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破片侵彻纤维复合材料板的有限元数值模拟 被引量:7

Finite element simulation of FRP plates impacted by fragments
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摘要 采用有限元方法对几种不同外形和材料的破片模拟弹垂直侵彻玻璃纤维增强复合材料层合板的动态响应过程进行了模拟分析,研究了靶板有限元模型网格尺度对抗破片侵彻特性模拟计算结果的影响,分析了靶板直径和边界约束条件等因素对复合材料板的抗破片特性的影响。对于厚度为4.0mm以上的较厚靶板,几种常用的13.4g钢质破片模拟弹的外形和材料的差异对侵彻能力影响较小。与已有文献中的实验结果的比较表明:当有限元网格尺度接近复合材料单层厚度时,计算结果的精度较好;当靶板直径大于一个与靶板材料波速相关的临界直径时,靶板直径、边界约束条件对破片模拟弹剩余速度的影响可忽略;完全固支条件的计算结果比简支或自由边界条件更接近于大尺寸靶板的计算结果。 The dynamic response of fiber reinforced composites impacted by fragment simulating projectiles(FSPs) of different shapes and materials was simulated with the finite element method.Studies were performed on the influence of the target's finite element mesh size to the particle penetration.The effects of the target plate diameter and boundary conditions on the ballistic analysis results were also investigated.The differences in the perforation probability of 13.4 g steel FSPs with different shapes and materials is negligible for composite targets thicker than about 4 mm.The numerically predicted ballistic limit velocities agree well with experimental results only with mesh sizes close to the ply layer thickness.If the target plate diameter is larger than a critical value related to the plate material wave speed,the target plate diameter and boundary conditions have almost no effect on the predicted fragment residual velocity.Simulations with fully clamped boundary condition are closer to those of a large target plate than with simply supported boundaries or fully free conditions.
作者 谢恒 吕振华
机构地区 清华大学汽车工程系
出处 《清华大学学报(自然科学版)》 EI CAS CSCD 北大核心 2012年第1期96-101,共6页 Journal of Tsinghua University(Science and Technology)
关键词 弹道冲击 破片模拟弹 纤维增强复合靶板 有限元网格尺度 边界条件 ballistic impact fragment simulating projectiles composite target finite element mesh size boundary condition
分类号 TJ810.38 [兵器科学与技术—武器系统与运用工程]
  • 相关文献

参考文献11

  • 1Deka L J, Bartus S D, Vaidya U K. Damage evolution and energy absorption of FRP plates subjected to ballistic impact using a numerical model[C]// 9th International LS-DYNA Users Conference. Dearborn= Livermore Software Technology Corporation, 2006: 49 - 60.
  • 2STANAG 4569. Protection Levels for Occupants of Logistic and Light Armored Vehicles [S]. Brussels: North Atlantic Treaty Organization, 2005.
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  • 4GJB5115-2004.军用防弹头盔安全技术性能要求[S].北京:中国人民解放军总后勤部,2004.
  • 5Talebi H, Wong S V, Hamouda A M S. Finite element evaluation of projectile nose angle effects in ballistic perforation of high strength fabric [J]. Composite Structures, 2009, 87(4) : 314 - 320.
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二级参考文献12

  • 1Livermore Software Technology Corporation. LS-DYNA keyword user's manual (970v) [M]. Livermore Software Technology Corporation, 2003 : 778.
  • 2GU Bohong,XU Jingyi. Finite element calculation of 4-step 3-dimensional braided composite under ballistic perforation [J ]. Composites Part B : Engineering, 2004,35 (4) : 291-297.
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  • 4Gu Bohong. Analytical modeling for the ballistic perforation of planar plain-woven fabric target by projectile [J]. Composites Part B : Engineering, 2003,34 (4) : 361-371.
  • 5Billon H H, Robinson D J, Models for the ballistic impact of fabric armour[J]. International Journal of Impact Engineering, 2001,25 (4) :411-422.
  • 6Karahan M, Kus A, Eren R. An investigation into ballistic performance and energy absorption capabilities of woven aramid fabrics[J]. International Journal of Impact Engineering,2008, 35(6) :499-510.
  • 7Cork C R,Foster P W. The ballistic performance of narrow fabrics[J]. International Journal of Impact Engineering,2007, 34(3) :495-508.
  • 8Tan V B C, Lim C T, Cheong C H. Perforation of high-strength fabric by projectiles of different geometry [J ]. International Journal of Impact Engineering, 2003,28 (2) : 207-222.
  • 9Lim C T, Tan V B C, Cheong C H. Perforation of high-strength double-ply fabric system by varying shaped projectiles [J]. International Journal of Impact Engineering,2002,27 (6) :577- 591.
  • 10Duan Y, Keefe M, Bogetti T A, et al. A numerical investigation of the influence of friction on energy absorption by a highstrength fabric subjected to ballistic impact [J]. International Journal of Impact Engineering, 2006,32 (8) : 1299-1312.

共引文献5

同被引文献75

引证文献7

二级引证文献42

清华大学学报(自然科学版)
2012年 第1期

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