复合材料均质技术:无网格配方

D.E.S. Rodrigues , J. Belinha , F.M.A. Pires , L.M.J.S. Dinis , R.M. Natal Jorge
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引用次数: 4

摘要

非均质材料的结构性能分析是工程领域的一个研究课题。一些非均质材料具有宏观尺度的行为,如果不考虑发生在低维尺度上的复杂过程,就无法预测。因此,文献中经常提出多尺度方法来更好地预测这些材料的均匀力学性能。本研究采用了一种适合模拟非均质材料的多尺度数值转换技术,并将其与一种无网格方法——径向点插值法(RPIM)[1]相结合。无网格方法只需要一个非结构化的节点分布来离散问题域。在RPIM的情况下,利用背景积分网格对Galerkin弱形式的积分微分方程进行数值积分。节点连通性是通过在每个集成点中定义的影响域的重叠来实现的。在这项工作中,使用平面应变公式,对代表性体积元(RVE)进行建模,并对其施加周期边界条件。实现了计算均匀化,确定了复合材料的有效弹性性能。最后,将RPIM和低阶有限元法得到的解与文献中提供的解进行了比较。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Material homogenization technique for composites: A meshless formulation

The analysis of the structural behaviour of heterogeneous materials is a topic of research in the engineering field. Some heterogeneous materials have a macro-scale behaviour that cannot be predicted without considering the complex processes that occur in lower dimensional scales. Therefore, multi-scale approaches are often proposed in the literature to better predict the homogeneous mechanical properties of these materials. This work uses a multi-scale numerical transition technique, suitable for simulating heterogeneous materials, and combines it with a meshless method – the Radial Point Interpolation Method (RPIM) [1]. Meshless methods only require an unstructured nodal distribution to discretize the problem domain. In the case of the RPIM, the numerical integration of the integro-differential equation from the Galerkin weak form is performed using a background integration mesh. The nodal connectivity is enforced by the overlap of influence-domains defined in each integration point. In this work, using a plane-strain formulation, representative volume elements (RVE) are modelled and periodic boundary conditions are imposed on them. A computational homogenization is implemented and effective elastic properties of a composite material are determined. In the end, the solutions obtained using the RPIM and also a lower-order Finite Element Method are compared with the ones provided in literature.

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