弹丸低速贯穿纤维与金属组合薄靶板的试验研究

doi:10.3969/j.issn.1000-1093.2012.12.011

兵工学报 ›› 2012, Vol. 33 ›› Issue (12): 1473-1479.doi: 10.3969/j.issn.1000-1093.2012.12.011

弹丸低速贯穿纤维与金属组合薄靶板的试验研究

陈长海¹，朱锡¹ ，侯海量¹ ，沈晓乐²，唐廷¹

(1.海军工程大学船舶工程系，湖北武汉 430033;2.海军91439部队旅顺试验场辽宁大连 116041)

收稿日期:2011-12-21 修回日期:2011-12-21 上线日期:2014-01-09
作者简介:陈长海(1985—)男博士研究生
基金资助:
国家自然科学基金项目(51179200、51209211);中国博士后科学基金项目(20100471794);海军工程大学自然科学基金项目(HGDYDJJ003)

An Experimental Research on Lowvelocity Projectiles Perforating Fiber and Metal Combined Thin Targets

CHEN Chang-hai¹, ZHU Xi¹ , HOU Hai-liang¹ , SHEN Xiao-le², TANG Ting¹

(1. Department of Naval Architectural Engineering, Naval University of Engineering, Wuhan 430033, Hubei, China;2. Lvshun Proving Ground, Naval Unit No. 91439, Dalian 116041, Liaoning, China)

Received:2011-12-21 Revised:2011-12-21 Online:2014-01-09

摘要/Abstract

摘要： 为研究半穿甲战斗部动能侵彻下舰船舷侧复合装甲结构的抗穿甲机理，以均质钢板前置复合材料板模拟舰船舷侧复合装甲结构，采用低速弹道冲击试验，研究了结构的典型破坏模式和吸能机理，分析了前置复合装甲板的面密度对组合结构靶板整体抗穿甲性能的影响。在此基础上，根据靶板的破坏模式，得到了球头弹丸低速贯穿组合靶板的剩余速度预测公式。结果表明，组合靶板在弹丸低速冲击下主要呈现局部破坏，前置复合装甲板的破坏模式主要为纤维拉伸断裂，迎弹面存在少量的纤维剪切断裂，而钢质背板则主要呈现花瓣开裂破坏；组合靶板的整体抗弹性能随前置复合装甲板面密度的增加而提高；将理论预测剩余速度值与实验结果进行了比较，二者吻合较好。

关键词: 爆炸力学, 低速贯穿, 组合靶板, 弹道试验, 理论预测

Abstract: Lowvelocity ballistic experiments were carried out to study the perforationresistant mechanisms of warship topside composite armor system, which was simulated by composite laminates at the front and homogeneous steel plates at the back. Failure modes and energy absorbing mechanisms were investigated and the influence of the area density of front composite armors on total perforation resistance of combined targets was analyzed. Based on the experiments, an equation was obtained to predict the residual velocities in the case of lowvelocity perforation of combined targets by hemisphericalnosed projectiles according to the failure modes of the targets. The results show that under low velocity perforation, combined targets mainly exhibit local damage. A few amounts of fiber at the impact side of front composite armor are sheared by the projectile. Failure modes of front composite armors are mainly fiber tensile rupture while for steel backing plates, failure modes are primarily petaloid damage. The whole energyabsorbing capability of combined targets increases with increasing the area density of front composite armors. It is shown that theoretical predictions coincide with the experimental results in terms of residual velocities.

Key words: explosion mechanics, lowvelocity perforation, combined target, ballistic experiment, theoretical prediction

中图分类号:

O385
TB333

陈长海, 朱锡, 侯海量, 沈晓乐, 唐廷. 弹丸低速贯穿纤维与金属组合薄靶板的试验研究[J]. 兵工学报, 2012, 33(12): 1473-1479.

CHEN Chang-hai, ZHU Xi, HOU Hai-liang, SHEN Xiao-le, TANG Ting. An Experimental Research on Lowvelocity Projectiles Perforating Fiber and Metal Combined Thin Targets[J]. Acta Armamentarii, 2012, 33(12): 1473-1479.

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弹丸低速贯穿纤维与金属组合薄靶板的试验研究

An Experimental Research on Lowvelocity Projectiles Perforating Fiber and Metal Combined Thin Targets

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