碳纤维复合靶板抗破片冲击性能研究

李巧歌 梁增友 王春光 郝永强

李巧歌, 梁增友, 王春光, 郝永强. 碳纤维复合靶板抗破片冲击性能研究[J]. 高压物理学报, 2024, 38(4): 044103. doi: 10.11858/gywlxb.20240720
引用本文: 李巧歌, 梁增友, 王春光, 郝永强. 碳纤维复合靶板抗破片冲击性能研究[J]. 高压物理学报, 2024, 38(4): 044103. doi: 10.11858/gywlxb.20240720
LI Qiaoge, LIANG Zengyou, WANG Chunguang, HAO Yongqiang. Study on Anti-Fragment Impact Performance of Carbon Fiber Reinforced Plastics[J]. Chinese Journal of High Pressure Physics, 2024, 38(4): 044103. doi: 10.11858/gywlxb.20240720
Citation: LI Qiaoge, LIANG Zengyou, WANG Chunguang, HAO Yongqiang. Study on Anti-Fragment Impact Performance of Carbon Fiber Reinforced Plastics[J]. Chinese Journal of High Pressure Physics, 2024, 38(4): 044103. doi: 10.11858/gywlxb.20240720

碳纤维复合靶板抗破片冲击性能研究

doi: 10.11858/gywlxb.20240720
基金项目: 山西省科技厅省基础研究计划项目(202103021224210)
详细信息
    作者简介:

    李巧歌(1999-),女,硕士研究生,主要从事高效毁伤理论与技术、弹箭结构设计等研究. E-mail:1901041103@st.nuc.edu.cn

    通讯作者:

    梁增友(1969-),男,博士,教授,主要从事弹药装药与安全技术、弹箭高效毁伤与控制技术、弹箭结构设计与仿真、新型远程弹技术等研究. E-mail:liangzy@nuc.edu.cn

  • 中图分类号: O347; TJ04

Study on Anti-Fragment Impact Performance of Carbon Fiber Reinforced Plastics

  • 摘要: 为探究碳纤维复合材料的抗破片侵彻性能,进行了8 g立方体钢破片侵彻厚度分别为5、10、15 mm碳纤维复合材料靶板试验,获取破片着靶速度,并回收破片、靶板,观测靶板破坏情况。根据试验情况进行数值模拟,探究破片侵彻碳纤维复合材料靶板的过程及碳纤维复合材料靶板的破坏机理,由此得到靶板破坏形式与破片速度的关系:破片速度大于弹道极限时,靶板以纤维的剪切破坏为主;破片速度逐渐降低时,纤维的拉伸破坏、基体破裂与纤维层分层多种破坏形式所占比重随着破片速度的变化而变化。

     

  • 图  破片侵彻碳纤维复合材料靶板试验系统

    Figure  1.  Test system of fragments penetrating carbon fiber composite target

    图  8 g钢破片

    Figure  2.  8 g steel fragments

    图  破片和弹托装配

    Figure  3.  Fragments and sabots assembly

    图  破片和发射药筒装配

    Figure  4.  Fragment and propellant cartridge

    图  破片侵彻5 mm厚碳纤维复合材料靶板的破坏形态

    Figure  5.  Failure mode of fragment penetrating 5 mm thick carbon fiber composite target

    图  破片侵彻10 mm厚碳纤维复合材料靶板的破坏形态

    Figure  6.  Failure mode of fragment penetrating 10 mm thick carbon fiber composite target

    图  破片侵彻15 mm厚碳纤维复合材料靶板的破坏形态

    Figure  7.  Failure mode of fragment penetrating 15 mm thick carbon fiber composite target

    图  钢破片的有限元模型

    Figure  8.  Finite element model of the steel fragment

    图  碳纤维复合材料靶板有限元模型

    Figure  9.  Finite element model of carbon fiber composite target plate

    图  10  破片侵彻碳纤维复合材料有限元模型

    Figure  10.  Finite element model of fragment penetrating carbon fiber composite material

    图  11  破片以不同姿态侵彻碳纤维复合靶板

    Figure  11.  Fragments penetrating carbon fiber composite target plates with different attitudes

    图  12  破片侵彻碳纤维复合靶板过程

    Figure  12.  Process diagram of fragment penetrating carbon fiber composite target plate

    图  13  破片侵彻5 mm厚碳纤维复合材料靶板结果对比

    Figure  13.  Comparison of the results of fragment penetrating 5 mm thick carbon fiber composite target

    图  14  破片侵彻10 mm厚碳纤维复合材料靶板结果对比

    Figure  14.  Comparison of the results of fragment penetrating 10 mm thick carbon fiber composite target

    图  15  破片侵彻15 mm厚碳纤维复合材料靶板结果对比

    Figure  15.  Comparison of the results of fragment penetrating 15 mm thick carbon fiber composite target

    表  1  碳纤维复合材料的力学性能参数

    Table  1.   Mechanical properties of carbon fiber composites plate

    $ {\sigma }_{x\mathrm{t}} $/
    MPa
    $ {E}_{1\mathrm{t}} $/
    GPa
    $ {\sigma }_{y\mathrm{t}} $/
    MPa
    $ {E}_{2\mathrm{t}} $/
    GPa
    $ {\sigma }_{x\mathrm{c}} $/
    MPa
    $ {E}_{1\mathrm{c}} $/
    GPa
    $ {\sigma }_{y\mathrm{c}} $/
    MPa
    $ {E}_{2\mathrm{c}} $/
    GPa
    $ {\tau }_{12} $/
    MPa
    $ {G}_{12} $/
    GPa
    $ {\tau }_{\mathrm{J}} $/
    MPa
    $ {\gamma }_{12} $
    1755 138 48 8.36 1248 128 214 8.48 113 4.51 21.5 0.27
    下载: 导出CSV

    表  2  破片侵彻靶板的损伤区域统计

    Table  2.   Statistic of damage area of fragment penetrating target

    Target thickness/mm Failure pattern Impact velocity/
    (m·s–1)
    Damage area of the
    projectile surface/
    (mm×mm)
    Damage area of back
    elastic surface/
    (mm×mm)
    5 Local penetration 328 10.92×9.60 11.55×12.24
    Complete penetration 340 13.76×10.50 23.10×25.10
    10 Local penetration 398 10.63×10.21 29.80×31.42
    Complete penetration 412 14.56×10.36 30.30×17.22
    15 Local penetration 443 16.26×8.35
    Complete penetration 453 15.49×11.22 33.23×24.05
    下载: 导出CSV

    表  3  钢破片材料参数

    Table  3.   Material parameters of steel fragment

    $ \rho $/(g·cm–3) G/GPa A/MPa B/MPa n c M TM/K TR/K
    7.83 0.77 792 510 0.26 0.014 1.03 1793 294
    下载: 导出CSV

    表  4  试验和数值模拟得到的弹道极限误差

    Table  4.   Ballistic limit error of test and numerical simulation

    Target thickness/mm Ballistic limit velocity/(m·s–1) Deviation/%
    Test Simulation
    5 334 307.76 7.86
    10 405 394.78 2.52
    15 448 437.55 2.33
    下载: 导出CSV
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出版历程
  • 收稿日期:  2024-01-30
  • 修回日期:  2024-02-23
  • 刊出日期:  2024-07-25

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