A chain stretch-based gradient-enhanced model for damage and fracture in elastomers

IF 6.9 1区工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY

Computer Methods in Applied Mechanics and Engineering Pub Date : 2025-06-12 DOI:10.1016/j.cma.2025.118103

S. Mohammad Mousavi , Jason Mulderrig , Brandon Talamini , Nikolaos Bouklas

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引用次数: 0

Abstract

Similar to quasi-brittle materials, it has been recently shown that elastomers can exhibit a macroscopically diffuse damage zone that accompanies the fracture process. In this study, we introduce a stretch-based gradient-enhanced damage (GED) model that allows the fracture to localize and also captures the development of a physically diffuse damage zone. This capability contrasts with the paradigm of the phase field method for fracture, where a sharp crack is numerically approximated in a diffuse manner. Capturing fracture localization and diffuse damage in our approach is achieved by considering nonlocal effects that encompass network topology, heterogeneity, and imperfections. These considerations motivate the use of a statistical damage function dependent upon the nonlocal deformation state. From this model, fracture toughness is realized as an output. While GED models have been classically utilized for damage modeling of structural engineering materials (e.g., concrete), they face challenges when trying to capture the cascade from damage to fracture, often leading to damage zone broadening (de Borst and Verhoosel, 2016). This deficiency contributed to the popularity of the phase-field method over the GED model for elastomers and other quasi-brittle materials. Other groups have proceeded with damage-based GED formulations that prove identical to the phase-field method (Lorentz et al., 2012), but these inherit the aforementioned limitations. To address this issue in a thermodynamically consistent framework, we implement two modeling features (a nonlocal driving force bound and a simple relaxation function) specifically designed to capture the evolution of a physically meaningful damage field and the simultaneous localization of fracture, thereby overcoming a longstanding obstacle in the development of these nonlocal strain- or stretch-based approaches. We discuss several numerical examples to understand the features of the approach at the limit of incompressibility, and compare them to the phase-field method as a benchmark for the macroscopic response and fracture energy predictions.

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基于链拉伸梯度增强的弹性体损伤与断裂模型

与准脆性材料类似，最近的研究表明，弹性体在断裂过程中会出现宏观弥漫性损伤区。在这项研究中，我们引入了一种基于拉伸的梯度增强损伤（GED）模型，该模型允许裂缝局部化，并捕获物理扩散损伤区的发展。这种能力与断裂的相场方法的范例形成对比，在相场方法中，尖锐裂纹以扩散的方式在数值上近似。在我们的方法中，通过考虑包括网络拓扑、异质性和缺陷在内的非局部效应，可以捕获裂缝局部化和弥漫性损伤。这些考虑促使使用依赖于非局部变形状态的统计损伤函数。从这个模型中，断裂韧性作为输出来实现。虽然GED模型通常用于结构工程材料（如混凝土）的损伤建模，但在试图捕捉从损伤到断裂的级联过程时，它们面临着挑战，通常会导致损伤区域扩大（de Borst和Verhoosel， 2016）。这一缺陷使得相场法在弹性体和其他准脆性材料中比GED模型更受欢迎。其他研究小组也采用了与相场法相同的基于损伤的GED公式（Lorentz et al., 2012），但这些公式继承了上述局限性。为了在热力学一致的框架中解决这一问题，我们实现了两个建模特征（非局部驱动力约束和简单松弛函数），专门用于捕捉物理上有意义的损伤场的演变和断裂的同时局部化，从而克服了这些基于非局部应变或拉伸的方法发展中的长期障碍。我们讨论了几个数值例子，以了解该方法在不可压缩极限下的特征，并将其与相场法作为宏观响应和裂缝能预测的基准进行了比较。

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来源期刊

Computer Methods in Applied Mechanics and Engineering 工程技术-工程：综合

CiteScore

12.70

自引率

15.30%

发文量

719

审稿时长

44 days

期刊介绍： Computer Methods in Applied Mechanics and Engineering stands as a cornerstone in the realm of computational science and engineering. With a history spanning over five decades, the journal has been a key platform for disseminating papers on advanced mathematical modeling and numerical solutions. Interdisciplinary in nature, these contributions encompass mechanics, mathematics, computer science, and various scientific disciplines. The journal welcomes a broad range of computational methods addressing the simulation, analysis, and design of complex physical problems, making it a vital resource for researchers in the field.