Adaptive mesh refinement for the phase field method: A FEniCS implementation

IF 2.2 Q2 ENGINEERING, MULTIDISCIPLINARY
F. Freddi, L. Mingazzi
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引用次数: 3

Abstract

This paper reports insightful implementation details of the global adaptive refinement procedure for the phase-field method recently published in Freddi and Mingazzi (2022). Phase field approaches reproduce cracks within solids in a smeared manner. The small transition zone between broken and unbroken material, whose width is controlled by an internal scale length parameter, permits to precisely replicate complex sharp crack topologies only if an extremely fine mesh is adopted. Starting from a coarse mesh, the proposed refinement process utilizes an energetic criterion to selectively refine the elements on which cracks may propagate. In fully broken areas, where the phase field is no longer evolving, a specific refinement is adopted to capture the high displacement gradient. The implementation is performed within the open-source finite element software FEniCS (ver. 19.1.0) which provides a framework for automated solutions of partial differential equations. The fundamental aspects of the code are described starting from the functional definition to the various steps of the refinement technique. A representative example is illustrated to supply further information on the code functionality. The code can be downloaded from https://github.com/LorenzoMingazzi/AGu-AGal and be used to easily apply the proposed refinement strategy to different problems or as a starting point for more sophisticated formulations.

相位场法的自适应网格细化:一种FEniCS实现
本文报道了最近发表在Freddi和Mingazzi(2022)上的相位场方法的全局自适应精化过程的深入实现细节。相场方法以涂抹的方式再现固体中的裂纹。破碎和未破碎材料之间的小过渡区,其宽度由内部尺度长度参数控制,只有在采用极细网格的情况下,才能精确复制复杂的尖锐裂纹拓扑结构。从粗网格开始,所提出的细化过程利用能量标准来选择性地细化裂纹可能在其上传播的元素。在相位场不再演化的完全破碎区域,采用特定的细化来捕捉高位移梯度。该实现是在开源有限元软件FEniCS(19.1.0版)中执行的,该软件为偏微分方程的自动求解提供了一个框架。从函数定义到细化技术的各个步骤,描述了代码的基本方面。图示了一个代表性示例,以提供关于代码功能的进一步信息。代码可以从下载https://github.com/LorenzoMingazzi/AGu-AGal并且可以用于将所提出的细化策略容易地应用于不同的问题,或者作为更复杂的公式的起点。
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
Applications in engineering science
Applications in engineering science Mechanical Engineering
CiteScore
3.60
自引率
0.00%
发文量
0
审稿时长
68 days
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