纤维增强复合材料层合板销节点损伤建模与失效分析综述

Akash Gupta, Manjeet Singh, J. Singh, Sunpreet Singh, C. Prakash
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引用次数: 1

摘要

纤维增强复合材料以其轻量化、高强比等优点在结构工程中发挥着至关重要的作用,成为机械紧固销接头的关键材料。近年来在这方面的研究仅限于用于预测聚合物基复合材料中销连接强度的数值和实验方法。本研究首先对所提供的结构夹固节理区域的相关研究进行了广泛的分析,采用了多种数值方法和破坏理论。目前已有大量的实验和数值方法用于预测复合材料接头的损伤起裂和破坏模式,并被研究人员在各自的研究中引用。该研究回顾了利用交互准则进行破坏分析的复合材料节点的不同数值分析,即Tsai-Wu, Tsai-Hill, Yamada Sun的理论使用包含所有应力或应变分量的高阶多项式方程预测破坏,而极限应力准则即使用线性方程寻找解的最大应力准则。渐进式损伤分析(PDA)采用Hashin理论提出的材料耗竭规则对基体和纤维的破坏进行量化,该规则对复合材料的类型都有很好的解释。最后讨论了在不同载荷条件下提高接头性能的参数。
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A critical review on damage modeling and failure analysis of pin joints in fiber reinforced composite laminates
Fiber-reinforced composite material plays a vital role in structural engineering due to its lightweight and high strength ratio which becomes a key material in a mechanically fastened pin joint. Recent review articles in this area were restricted to the numerical and experimental approaches which are used for strength prediction of pin joints in polymer matrix composites. The present study begins with an extensive analysis of relevant studies in the provided structurally clamped joint region using numerous numerical approaches and theories of failure. Numerous experimental and numerical approaches are available nowadays and have been cited by the researchers in their respective research to foretell the damage initiation and failure mode in the composite joint. The study gives the review of different numerical analyses of composite joints by utilizing interactive criteria for failure analysis, viz. Tsai-Wu, Tsai-Hill, Yamada Sun’s theory predicts failure using higher-order polynomial equations that comprise all stress or strain components, whereas limit stress criteria i.e. Maximum stress criterion which uses linear equations for finding the solution. Progressive Damage Analysis (PDA) quantifies matrix and fiber failure using the material depletion rule preceded by Hashin’s theory which offers a good interpretation irrespective of the types of composite material. In the end, various parameters are discussed which enhance joint performance under different loading conditions.
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