装药水下接触爆炸驱动能力测量技术研究
作者:张显丕, 刘建湖, 潘建强, 毛海斌, 张克明 作者单位:中国船舶科学研究中心, 江苏 无锡 214082 发布时间:2018-10-29 15:51:19 点击数:278

PDF下载[4] HTML[0]

关键词:水下接触爆炸;驱动能力;测量方法;水中弹道摆
摘要:

因为传递介质的不同,装药水下接触爆炸载荷输出与空气中存在较大的差异。而由于水下接触爆炸破坏程度高及水中测试难度大等因素,装药水下接触爆炸驱动能力的试验测量一直处于停滞状态。该文基于空气猛度摆的原理设计用于测量水下接触爆炸驱动能力的弹道摆,装置主要通过测量炸药水中爆炸作用下摆锤的摆角获取炸药对接触刚性表面的冲量,从而得到表征装药水下爆炸冲击波及爆轰产物的驱动能力。通过对装置多阶段的整体及局部设计,建立猛度弹道摆试验方法,获得炸药端面冲量输出特性,为水下接触爆炸载荷定量分析提供技术支撑。

Investigation on measurement technology of driving capability for underwater contact explosion

ZHANG Xianpi, LIU Jianhu, PAN Jianqiang, MAO Haibin, ZHANG Keming

China Ship Scientific Research Center, Wuxi 214082, China

Abstract: Because of the difference of transmission medium, the load output of underwater contact explosion of charge is quite different from that of air. Because of the high damage degree of underwater contact explosion and the difficulty of underwater test, the test measurement of the driving ability of underwater contact explosion of charge has been in a stagnant state. In this paper, a ballistic pendulum is designed to measure the driving ability of underwater contact explosion based on the principle of air-force pendulum. The pendulum angle of the pendulum under underwater explosion is measured to obtain the impulse of the explosive on the contact rigid surface, and the driving ability of the shock wave and the detonation product of underwater explosion is obtained. Through multi-stage overall and local design of the device, the test method of the violent ballistic pendulum is established, and the impulse output characteristics of the end face of the explosive are obtained. This measurement technology provides technical support for quantitative analysis of underwater contact explosion load.

Keywords: underwater contact explosion;driving capability;measurement method;underwater ballistic pendulum

2018, 1900-02-12(10): 14-19  收稿日期: 2018-05-01;收到修改稿日期: 2018-06-10

基金项目: 国家自然科学基金项目(51409234)

作者简介: 张显丕(1981-),男,辽宁庄河市人,工程师,博士,主要从事水下爆炸载荷测量技术研究

参考文献

[1] 揭太元. 用双弹道摆测定垂直穿甲动量耗损的实验方法[J]. 兵工学报, 1990(4):70-75.
[2] 夏天赦. 改进威力弹道摆的研究[J]. 火炸药, 1982(4):63-67.
[3] HELD M. Impulse method for the blast contour of cylindrical high explosive charges[J]. Propellants Explosives Pyrotechnics, 1999, 24(1):17-26.
[4] KUMAR A S, VEPAKOMMA B R, SINHA R K, et al. Evaluation of plastic bonded explosive (PBX) formulations based on RDX, aluminum, and HTPB for underwater applications[J]. Propellants Explosives Pyrotechnics, 2010, 35(4):359-364.
[5] NURICK G N, SHAVE G C. The deformation and tearing of thin square plates subjected to impulsive loads-an experimental study[J]. International Journal of Impact Engineering, 1996, 18(1):99-116.
[6] NURICK G N, MARTIN J B. Deformation of thin plates subjected to impulsive loading-a review part Ⅱ:experimental studies[J]. International Journal of Impact Engineering, 1989, 8(2):171-186.
[7] RAJENDRAN R, NARASIMHAN K. Underwater shock response of circular HSLA steel plates[J]. Shock and Vibration, 2015, 7(14):251-262.
[8] TEELING-SMITH R G, NURICK G N. The deformation and tearing of thin circular plates subjected to impulsive loads[J]. International Journal of Impact Engineering, 1991, 11(1):77-91.
[9] KUMAR A S,GOKUL K U,RAO P V K,et al. Blast loading of underwater targets-A study through Explosion Bulge Test experiments[J]. International Journal of Impact Engineering, 2015(76):189-195.
[10] MURATA K, TAKAHASHI K, KATO Y. Underwater shock and bubble pulse loading against model steel cylinder[J]. Materials Science Forum, 2004(456-466):283-288.
[11] 吴林杰, 侯海量, 朱锡, 等. 水下接触爆炸下防雷舱舷侧空舱的内压载荷特性仿真研究[J]. 兵工学报, 2017(1):143-150.
[12] 吴林杰, 侯海量, 朱锡, 等. 水下接触爆炸下防雷舱舷侧空舱的内压载荷特性[J]. 爆炸与冲击, 2017(4):719-726.
[13] 李维新. 一维不定常流与冲击波[M]. 北京:国防工业出版社, 2003:430-456.

内容:
昵称:
验证码:    点击刷新
全部评论:(0)
年份:
标题:
作者:
关键词:
内容: