Experimental study on ballistic characteristics of fiber reinforced aerogel composite structures

Da Long Li; Hai Jun Wu; Feng Lei Huang; Chao Guo

Experimental study on ballistic characteristics of fiber reinforced aerogel composite structures

Da Long Li^*, Hai Jun Wu, Feng Lei Huang, Chao Guo

^*Corresponding author for this work

School of Mechatronical Engineering

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

Abstract

Fiber reinforced silica aerogels (GRSA) were combined with aluminum plates, steel plates and PMMA plates to form a range of composite structures, and the impact responses of the structures to a 7.62 mm ballistic gun were investigated. The result shows that GRSA can significantly improve the impact resistant capacity of composite structures, especially for brittle materials. The failure models of GRSA are the crushing and splash of aerogel matrix, the fracture of fiber and its extraction from the areogel matrix. The protection capability of composite armors against the flat-nosed projectiles is better than that of them against the ogival-nosed projectiles at low and high velocities. In addition, GRSA shows a stain rate effect, and these novel armors offer excellent energy absorbing characteristics under the high velocity impact loading condition.

Original language	English
Pages (from-to)	1-6
Number of pages	6
Journal	Binggong Xuebao/Acta Armamentarii
Volume	33
Issue number	SUPPL2
Publication status	Published - Dec 2012

Keywords

Ballistic performance
Composite armor
Explosion mechanics
Fiber reinforced aerogel
Protective mechanism

Cite this

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title = "Experimental study on ballistic characteristics of fiber reinforced aerogel composite structures",

abstract = "Fiber reinforced silica aerogels (GRSA) were combined with aluminum plates, steel plates and PMMA plates to form a range of composite structures, and the impact responses of the structures to a 7.62 mm ballistic gun were investigated. The result shows that GRSA can significantly improve the impact resistant capacity of composite structures, especially for brittle materials. The failure models of GRSA are the crushing and splash of aerogel matrix, the fracture of fiber and its extraction from the areogel matrix. The protection capability of composite armors against the flat-nosed projectiles is better than that of them against the ogival-nosed projectiles at low and high velocities. In addition, GRSA shows a stain rate effect, and these novel armors offer excellent energy absorbing characteristics under the high velocity impact loading condition.",

keywords = "Ballistic performance, Composite armor, Explosion mechanics, Fiber reinforced aerogel, Protective mechanism",

author = "Li, {Da Long} and Wu, {Hai Jun} and Huang, {Feng Lei} and Chao Guo",

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T1 - Experimental study on ballistic characteristics of fiber reinforced aerogel composite structures

AU - Li, Da Long

AU - Wu, Hai Jun

AU - Huang, Feng Lei

AU - Guo, Chao

PY - 2012/12

Y1 - 2012/12

N2 - Fiber reinforced silica aerogels (GRSA) were combined with aluminum plates, steel plates and PMMA plates to form a range of composite structures, and the impact responses of the structures to a 7.62 mm ballistic gun were investigated. The result shows that GRSA can significantly improve the impact resistant capacity of composite structures, especially for brittle materials. The failure models of GRSA are the crushing and splash of aerogel matrix, the fracture of fiber and its extraction from the areogel matrix. The protection capability of composite armors against the flat-nosed projectiles is better than that of them against the ogival-nosed projectiles at low and high velocities. In addition, GRSA shows a stain rate effect, and these novel armors offer excellent energy absorbing characteristics under the high velocity impact loading condition.

AB - Fiber reinforced silica aerogels (GRSA) were combined with aluminum plates, steel plates and PMMA plates to form a range of composite structures, and the impact responses of the structures to a 7.62 mm ballistic gun were investigated. The result shows that GRSA can significantly improve the impact resistant capacity of composite structures, especially for brittle materials. The failure models of GRSA are the crushing and splash of aerogel matrix, the fracture of fiber and its extraction from the areogel matrix. The protection capability of composite armors against the flat-nosed projectiles is better than that of them against the ogival-nosed projectiles at low and high velocities. In addition, GRSA shows a stain rate effect, and these novel armors offer excellent energy absorbing characteristics under the high velocity impact loading condition.

KW - Ballistic performance

KW - Composite armor

KW - Explosion mechanics

KW - Fiber reinforced aerogel

KW - Protective mechanism

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Experimental study on ballistic characteristics of fiber reinforced aerogel composite structures

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