Numerical simulation on ballistic penetration of composite case

Jing Xuan He; Wen Hui Ding; Xiao Hou; Kan Li

Numerical simulation on ballistic penetration of composite case

Jing Xuan He, Wen Hui Ding, Xiao Hou, Kan Li

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

Abstract

The ballistic penetration process of the aramid fiber/epoxy resin composite case was numerically simulated based on LS-DYNA dynamic finite element software display algorithm. The velocity variation laws of the bullet in the composite case were obtained under different incident angles and initial velocity conditions. The calculation results show that under 90°, 60° and 30° incident angle, absorbed energy of the bullet in the composite case is the lowest, and residual velocity can reach the maximum value when tungsten bullet and armor-piercing bullet inject vertically. With the decrease of the incident angle, interaction time between bullet and target as well as kinetic energy loss increase, with the result that residual velocity becomes smaller;when residual velocity reaches a certain value, the bullet starts to ricochet. The critical velocity was obtained through calculation. The calculation results agree well with the experimental results.

Original language	English
Pages (from-to)	258-261
Number of pages	4
Journal	Guti Huojian Jishu/Journal of Solid Rocket Technology
Volume	31
Issue number	3
State	Published - Jun 2008
Externally published	Yes

Keywords

Ballistic resistance
Composite case
Numerical simulation
Penetration

Cite this

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title = "Numerical simulation on ballistic penetration of composite case",

abstract = "The ballistic penetration process of the aramid fiber/epoxy resin composite case was numerically simulated based on LS-DYNA dynamic finite element software display algorithm. The velocity variation laws of the bullet in the composite case were obtained under different incident angles and initial velocity conditions. The calculation results show that under 90°, 60° and 30° incident angle, absorbed energy of the bullet in the composite case is the lowest, and residual velocity can reach the maximum value when tungsten bullet and armor-piercing bullet inject vertically. With the decrease of the incident angle, interaction time between bullet and target as well as kinetic energy loss increase, with the result that residual velocity becomes smaller;when residual velocity reaches a certain value, the bullet starts to ricochet. The critical velocity was obtained through calculation. The calculation results agree well with the experimental results.",

keywords = "Ballistic resistance, Composite case, Numerical simulation, Penetration",

author = "He, {Jing Xuan} and Ding, {Wen Hui} and Xiao Hou and Kan Li",

year = "2008",

month = jun,

language = "英语",

volume = "31",

pages = "258--261",

journal = "Guti Huojian Jishu/Journal of Solid Rocket Technology",

issn = "1006-2793",

publisher = "Journal of Solid Rocket Technology",

number = "3",

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TY - JOUR

T1 - Numerical simulation on ballistic penetration of composite case

AU - He, Jing Xuan

AU - Ding, Wen Hui

AU - Hou, Xiao

AU - Li, Kan

PY - 2008/6

Y1 - 2008/6

N2 - The ballistic penetration process of the aramid fiber/epoxy resin composite case was numerically simulated based on LS-DYNA dynamic finite element software display algorithm. The velocity variation laws of the bullet in the composite case were obtained under different incident angles and initial velocity conditions. The calculation results show that under 90°, 60° and 30° incident angle, absorbed energy of the bullet in the composite case is the lowest, and residual velocity can reach the maximum value when tungsten bullet and armor-piercing bullet inject vertically. With the decrease of the incident angle, interaction time between bullet and target as well as kinetic energy loss increase, with the result that residual velocity becomes smaller;when residual velocity reaches a certain value, the bullet starts to ricochet. The critical velocity was obtained through calculation. The calculation results agree well with the experimental results.

AB - The ballistic penetration process of the aramid fiber/epoxy resin composite case was numerically simulated based on LS-DYNA dynamic finite element software display algorithm. The velocity variation laws of the bullet in the composite case were obtained under different incident angles and initial velocity conditions. The calculation results show that under 90°, 60° and 30° incident angle, absorbed energy of the bullet in the composite case is the lowest, and residual velocity can reach the maximum value when tungsten bullet and armor-piercing bullet inject vertically. With the decrease of the incident angle, interaction time between bullet and target as well as kinetic energy loss increase, with the result that residual velocity becomes smaller;when residual velocity reaches a certain value, the bullet starts to ricochet. The critical velocity was obtained through calculation. The calculation results agree well with the experimental results.

KW - Ballistic resistance

KW - Composite case

KW - Numerical simulation

KW - Penetration

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M3 - 文章

AN - SCOPUS:48049108237

SN - 1006-2793

VL - 31

SP - 258

EP - 261

JO - Guti Huojian Jishu/Journal of Solid Rocket Technology

JF - Guti Huojian Jishu/Journal of Solid Rocket Technology

IS - 3

ER -

Numerical simulation on ballistic penetration of composite case

Abstract

Keywords

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