Study on Damage Effect of Fragment Penetrating Concrete

被引：0

作者：

Yu Q. ^{[1
]}

Zhong S. ^{[1
]}

Ge C. ^{[1
]}

机构：

[1] State Key Laboratory of Explosion Science and Technology, Beijing Institute of Technology, Beijing

来源：

Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology | 2023年 / 43卷 / 03期

关键词：

ammunition warhead; concrete; numerical simulation; prefabricated fragments;

D O I：

10.15918/j.tbit1001-0645.2022.076

中图分类号：

学科分类号：

摘要：

The Autodyn dynamics software was used to carry out a numerical simulation study on the influencing factors of the end effect of large-size fragments penetrating concrete, and the influence characteristics of factors such as penetration speed, penetration attitude, fragment shape, and fragment material on the end effect of concrete were obtained. The research results show that when penetration speed of fragments increased, penetration depth and the diameter of the penetration hole gradually increased, and the diameter tended to a certain value; when penetration was oblique, the compression-shear coupling effect and boundary effect could cause the size of the penetration hole to increase; when the penetration kinetic energy and the shape of fragments were the same, the comprehensive damage effect of tungsten fragments was better than that of 4340 steel and 45# steel; the cylindrical fragments had the strongest piercing ability, and the square fragments had the strongest penetrating ability. © 2023 Beijing Institute of Technology. All rights reserved.

引用

页码：259 / 266

页数：7

共 10 条

[1] ZHAO Hongwei, HE Yuanji, CHENG Lirong, Et al., Research on the penetration law of reinforced concrete with forward cabin warhead, Transactions of Beijing Institute of Technology, 39, 6, pp. 578-582, (2019)
[2] WANG Jiangbo, ZHANG Tianxing, DING Junsheng, Et al., Research on the effect of aggregate particle size on the mechanical properties of concrete, Transactions of Beijing Institute of Technology, 41, 11, pp. 1162-1170, (2021)
[3] GAO Guangfa, Influence and correction of concrete strain rate effect, pressure and lateral effect under dynamic compression, Transactions of Beijing Institute of Technology, 40, 2, (2020)
[4] SUN Shanzheng, LU Hao, YUE Songlin, Et al., The composite damage effects of explosion after penetration in plain concrete targets, International Journal of Impact Engineering, 153, (2021)
[5] PENG Yong, LU Fangyun, FANG Qin, Et al., Size effect analysis of projectile penetrating concrete target, Explosion and Impact, 39, 11, pp. 55-65, (2019)
[6] WU Haijun, HUANG Fenglei, JIN Qiankun, Et al., Numerical simulation of projectile penetration through reinforced concrete, Explosion and Impact, 23, 6, pp. 545-550, (2003)
[7] LIAO Z, TANG D, LI Z, Et al., Study on explosion resistance performance experiment and damage assessment model of high-strength reinforcement concrete beams[J], Int J Impact Eng, 133, (2019)
[8] Jinzhu LI, LU Zhongjie, ZHANG Hongsong, Et al., Perforation experiments of concrete targets with residual velocity measurements[J], Int J Impact Eng, 57, 1, pp. 1-6, (2013)
[9] WANG Zhe, Numerical simulation research of projectile penetrating concrete target at high speed, (2015)
[10] CHEN X W, LI Q M., Transition from nondeformable projectile penetration to semihydrodynamic penetration[J], Journal of Engineering Mechanics, 130, 1, pp. 123-127, (2004)

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