Finite-strain gradient-extended damage-plastic modeling of rock: Understanding catastrophe from material failure and structural instability

IF 5.3 1区工程技术 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Computers and Geotechnics Pub Date : 2024-11-08 DOI:10.1016/j.compgeo.2024.106891

Xiaofeng Cheng , Xianhui Feng , Chun’an Tang

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Abstract

Rock, a natural geological material, exhibits diverse collapse modes that make predicting catastrophic behavior challenging. Material failure and structural instability each provide independent mechanical explanations for rock catastrophes. However, isolated perspectives often obscure the distinctions and connections between these two critical mechanisms. Here, we propose a finite-strain gradient-extended damage-plastic scheme within a thermodynamically consistent framework to encapsulate the indispensable dual effects of failure and instability. The crack propagation and frictional dissipation of crack clusters in rock materials inspire coupled damage-plastic theory, whereas the large displacement, large rotation and large strain of rock structures motivate the application of finite strain theory. The proposed scheme incorporates nonlocal gradient-enhanced terms to mitigate mesh dependence and is immune to spurious energy dissipation under cyclic loading. Constitutive treatment at finite strain retains the easily achievable features of the small deformation case. The model is validated through laboratory- and engineering-scale simulations, offering insights into the mechanisms of rock catastrophes. Our findings highlight the dual role of material failure and structural instability as interconnected drivers of rock catastrophes, offering a more holistic understanding for effective prediction and mitigation strategies.

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岩石的有限应变梯度扩展损伤-塑性模型：了解材料失效和结构失稳带来的灾难

岩石作为一种天然地质材料，表现出多种多样的崩塌模式，这使得预测灾难行为具有挑战性。材料失效和结构不稳定性各自为岩石灾难提供了独立的力学解释。然而，孤立的视角往往会模糊这两种关键机制之间的区别和联系。在此，我们在热力学一致的框架内提出了一种有限应变梯度扩展损伤-塑性方案，以囊括失效和失稳这两种不可或缺的双重效应。岩石材料中裂纹群的裂纹扩展和摩擦耗散激发了耦合损伤-塑性理论，而岩石结构的大位移、大旋转和大应变则激发了有限应变理论的应用。所提出的方案包含非局部梯度增强项，可减轻网格依赖性，并可避免循环加载下的虚假能量耗散。有限应变下的构造处理保留了小变形情况下易于实现的特征。该模型通过实验室和工程规模的模拟进行了验证，为岩石灾难的机理提供了见解。我们的研究结果强调了材料失效和结构不稳定性的双重作用，它们是岩石灾难的相互关联的驱动因素，为有效预测和缓解策略提供了更全面的理解。

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

Computers and Geotechnics 地学-地球科学综合

CiteScore

9.10

自引率

15.10%

发文量

438

审稿时长

45 days

期刊介绍： The use of computers is firmly established in geotechnical engineering and continues to grow rapidly in both engineering practice and academe. The development of advanced numerical techniques and constitutive modeling, in conjunction with rapid developments in computer hardware, enables problems to be tackled that were unthinkable even a few years ago. Computers and Geotechnics provides an up-to-date reference for engineers and researchers engaged in computer aided analysis and research in geotechnical engineering. The journal is intended for an expeditious dissemination of advanced computer applications across a broad range of geotechnical topics. Contributions on advances in numerical algorithms, computer implementation of new constitutive models and probabilistic methods are especially encouraged.