Energy dissipation mechanism and ballistic characteristic optimization in foam sandwich panels against spherical projectile impact

IF 5 Q1 ENGINEERING, MULTIDISCIPLINARY
Jianqiang Deng , Tao Liu , Liming Chen , Xin Pan , Jingzhe Wang , Shaowei Zhu , Weiguo Li
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引用次数: 0

Abstract

This study systematically examines the energy dissipation mechanisms and ballistic characteristics of foam sandwich panels (FSP) under high-velocity impact using the explicit non-linear finite element method. Based on the geometric topology of the FSP system, three FSP configurations with the same areal density are derived, namely multi-layer, gradient core and asymmetric face sheet, and three key structural parameters are identified: core thickness (tc), face sheet thickness (tf) and overlap face/core number (no). The ballistic performance of the FSP system is comprehensively evaluated in terms of the ballistic limit velocity (BLV), deformation modes, energy dissipation mechanism, and specific penetration energy (SPE). The results show that the FSP system exhibits a significant configuration dependence, whose ballistic performance ranking is: asymmetric face sheet > gradient core > multi-layer. The mass distribution of the top and bottom face sheets plays a critical role in the ballistic resistance of the FSP system. Both BLV and SPE increase with tf, while the raising tc or no leads to an increase in BLV but a decrease in SPE. Further, a face-core synchronous enhancement mechanism is discovered by the energy dissipation analysis, based on which the ballistic optimization procedure is also conducted and a design chart is established. This study shed light on the anti-penetration mechanism of the FSP system and might provide a theoretical basis for its engineering application.

泡沫夹芯板抵御球形弹丸冲击的消能机制和弹道特性优化
本研究采用显式非线性有限元方法,系统地研究了泡沫夹芯板(FSP)在高速冲击下的能量耗散机制和弹道特性。根据泡沫夹芯板系统的几何拓扑结构,推导出三种具有相同面积密度的泡沫夹芯板配置,即多层、梯度夹芯和非对称面片,并确定了三个关键结构参数:夹芯厚度(tc)、面片厚度(tf)和重叠面/夹芯数量(no)。从弹道极限速度(BLV)、变形模式、能量耗散机制和比穿透能(SPE)等方面对 FSP 系统的弹道性能进行了全面评估。结果表明,FSP 系统具有明显的构型依赖性,其弹道性能排序为:非对称面片> 梯度芯> 多层。顶部和底部面片的质量分布对 FSP 系统的抗弹性起着关键作用。BLV和SPE都随tf的增加而增加,而提高tc或不提高tc会导致BLV增加但SPE减少。此外,还通过能量耗散分析发现了面核同步增强机制,并在此基础上进行了弹道优化程序,建立了设计图。该研究揭示了 FSP 系统的抗穿透机制,为其工程应用提供了理论依据。
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来源期刊
Defence Technology(防务技术)
Defence Technology(防务技术) Mechanical Engineering, Control and Systems Engineering, Industrial and Manufacturing Engineering
CiteScore
8.70
自引率
0.00%
发文量
728
审稿时长
25 days
期刊介绍: Defence Technology, a peer reviewed journal, is published monthly and aims to become the best international academic exchange platform for the research related to defence technology. It publishes original research papers having direct bearing on defence, with a balanced coverage on analytical, experimental, numerical simulation and applied investigations. It covers various disciplines of science, technology and engineering.
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