Mode-I and Mode-II Crack Tip Fields in Implicit Gradient Elasticity Based on Laplacians of Stress and Strain. Part II: Asymptotic Solutions

Nanomechanics [Working Title] Pub Date : 2020-10-10 DOI:10.5772/intechopen.93618

C. Broese, Jan Frischmann, C. Tsakmakis

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Abstract

We develop asymptotic solutions for near-tip fields of Mode-I and Mode-II crack problems and for model responses reflected by implicit gradient elasticity. Especially, a model of gradient elasticity is considered, which is based on Laplacians of stress and strain and turns out to be derivable as a particular case of micromorphic (microstrain) elasticity. While the governing model equations of the crack problems are developed in Part I, the present paper addresses analytical solutions for near-tip fields by using asymptotic expansions of Williams’ type. It is shown that for the assumptions made in Part I, the model does not eliminiate the well-known singularities of classical elasticity. This is in contrast to conclusions made elsewhere, which rely upon different assumptions. However, there are significant differences in comparison to classical elasticity, which are discussed in the paper. For instance, in the case of Mode-II loading conditions, the leading terms of the asymptotic solution for the components of the double stress exhibit the remarkable property that they include two stress intensity factors.

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基于应力应变拉普拉斯函数的隐式梯度弹性中ⅰ型和ⅱ型裂纹尖端场。第二部分:渐近解

我们给出了i型和ii型裂纹问题的近尖场和隐式梯度弹性反映的模型响应的渐近解。特别地，考虑了一种梯度弹性模型，该模型是基于应力和应变的拉普拉斯函数，并作为微态(微应变)弹性的特殊情况而被证明是可推导的。虽然裂纹问题的控制模型方程在第一部分中得到了发展，但本文利用Williams型的渐近展开式给出了近尖端场的解析解。结果表明，对于第一部分中所作的假设，该模型并没有消除经典弹性力学中众所周知的奇点。这与其他地方得出的结论相反，这些结论依赖于不同的假设。但是，与经典弹性力学相比，存在着显著的差异，本文对此进行了讨论。例如，在ii型加载条件下，双应力分量的渐近解的主要项表现出包含两个应力强度因子的显著特性。

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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Nanomechanics [Working Title]

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