Explicit Phase-Field Regularized Voronoi-Based Lattice Model for Quasi-Brittle Fracture and Its Finite Element Implementation

IF 0.9 4区材料科学

Science of Advanced Materials Pub Date : 2023-08-01 DOI:10.1166/sam.2023.4512

Shijun Wang, Jing Yang, Zhong Zhang, Kui Liang, Siqi Yuan, Teng Tong, Tao Wang

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Abstract

In this study, the conventional Voronoi-based irregular lattice model is regularized by the phase-field method, which effectively introduces a characteristic length parameter to overcome the mesh-size dependent solution. To circumvent the local instability (snap-back) which generally requires sophisticated arc-length control, the so-called phase-field regularized Voronoi-based lattice ( PHL ) model is realized using an explicit finite element solver. Furthermore, the constitutive law of quasi-brittle materials is embraced when establishing the PHL model, which is proven length-scale insensitive. We show that the PHL model with an explicit solver is very robust and computationally efficient, provided with proper parameters and parallel computing. Moreover, the necessary fine mesh size in the implicit phase-field method is greatly released in the explicit PHL model, of which accurate results could be obtained with the coarser mesh size. Several experiments are adopted to demonstrate the model, including the size effect and mix-mode bending of concrete specimens. Cracks’ initiation, propagation, and coalescence could be automatically captured without any tracking algorithms. In addition, it is noteworthy that the model could easily be extended to coupled mechanical and transportation problems.

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准脆性断裂的显式相场正则化voronoi晶格模型及其有限元实现

本文采用相场法对传统的基于voronoi的不规则晶格模型进行正则化，有效地引入了特征长度参数，克服了网格大小依赖的问题。为了避免通常需要复杂弧长控制的局部不稳定(弹回)，使用显式有限元求解器实现了所谓的相场正则化Voronoi-based lattice (PHL)模型。此外，在建立PHL模型时考虑了准脆性材料的本构规律，证明了该模型具有长度尺度不敏感性。结果表明，在适当的参数和并行计算条件下，带显式求解器的PHL模型具有很强的鲁棒性和计算效率。此外，隐式相场法所需的细网格尺寸在显式PHL模型中得到了极大的释放，更粗的网格尺寸可以获得更精确的结果。通过试验对模型进行了验证，包括尺寸效应和混凝土试件的混合模态弯曲。在不需要任何跟踪算法的情况下，可以自动捕获裂纹的产生、扩展和合并过程。此外，值得注意的是，该模型可以很容易地推广到耦合的力学和运输问题。

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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来源期刊

Science of Advanced Materials NANOSCIENCE & NANOTECHNOLOGY-MATERIALS SCIENCE, MULTIDISCIPLINARY

自引率

11.10%

发文量

审稿时长

4.4 months