Ballistic experiments on the mechanism of protective layer against domino effect caused by projectiles

Dongliang Sun; Juncheng Jiang; Mingguang Zhang; Zhirong Wang

doi:10.1016/j.jlp.2015.11.020

Ballistic experiments on the mechanism of protective layer against domino effect caused by projectiles

Dongliang Sun, Juncheng Jiang, Mingguang Zhang, Zhirong Wang

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

The mechanism of protective layer against the domino effect caused by high velocity and low mass projectiles was investigated using ballistic experiments, under various values of thickness, surface density, fabric structure, and impact velocity. The results showed that unit absorption energy generally decreased and then increased with thickness and surface density. The critical value of thickness existed, the highest absorption was demonstrated in UD composite, and the back convex reached the maximum when impact velocity reached the ballistic limitation. Stretching fracture of fiber was the major way of energy absorption. Finally, four layers were designed for the protective layer.

Original language	English
Pages (from-to)	17-28
Number of pages	12
Journal	Journal of Loss Prevention in the Process Industries
Volume	40
DOIs	https://doi.org/10.1016/j.jlp.2015.11.020
State	Published - 1 Mar 2016

Keywords

Ballistic experiment
Domino effect
Influential mechanism
Projectiles
Protective layer

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10.1016/j.jlp.2015.11.020

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title = "Ballistic experiments on the mechanism of protective layer against domino effect caused by projectiles",

abstract = "The mechanism of protective layer against the domino effect caused by high velocity and low mass projectiles was investigated using ballistic experiments, under various values of thickness, surface density, fabric structure, and impact velocity. The results showed that unit absorption energy generally decreased and then increased with thickness and surface density. The critical value of thickness existed, the highest absorption was demonstrated in UD composite, and the back convex reached the maximum when impact velocity reached the ballistic limitation. Stretching fracture of fiber was the major way of energy absorption. Finally, four layers were designed for the protective layer.",

keywords = "Ballistic experiment, Domino effect, Influential mechanism, Projectiles, Protective layer",

author = "Dongliang Sun and Juncheng Jiang and Mingguang Zhang and Zhirong Wang",

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T1 - Ballistic experiments on the mechanism of protective layer against domino effect caused by projectiles

AU - Sun, Dongliang

AU - Jiang, Juncheng

AU - Zhang, Mingguang

AU - Wang, Zhirong

PY - 2016/3/1

Y1 - 2016/3/1

N2 - The mechanism of protective layer against the domino effect caused by high velocity and low mass projectiles was investigated using ballistic experiments, under various values of thickness, surface density, fabric structure, and impact velocity. The results showed that unit absorption energy generally decreased and then increased with thickness and surface density. The critical value of thickness existed, the highest absorption was demonstrated in UD composite, and the back convex reached the maximum when impact velocity reached the ballistic limitation. Stretching fracture of fiber was the major way of energy absorption. Finally, four layers were designed for the protective layer.

AB - The mechanism of protective layer against the domino effect caused by high velocity and low mass projectiles was investigated using ballistic experiments, under various values of thickness, surface density, fabric structure, and impact velocity. The results showed that unit absorption energy generally decreased and then increased with thickness and surface density. The critical value of thickness existed, the highest absorption was demonstrated in UD composite, and the back convex reached the maximum when impact velocity reached the ballistic limitation. Stretching fracture of fiber was the major way of energy absorption. Finally, four layers were designed for the protective layer.

KW - Ballistic experiment

KW - Domino effect

KW - Influential mechanism

KW - Projectiles

KW - Protective layer

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SN - 0950-4230

VL - 40

SP - 17

EP - 28

JO - Journal of Loss Prevention in the Process Industries

JF - Journal of Loss Prevention in the Process Industries

ER -

Ballistic experiments on the mechanism of protective layer against domino effect caused by projectiles

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Keywords

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