Impact action on fiber and composite material based on it

Physics and Chemistry of Materials Treatment Pub Date : 1900-01-01 DOI:10.30791/0015-3214-2020-6-69-74

V. Kudinov, I. Krylov, N. Korneeva

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Abstract

The low-velosity impact properties and failure mechanisms of ultra-high molecular weight polyethylene (UHMWPE) fiber (Dyneema®SK-75) and a composite material (CM) based on it with the rigid and flexible matrices were investigated by the “Impact Break” (IB) method. A fundamental difference in deformation behavior and failure mechanisms upon impact on the UHMWPE-fiber and on the CM based on this fiber has been investigated experimentally. It is shown that impact has a little effect on the properties of UHMWPE-fiber, since it is an isotropic material. It has been established that upon impact, the properties of a fiber without a matrix were significantly higher than the properties of CM based on it. Impact action stimulates the interaction between CM components (fibers and matrix). Mechanism of stepwise deformation of anisotropic CM is occurred, which begins from the first moment of impact and ends with the destruction of the CM. A “stairway of deformation” behavior is observed in anisotropic materials. Stepwise deformation is the main form of deformation and the basic mechanism of failure of anisotropic composite materials upon impact.

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影响作用在纤维和基于它的复合材料上

采用“冲击断裂”(impact Break, IB)方法研究了超高分子量聚乙烯(UHMWPE)纤维(Dyneema®SK-75)及其复合材料(CM)的低速冲击性能和失效机理。实验研究了uhmwpe纤维和基于该纤维的CM受冲击时变形行为和破坏机制的根本差异。结果表明，冲击对超高分子量聚乙烯纤维的性能影响不大，因为它是一种各向同性材料。研究表明，无基体纤维的冲击性能明显高于基于基体的CM纤维的性能。冲击作用刺激CM成分(纤维和基质)之间的相互作用。分析了各向异性复合材料的逐步变形机理，该过程从撞击的第一个瞬间开始，到复合材料的破坏结束。在各向异性材料中观察到“阶梯变形”行为。逐步变形是各向异性复合材料在冲击作用下的主要变形形式和破坏的基本机制。

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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Physics and Chemistry of Materials Treatment

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