球头弹体侵彻舰船板架加强筋时的攻角变化简化理论模型

姚熊亮 王治 叶墡君 吴子奇 王志凯

姚熊亮, 王治, 叶墡君, 吴子奇, 王志凯. 球头弹体侵彻舰船板架加强筋时的攻角变化简化理论模型[J]. 爆炸与冲击, 2021, 41(3): 033301. doi: 10.11883/bzycj-2020-0092
引用本文: 姚熊亮, 王治, 叶墡君, 吴子奇, 王志凯. 球头弹体侵彻舰船板架加强筋时的攻角变化简化理论模型[J]. 爆炸与冲击, 2021, 41(3): 033301. doi: 10.11883/bzycj-2020-0092
YAO Xiongliang, WANG Zhi, YE Shanjun, WU Ziqi, WANG Zhikai. A simplified theoretical model for attack angle change of a hemispherically-nosed projectile while penetrating the stiffener of a ship plate frame[J]. Explosion And Shock Waves, 2021, 41(3): 033301. doi: 10.11883/bzycj-2020-0092
Citation: YAO Xiongliang, WANG Zhi, YE Shanjun, WU Ziqi, WANG Zhikai. A simplified theoretical model for attack angle change of a hemispherically-nosed projectile while penetrating the stiffener of a ship plate frame[J]. Explosion And Shock Waves, 2021, 41(3): 033301. doi: 10.11883/bzycj-2020-0092

球头弹体侵彻舰船板架加强筋时的攻角变化简化理论模型

doi: 10.11883/bzycj-2020-0092
基金项目: 国家自然科学基金(52001091,51779056);黑龙江省自然科学基金(E2017026)
详细信息
    作者简介:

    姚熊亮(1963- ),男,博士,教授,xiongliangyao@hrbeu.edu.cn

    通讯作者:

    王 治(1985- ),男,博士,讲师,wang_z@hrbeu.edu.cn

  • 中图分类号: O385

A simplified theoretical model for attack angle change of a hemispherically-nosed projectile while penetrating the stiffener of a ship plate frame

  • 摘要: 舰船板架结构加强筋对于弹体侵彻着角与攻角变化有较大影响,而目前对此尚无理论模型。本文开展板架加强筋对弹体攻角变化的理论研究。针对刚性球头弹体侵彻舰船板架结构加强筋问题,将加强筋简化为刚塑性梁模型,建立了侵彻过程力学模型,给出了弹体剩余速度、着角和攻角变化的求解公式。公式表明弹体攻角与着角的变化与弹体初始速度、初始着角、初始攻角以及加强筋极限弯矩有关。通过编程求解理论公式,发现初始着角对于侵彻结束攻角和着角变化的影响大于初始攻角;初始着角超过某一值后,攻角改变会急剧增大,而当初始着角超过另一极限值后会发生弹体跳飞;初始速度越高,弹体侵彻结束后着角和攻角变化越小;加强筋的极限弯矩对弹体攻角改变有较大影响。
  • 图  1  着角与攻角示意图

    Figure  1.  Schematic diagram of impact angle and attack angle

    图  2  弹体侵彻板架结构示意图与简化模型

    Figure  2.  The diagrammatic sketch and simplified model for a projectile penetrating a ship plate frame

    图  3  加强筋运动速度场

    Figure  3.  Velocity field of the stiffener

    图  4  弹体质心位移

    Figure  4.  Displacement of the mass center of the projectile

    图  5  侵彻结束后弹体质心速度

    Figure  5.  Centroid velocity of the projectile after penetration

    图  6  实验靶标示意图[13]

    Figure  6.  Schematic diagram of the experimental target[13]

    图  7  侵彻过程中Δα随时间变化曲线

    Figure  7.  Time varying curves of Δα in the penetration process

    图  8  侵彻结束时转角改变Δαm与初始攻角的关系

    Figure  8.  Relationship between the change of rotation angle and the initial attack angle

    图  9  侵彻结束时着角改变Δβm与初始攻角的关系

    Figure  9.  Relationship between the change of impact angle and the initial attack angle

    图  10  飞行至下层甲板时攻角变化Δφ与初始攻角的关系

    Figure  10.  Relationship between the change of attack angle Δφ at the next deck and the initial attack angle

    图  11  剩余速度随初始攻角变化图

    Figure  11.  Residual velocity versus initial attack angle

    图  12  侵彻结束时转角改变Δαm与初始着角的关系

    Figure  12.  Relationship between the change of rotation angle and the initial impact angle

    图  13  飞行至下层甲板时攻角变化Δφ与初始着角的关系

    Figure  13.  Relationship between the change of attack angle Δφ at the next deck and the initial impact angle

    图  14  初始速度对着角改变的影响

    Figure  14.  The influence of initial velocity on the change of impact angle

    图  15  初始速度对飞行至下层甲板时攻角变化Δφ的影响

    Figure  15.  The influence of initial velocity on the change of attack angle Δφ at the next deck

    图  16  梁的极限弯矩M0对着角和攻角改变的影响

    Figure  16.  The influence of the ultimate moment of the beam on the changes of impact angle and attack angle

    表  1  板架结构与弹体材料参数

    Table  1.   Material parameters of the plate frame and the projectile

    材料型号密度/(kg·m−3弹性模量/GPa泊松比屈服应力/MPa硬化模量/GPaDp
    921A7 8502020.306851.0608 0000.8
    30CrMnSiNi2A7 8505170.281 6000.5944 3220.2
    下载: 导出CSV

    表  2  板架结构参数表

    Table  2.   Structural parameters of the plate frame

    板厚/mm纵骨横梁
    尺寸/mm间距/m尺寸/mm间距/m
    8$\bot \dfrac{ { {\rm{115} } \times 1{\rm{5} } } }{ {1{\rm{00} } \times {\rm{15} } } }$0.6$\bot \dfrac{ {200 \times 6} }{ {80 \times 8} }$1.2
    下载: 导出CSV

    表  3  数值与理论剩余速度结果比对

    Table  3.   Comparison of the numerical and theoretical results of the residual velocity

    v0/(m∙s−1β0/(°)φ0/(°)Δv/(m∙s−1
    理论数值误差/%
    75010514.6416.5911.8
    75020514.7816.8812.4
    75030514.9817.5214.5
    75040515.3418.8318.5
    75050516.1119.1315.8
    750401015.4217.9914.3
    650401018.3520.7911.7
    550401023.0425.5910.0
    下载: 导出CSV

    表  4  数值与理论着角结果比对

    Table  4.   Comparison of the numerical and theoretical results of the impact angle

    v0/(m∙s−1)β0/(°)φ0/(°)Δβm/(°)
    理论数值误差/%
    7501050.230.2015.0
    7502050.440.3912.8
    7503050.750.70 7.2
    7504051.070.98 9.2
    7505051.511.3115.3
    75040101.020.97 5.2
    65040101.431.32 8.3
    55040102.142.01 6.5
    45040102.512.39 5.0
    下载: 导出CSV

    表  5  数值与理论攻角结果比对

    Table  5.   Comparison of the numerical and theoretical results of the attack angle

    v0/(m∙s−1)β0/(°)φ0/(°)Δφ/(°)
    理论数值误差/%
    7501050.080.0714.3
    7502050.170.166.3
    7503050.190.185.6
    7504050.230.2015.0
    7505052.011.924.7
    75040100.430.47.5
    65040101.211.155.2
    55040104.984.569.2
    45040105.355.212.7
    下载: 导出CSV

    表  6  靶标板架结构参数[13]

    Table  6.   Structural parameters of the target frame[13]

    靶板材料板厚纵骨截面积横梁截面积纵骨间距横梁间距
    第1层907At34.4t291.9t2δl3.65δl
    第2层921A2t34.4t291.9t2δl3.65δl
    第3层907At34.4t291.9t2δl3.65δl
    第4层907At34.4t291.9t2δl3.65δl
    下载: 导出CSV

    表  7  试验与理论结果比对

    Table  7.   Comparison of experimental and theoretical results

    靶板侵彻后无量纲剩余速度${v_{\rm{r}}}/{v_0}$弹体着靶姿态角$(\varphi + \beta )$/(°)
    实验[13]理论误差实验[13]理论误差
    第1层0.96942.842.80%
    第2层0.9380.9592.2%48.3
    第3层0.8920.9102.0%50.855.28.7%
    第4层0.8680.8710.3%59.666.311.2%
    下载: 导出CSV
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出版历程
  • 收稿日期:  2020-03-30
  • 修回日期:  2020-11-29
  • 网络出版日期:  2021-01-25
  • 刊出日期:  2021-03-10

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