics,2006,14(4):355. |
|
|
|
渝公网安备50019002502923号 © Editorial Office of Materials Reports.
2018, Vol. 32 
