PELE贯穿薄靶后外壳破片径向速度计算方法与影响因素分析

樊自建 冉宪文 汤文辉 于国栋 陈为科 任才清

樊自建, 冉宪文, 汤文辉, 于国栋, 陈为科, 任才清. PELE贯穿薄靶后外壳破片径向速度计算方法与影响因素分析[J]. 爆炸与冲击, 2017, 37(4): 621-628. doi: 10.11883/1001-1455(2017)04-0621-08
引用本文: 樊自建, 冉宪文, 汤文辉, 于国栋, 陈为科, 任才清. PELE贯穿薄靶后外壳破片径向速度计算方法与影响因素分析[J]. 爆炸与冲击, 2017, 37(4): 621-628. doi: 10.11883/1001-1455(2017)04-0621-08
Fan Zijian, Ran Xianwen, Tang Wenhui, Yu Guodong, Chen Weike, Ren Caiqing. Calculation method and influencing factors of the fragmental radial velocities of PELE after penetrating thin target[J]. Explosion And Shock Waves, 2017, 37(4): 621-628. doi: 10.11883/1001-1455(2017)04-0621-08
Citation: Fan Zijian, Ran Xianwen, Tang Wenhui, Yu Guodong, Chen Weike, Ren Caiqing. Calculation method and influencing factors of the fragmental radial velocities of PELE after penetrating thin target[J]. Explosion And Shock Waves, 2017, 37(4): 621-628. doi: 10.11883/1001-1455(2017)04-0621-08

PELE贯穿薄靶后外壳破片径向速度计算方法与影响因素分析

doi: 10.11883/1001-1455(2017)04-0621-08
详细信息
    作者简介:

    樊自建(1978-),男,博士,副教授

    通讯作者:

    汤文辉,wenhuitang@163.com

  • 中图分类号: O385

Calculation method and influencing factors of the fragmental radial velocities of PELE after penetrating thin target

  • 摘要: 基于横向效应增强型弹丸(PELE)侵彻金属薄靶板过程分析,将弹体前端在撞击作用下的变形过程分解为轴向一维压缩和径向自由膨胀两个变形阶段;依据冲击波理论,给出了弹体前端的冲击波压缩势能,由功能转化原理,给出了PELE前端外壳在靶后形成破片的最大径向飞散速度计算公式。计算结果在多种工况下均与文献的实验结果较为一致。计算结果表明:PELE靶后外壳破片的最大径向飞散速度与外壳和内芯材料的体积模量和泊松比有关,且随二者的增大而增大;PELE外壳破片的最大径向飞散速度是壳体和内芯在冲击波压缩作用下共同径向膨胀的结果,且外壳膨胀能在弹体整体膨胀能中所占比例较大,计算中应当同时考虑弹体外壳和内芯材料的横向膨胀效应对弹体破片径向飞散速度的影响。
  • 图  1  弹靶撞击后冲击波在弹靶中的传播示意图

    Figure  1.  Shock wave propagation in the target and the projectile

    图  2  实验弹体[13]

    Figure  2.  Experimental projectile[13]

    图  3  A-G3内芯PELE在不同工况下的靶后外壳破片最大径向速度

    Figure  3.  Maximum radial velocity of the jacket fragments of PELE with A-G3 as filling material under different conditions

    图  4  PE内芯PELE在不同工况下的靶后外壳破片最大径向速度

    Figure  4.  Maximum radial velocity of the jacket fragments of PELE with PE as filling material under different conditions

    图  5  不同工况下单位长度A-G3内芯PELE的外壳径向膨胀能占单位长度弹体整体径向膨胀能的百分比

    Figure  5.  Percentage of the unit-length radial expansion energy from the unit-length expansion energy of PELE with A-G3 as filling material

    图  6  不同工况下单位长度PE内芯PELE的外壳径向膨胀能占单位长度弹体整体径向膨胀能的百分比

    Figure  6.  Percentage of the unit-length radial expansion energy from the unit-length expansion energy of PELE with PE as filling material

    表  1  弹靶材料参数[6, 13]

    Table  1.   Material parameters of projectile and target[6, 13]

    弹/靶 材料 ρ/(g·cm-3) c0/(m·s-1) s K/GPa μ σy/GPa
    弹体 D180K 18.0 4029 1.237 292 0.28
    A-G3 2.65 5176 1.35 71 0.33
    PE 0.92 2187 1.48 4.4 0.44
    靶板 A-U4G 2.80 5106 1.35 0.43
    XC48 7.823 4797 1.49 0.72
    下载: 导出CSV

    表  2  A-G3内芯PELE穿靶后弹体破片的最大径向飞散速度

    Table  2.   Maximum radial velocity of the jacket fragments of PELE with A-G3 as filling material

    靶板材料 h/mm u0/(m·s-1) urad/(m·s-1)
    实测值[13] 计算值 计算值[13]
    A-U4G 3 929 112 123 135
    1275 158 164 193
    2457 333 289
    8 937 143 132 195
    1254 221 168 230
    2472 356 296
    2984 306 321
    XC48 3 925 184 198 226
    1261 243 255 288
    2441 492 418
    下载: 导出CSV

    表  3  PE内芯PELE穿靶后弹体破片的最大径向飞散速度

    Table  3.   Maximum radial velocity of the jacket fragments of PELE with PE as filling material

    靶板材料 h/mm u0/(m·s-1) urad/(m·s-1)
    实测值[13] 计算值 计算值[13]
    A-U4G 3 924 39 120 35
    1279 100 156 78
    2420 223 259
    8 939 112 129 123
    1258 184 161 148
    2445 321 167
    2977 348 300
    XC48 3 936 94 188 57
    1262 145 237 102
    2475 361 388
    下载: 导出CSV
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出版历程
  • 收稿日期:  2015-11-17
  • 修回日期:  2016-04-18
  • 刊出日期:  2017-07-25

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