孔洞排布对PMMA多孔材料冲击响应行为的影响

罗国强 费细欢 喻寅 张睿智 张成成 沈强

罗国强, 费细欢, 喻寅, 张睿智, 张成成, 沈强. 孔洞排布对PMMA多孔材料冲击响应行为的影响[J]. 高压物理学报, 2020, 34(5): 054202. doi: 10.11858/gywlxb.20200542
引用本文: 罗国强, 费细欢, 喻寅, 张睿智, 张成成, 沈强. 孔洞排布对PMMA多孔材料冲击响应行为的影响[J]. 高压物理学报, 2020, 34(5): 054202. doi: 10.11858/gywlxb.20200542
LUO Guoqiang, FEI Xihuan, YU Yin, ZHANG Ruizhi, ZHANG Chengcheng, SHEN Qiang. Effect of Voids Arrangement on Behavior of PMMA Cellular Materials on Impact Loading[J]. Chinese Journal of High Pressure Physics, 2020, 34(5): 054202. doi: 10.11858/gywlxb.20200542
Citation: LUO Guoqiang, FEI Xihuan, YU Yin, ZHANG Ruizhi, ZHANG Chengcheng, SHEN Qiang. Effect of Voids Arrangement on Behavior of PMMA Cellular Materials on Impact Loading[J]. Chinese Journal of High Pressure Physics, 2020, 34(5): 054202. doi: 10.11858/gywlxb.20200542

孔洞排布对PMMA多孔材料冲击响应行为的影响

doi: 10.11858/gywlxb.20200542
基金项目: 国家自然科学基金重点项目(51932006);湖北省技术创新专项重大项目(2019AFA176)
详细信息
    作者简介:

    罗国强(1980-),男,博士,教授,主要从事先进复合材料研究. E-mail:luogq@whut.edu.cn

    通讯作者:

    喻 寅(1986-),男,博士,副研究员,主要从事爆炸冲击模拟研究. E-mail:yuyun86@caep.cn

  • 中图分类号: O347.5

Effect of Voids Arrangement on Behavior of PMMA Cellular Materials on Impact Loading

  • 摘要: 多孔材料具有轻质、缓冲减震、吸能等特点,在加载路径调控、爆炸或冲击防护领域具有广泛的应用前景。采用格点-弹簧模型(离散元方法),模拟多种孔洞排布方式的PMMA多孔材料在冲击加载过程中的早期孔洞塌缩破坏、应力分布与粒子速度等冲击响应行为。结果表明:在冲击加载过程中,裂纹萌发于孔洞侧向(垂直于冲击波方向)附近区域,孔洞破坏形式以剪切断裂为主;在不同的孔洞排列模型中,孔洞与孔洞之间均存在剪切裂纹相互贯通现象,促进孔洞体积压缩致密化,且孔洞排列方式不影响冲击波传播速度;四角点阵模型有效减缓孔洞附近区域的应力集中;四角点阵、三角点阵、锥形递减排列、锥形递增排列模型都显著影响PMMA多孔材料的冲击波阵面平整性;孔洞的随机排列模型对降低粒子速度最有效,四角点阵排列模型对降低波阵面后压力贡献最大。

     

  • 图  相邻两颗粒间的相互作用示意图

    Figure  1.  Schematic of the interaction between adjacent particles

    图  基于格点-弹簧模型的冲击压缩构型

    Figure  2.  Configuration of the shock compression model based on the lattice-spring model

    图  多孔材料的孔洞排列模型

    Figure  3.  Arrangement modes of voids of the cellular materials

    图  不同时刻下5种孔洞排列模型的裂纹扩展

    Figure  4.  Crack growth patterns of five arrangement models of voids at various times

    图  孔洞附近区域剪切裂纹(a)和颗粒破碎填充孔洞示意图(b)

    Figure  5.  Shear cracks in the area around the void (a) and schematic of particle-fragmentation-filled void (b)

    图  不同时刻5种孔洞排列模型的应力分布云图

    Figure  6.  Stress distributions of five arrangement models of voids at various times

    图  5种孔洞排列模型的粒子速度剖面

    Figure  7.  Particle velocity profiles of voids for five arrangement modes

    表  1  模型各部分材料的物性参数

    Table  1.   Specific physical parameters of each part of the model

    MaterialR/μm$\delta $/μmE/GPa$\;\mu$$\;\rho$/(kg·m−3)$\gamma $/(J·m−2)
    Cu2001100.258 96050 000
    PMMA1020030.201 18010
    LiF200650.102 640
    下载: 导出CSV

    表  2  5种孔洞排列模型中的粒子速度与波阵面后应力

    Table  2.   Particle velocities and stresses in the five arrangements modes of void

    ModesParticle velocity/(m·s−1)Stress/MPa
    Random lattice142.656.11
    Square lattice155.029.74
    Triangular lattice151.562.84
    Decreasing lattice161.758.13
    Increasing lattice158.955.39
    下载: 导出CSV
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  • 收稿日期:  2020-04-10
  • 修回日期:  2020-05-04

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