Numerical simulation of two-dimensional crack propagation using stretching finite element method by Abaqus

Tribology and Materials Pub Date : 1900-01-01 DOI:10.46793/tribomat.2022.018

M. Bentahar, H. Benzaama

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引用次数: 2

Abstract

Fatigue is a phenomenon that appears in items subjected to cyclic loads. Thus, rupture and partial oxidation are initiated from the beginning of the process. For this, the study of such a problem of material in fracture mechanics is based on the numerical analysis of the characteristics of a crack. In this article, we propose a modelling of crack propagation by a new method of stretching the mesh by 2D finite element in mixed mode, based on the creation of the elements through a program in the computer language Fortran. The parametric mesh with 4 nodes (CPE4) was created to make the simulation and to characterise the stress intensity factors, by the Abaqus computer code. For this, the validation of stretching finite element method (SFEM) results is done by other methods: extended finite element method (XFEM) and analytical method to simulate the crack propagation. The stress intensity factor (SIF) is an essential parameter of this study. Two possibilities for determining the SIF have been retained: one by the numerical method of our choice and the other by the analytical method. Parameters to characterise the stress state at the crack front KI and KII were evaluated in two stages one by the crack length and the other by the a/c ratio.

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基于Abaqus的拉伸有限元法二维裂纹扩展数值模拟

疲劳是在循环荷载作用下出现的一种现象。因此，破裂和部分氧化从工艺一开始就开始了。因此，断裂力学中对材料这一问题的研究是建立在对裂纹特征进行数值分析的基础上的。在本文中，我们提出了一种基于二维有限元在混合模式下拉伸网格的新方法，该方法基于计算机语言Fortran的程序创建。利用Abaqus计算机代码，建立了4节点参数网格(CPE4)进行仿真并表征应力强度因子。为此，采用扩展有限元法(XFEM)和解析法模拟裂纹扩展来验证拉伸有限元法(SFEM)的结果。应力强度因子(SIF)是本研究的重要参数。我们保留了确定SIF的两种可能性:一种是我们选择的数值方法，另一种是分析方法。表征裂纹前缘应力状态的参数KI和KII分两个阶段进行评估，一个是通过裂纹长度，另一个是通过a/c比。

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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Tribology and Materials

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