期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

陶瓷/泡沫铝/铝合金复合装甲抗射流侵彻性能 被引量:8

Anti-jet Penetration Performances of the Ceramic/Aluminum Foam/Alum inum Alloy Com posite Armor
下载PDF
导出
摘要 为研究泡沫铝复合装甲抗侵彻性能,根据应力波传播特性对陶瓷/泡沫铝/铝合金复合结构进行了理论分析。从不同泡沫铝夹芯厚度、相同厚度复合装甲下不同前后板厚度及布置方式和复合装甲倾角三方面研究了该复合装甲能量吸收规律、射流头部剩余速度以及不同倾角下装甲的防护性能。结果表明,泡沫铝作为夹芯层可充分降低复合装甲背板质点速度。同一倾角θ下,随着泡沫铝厚度的增大,复合装甲背板质点速度减小。泡沫铝厚度为2.4 mm时,射流头部剩余速度最低,复合装甲能量吸收最多,抗侵彻性能最优。同一泡沫铝厚度下,随着t_1/t_2值的增大,接触式复合装甲与间隔式复合装甲的射流头部剩余速度均先降低后增加。t_1/t_2=1时,间隔式复合装甲的抗侵彻性能最优。当仅布置方式不同时,间隔式与接触式复合装甲抗射流侵彻性能的差别较小。随着倾角θ的增大,复合装甲的防护性能先增强后降低。倾角为20°时,复合装甲抗射流侵彻性能最优。 To study the anti-penetration performance of composite armor with aluminum foam, based on the stress-wave propagation characteristics, a theorytical analysis of the structure of ceramic/aluminum foam/aluminum alloy composite armor was carried out. The energy absorption rule, residual velocity of jet head, and protective capability of armor under different dip angle were investigated from three aspects of different aluminum foam sandwich thickness, different thickness and arrangement way of front-back plate under the composite armor with same thickness, and composite armor dip angle. Results show that the aluminum foam as sandwich layer can reduce the particle velocity of back plate of composite armor adequately. Under the same dip angle θ, the particle velocity of back plate decreases with increasing thickness of aluminum foam. When the thickness of foam aluminum is 2.4 mm, the residual velocity of the jet head is minimum, the energy of the composite armor is maximum and the anti-penetration performance is optimal. Under the same thickness of aluminum foam, with increasing the thickness ratio t1/t2, the residual velocity of jet head of the interval and contact type composite armor decreases firstly, and then increases. When t1/t2=1, the anti-penetration performance of interval type composite armor is optimal. When the layout way is not the same only, the difference of penetration performance between interval and contact type composite armor is small. With increasing the dip angle θ, the protective capability of composite armor increases firstly, and then decreases. When the dip angle θ is 20°, the anti-jet penetration performance of composite armor is optimal.
作者 苟瑞君 孙丹 张博
机构地区 中北大学化工与环境学院
出处 《含能材料》 EI CAS CSCD 北大核心 2017年第6期451-458,共8页 Chinese Journal of Energetic Materials
关键词 泡沫铝 复合装甲 抗侵彻 应力波 射流 防护性能 aluminum foam composite armor resist to penetration stress wave jet protective performance
分类号 TJ810.38 [兵器科学与技术—武器系统与运用工程]
  • 相关文献

参考文献3

二级参考文献23

  • 1魏雪英,张春燕,马淑芳.射流侵彻作用下陶瓷材料的性态与阻力[J].兵工学报,2005,26(4):481-485. 被引量:9
  • 2王志华,朱峰,赵隆茂.多孔金属夹芯结构动力学行为及其应用[M].北京:兵器工业出版社,2010.
  • 3Zhu F, Zhao L M, Lu G X, et al. Deformation and failure of blast-loaded metallic sandwich panels--Experimental in- vestigations [J]. Int J Impact Eng, 2008,35 (8) : 937-951.
  • 4Dharmasena K P,Wadley H N G,Xue Z Y, et al. Mechanical response of metallic honeycomb sandwich panel struc- tures to high-intensity dynamic loading [J]. Int J Impact Eng, 2008,35 (9) :1063-1074.
  • 5Fleck N A, Deshpande V S. The resistance of clamped sandwich beams to shock loading [J]. J Appl Mech, 2004,71 : 1-16.
  • 6Xue Z Y, Hutchinson J W. Preliminary assessment of sandwich plates subject to blast loads [J]. Int J Mech Sci, 2003,45 (4) : 687-705.
  • 7Nurick G N,Langdon G S,Chi Y,et al. Behaviour of sandwich panels subjected to intense air blast--Part 1 :Experi- ments [J]. Composite Structures, 2009,91 (4) : 433-441.
  • 8Radford D D, McShane G J, Deshpande V S, et al. The response of clamped sandwich plates with metallic foam cores to simulated blast loading[J]. Int J Solids Struct,2006,43:2243-2259.
  • 9McShane G J,Deshpande V S, Fleck N A. The underwater blast resistance of metallic sandwich beams with prismat- ic lattice cores [J]. J Appl Mech,2007,74:352-364.
  • 10McShane G J, Radford D D,Deshpande V S, et al. The response of clamped sandwich plates with lattice cores subjec- ted to shock loading [J]. Eur J Mech A--Solids,2006,25(2):215-229.

共引文献30

同被引文献77

引证文献8

二级引证文献15

含能材料
2017年 第6期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部