The effect of matrix cracking on mechanical properties in FRP laminates

M.J. Mohammad Fikry, Shinji Ogihara, Vladimir Vinogradov
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引用次数: 24

Abstract

Fiber Reinforced Polymer (FRP) laminates have properties, which are highly dependent on the ply fiber orientations and which can be designed for optimum laminate performance. The purpose of this study is to investigate the effect of matrix cracking on the mechanical properties of FRP laminates with various off-axis angles, and to provide a critical test for an analytical solution using variational stress analysis.

Carbon and glass fiber reinforced polymer laminates (CFRP and GFRP) are tested. FRP prepregs are cured by using autoclave method to form laminates with layups [θm/ φn]s. The laminates are then loaded monotonically and cyclically to obtain their mechanical properties and the effect of matrix cracks on the properties. Some of the effects include reduction of laminates’ stiffness and residual strains after unloading. In order to obtain higher crack densities in specimens, artificial cracks method was introduced in this study, where notches were made at the edges of some specimens before tested in tension. Cracks observation for CFRP laminates is done by using the X-ray technique, while for GFRP laminates a DSLR camera is used.

The measured stiffness reduction as a function of the crack density is compared to an analytical prediction for cracked angle-ply laminates based on a variational stress analysis. The experimental results for stiffness reduction agree well with the analytical results.

Understanding the behavior of damaged laminates with simple configurations, as performed in this study, is of high importance for prediction of damage effects on laminates with more complex configuration, e.g. with quasi-isotropic layups.

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基体开裂对玻璃钢复合材料力学性能的影响
纤维增强聚合物(FRP)层压板具有高度依赖于纤维取向的性能,并且可以设计为最佳层压板性能。本研究的目的是研究不同离轴角度下基体开裂对玻璃钢层合板力学性能的影响,并为变分应力分析的解析解提供关键测试。碳和玻璃纤维增强聚合物层压板(CFRP和GFRP)进行了测试。采用高压灭菌法固化FRP预浸料,形成层数为[θm/ φn]s的层压板。然后对复合材料进行单调和循环加载,得到复合材料的力学性能以及基体裂纹对复合材料力学性能的影响。一些影响包括降低层合板的刚度和卸载后的残余应变。为了在试样中获得更高的裂纹密度,本研究引入了人工裂纹法,在拉伸试验前,在部分试样的边缘处做缺口。CFRP层合板的裂纹观测采用x射线技术,GFRP层合板的裂纹观测采用单反相机。测量的刚度降低作为裂纹密度的函数与基于变分应力分析的角层合板裂纹的分析预测进行了比较。刚度折减的实验结果与分析结果吻合较好。在本研究中,理解具有简单结构的损伤层压板的行为,对于预测具有更复杂结构的层压板(例如准各向同性层压板)的损伤效应具有重要意义。
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