The Effect of Material Heterogeneity on the Shock Response of Layered Systems in Plate Impact Tests

Journal of Composites Technology & Research Pub Date : 2002-12-01 DOI:10.1520/CTR10929J

N. Chandra, Xianglei Chen, A. Rajendran

{"title":"The Effect of Material Heterogeneity on the Shock Response of Layered Systems in Plate Impact Tests","authors":"N. Chandra, Xianglei Chen, A. Rajendran","doi":"10.1520/CTR10929J","DOIUrl":null,"url":null,"abstract":"In the study of shock wave propagation in solids, scattering, dispersion, and attenuation play a critical role in determining the thermomechanical response of the media. These phenomena can be attributed to a number of nonlinearities arising from the wave characteristics, loading conditions, material heterogeneity (measured at various spatial scales ranging from nanometers to a few millimeters). The nonlinear effects in general can be ascribed to impedance (and geometric) mismatch present at various length scales as often encountered in composite material systems, apart from material nonlinearities arising from inelastic effects, void nucleation and growth, cracking, and delamination. However, in nearly brittle material systems, elastic effects dominate and is the only effect considered here. Uniaxial strain experiments on the S-2 glass/polymer composite system display markedly different behavior than that observed in monolithic metallic systems [6] and this motivated the present work. Stress profiles measured at various locations along the direction of wave propagation in the plate impact experiments showed that the shock wave rise time increased with propagation in addition to the reduction of peak stress. In this work, we specifically address the issue of shock wave rise time in a simplified multi-layered system. A careful analysis of wave propagation in heterogeneous medium is performed by considering the elastic/acoustic properties of individual lamina in a layered system. An analytical model has been developed to describe the scattering process (reflection/transmission) at various layer interfaces of multilayer composite system. FEM results are then used to compare with the analytical predictions. These results show that the rise time can be a consequence of multiple internal reflections and transmissions occurring at the heterogeneous interfaces, it is further shown that the rise time depends on the magnitude of impedance mismatch and the number of layers.","PeriodicalId":15514,"journal":{"name":"Journal of Composites Technology & Research","volume":"38 1","pages":"232-238"},"PeriodicalIF":0.0000,"publicationDate":"2002-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"7","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Composites Technology & Research","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1520/CTR10929J","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 7

Abstract

In the study of shock wave propagation in solids, scattering, dispersion, and attenuation play a critical role in determining the thermomechanical response of the media. These phenomena can be attributed to a number of nonlinearities arising from the wave characteristics, loading conditions, material heterogeneity (measured at various spatial scales ranging from nanometers to a few millimeters). The nonlinear effects in general can be ascribed to impedance (and geometric) mismatch present at various length scales as often encountered in composite material systems, apart from material nonlinearities arising from inelastic effects, void nucleation and growth, cracking, and delamination. However, in nearly brittle material systems, elastic effects dominate and is the only effect considered here. Uniaxial strain experiments on the S-2 glass/polymer composite system display markedly different behavior than that observed in monolithic metallic systems [6] and this motivated the present work. Stress profiles measured at various locations along the direction of wave propagation in the plate impact experiments showed that the shock wave rise time increased with propagation in addition to the reduction of peak stress. In this work, we specifically address the issue of shock wave rise time in a simplified multi-layered system. A careful analysis of wave propagation in heterogeneous medium is performed by considering the elastic/acoustic properties of individual lamina in a layered system. An analytical model has been developed to describe the scattering process (reflection/transmission) at various layer interfaces of multilayer composite system. FEM results are then used to compare with the analytical predictions. These results show that the rise time can be a consequence of multiple internal reflections and transmissions occurring at the heterogeneous interfaces, it is further shown that the rise time depends on the magnitude of impedance mismatch and the number of layers.

查看原文本刊更多论文

板冲击试验中材料非均质性对层状系统冲击响应的影响

在研究激波在固体中的传播时，散射、色散和衰减在决定介质的热力学响应方面起着关键作用。这些现象可归因于波浪特性、加载条件、材料非均质性(在从纳米到几毫米的各种空间尺度上测量)引起的许多非线性。除了非弹性效应、空洞成核和生长、开裂和分层引起的材料非线性外，非线性效应一般可归因于复合材料系统中经常遇到的各种长度尺度上的阻抗(和几何)不匹配。然而，在近脆性材料系统中，弹性效应占主导地位，并且是这里唯一考虑的效应。S-2玻璃/聚合物复合材料系统的单轴应变实验显示出与单片金属系统[6]明显不同的行为，这是本研究的动机。在平板冲击实验中沿波传播方向不同位置测量的应力剖面表明，冲击波上升时间随传播而增加，峰值应力随传播而减小。在这项工作中，我们专门解决了一个简化的多层系统中激波上升时间的问题。通过考虑层状系统中各个层的弹性/声学特性，对波在非均质介质中的传播进行了仔细的分析。建立了描述多层复合材料系统在不同层界面处散射过程(反射/透射)的解析模型。然后用有限元计算结果与分析预测结果进行比较。这些结果表明，上升时间可能是发生在非均质界面上的多次内部反射和传输的结果，进一步表明上升时间取决于阻抗失配的大小和层数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Journal of Composites Technology & Research

自引率

0.00%

发文量