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

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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.

Sandwich panelNumerical simulationBallistic resistanceSpecific penetration energyEnergy analysis

Jianqiang Deng、Tao Liu、Liming Chen、Xin Pan、Jingzhe Wang、Shaowei Zhu、Weiguo Li

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College of Aerospace Engineering,Chongqing University,Chongqing 400030,China

State Key Laboratory of Coal Mine Disaster Dynamics and Control,Chongqing University,Chongqing 400030,China

Chongqing Key Laboratory of Heterogeneous Material Mechanics,Chongqing University,Chongqing 400030,China

State Key Laboratory of Explosion Science and Technology,Beijing Institute of Technology,Beijing 100081,China

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国家自然科学基金国家自然科学基金国家自然科学基金中央高校基本科研业务费专项Chongqing Natural Science Foundation中国博士后科学基金Chongqing Postdoctoral Science FoundationOpening Project of State Key Laboratory of Explosion Science and Technology(Beijing Institute of Technology)

1197209612372127122020852022CDJQY-004cstc2021ycjhbgzxm01172022M7205622021XM3022KFJJ23-18 M

2024

10.1016/j.dt.2023.09.015

防务技术
中国兵工学会

防务技术

CSTPCD
影响因子:0.358
ISSN:2214-9147
年,卷(期):2024.35(5)
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