Transverse cracking and delamination in composite materials

Fibre Science and Technology Pub Date : 1983-04-01 DOI:10.1016/0015-0568(83)90041-6

R.Y. Kim, R.M. Aoki

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引用次数: 12

Abstract

An experimental investigation has been conducted on damage behaviour related with matrix cracking under static and fatigue loading using two stacking sequences of the (0/90_n/±45)_s and (0/±45/90_n)_s laminates for n = 1, 3, and 6. The latter stacking sequence produces tensile interlaminar normal stress along free edges of a tensile coupon, whereas the other stacking sequence produces compression at the same edges. Emphasis in this study was on the interaction between transverse cracks and delamination, and effect of layer thickness on crack density and propagation. Transverse crack and delamination were periodically measured by interrupting testing until final failure. Experimental results indicate that the crack density and propagation are influenced by layer thickness, and delamination appears to be mainly governed by either, or a combination of, tensile interlaminar normal stress and size of transverse crack. The applied force at incipient delamination can be predicted by an existing theory with a certain limitation.

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复合材料的横向开裂和分层

使用（0/90n/±45）s和（0/±45/90n）s层压板的两个堆叠顺序，对静载荷和疲劳载荷下与基体开裂相关的损伤行为进行了实验研究，其中n=1、3和6。后一种堆叠顺序沿着拉伸试片的自由边缘产生拉伸层间法向应力，而另一种堆叠序列在相同边缘产生压缩。本研究的重点是横向裂纹和分层之间的相互作用，以及层厚度对裂纹密度和扩展的影响。通过中断测试定期测量横向裂纹和分层，直到最终失效。实验结果表明，裂纹密度和扩展受层厚的影响，分层似乎主要受层间拉伸正应力和横向裂纹尺寸的控制，或两者的组合。在存在一定局限性的情况下，现有理论可以预测初始分层时施加的力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Fibre Science and Technology

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