An Efficient Damage-Plasticity DEM Contact Model for Highly Porous Rocks.

IF 5.5 2区工程技术 Q1 ENGINEERING, GEOLOGICAL

Rock Mechanics and Rock Engineering Pub Date : 2025-01-01 Epub Date: 2025-02-19 DOI:10.1007/s00603-025-04411-0

Jinhui Zheng, Matteo Oryem Ciantia

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引用次数: 0

Abstract

A novel discrete element method (DEM) model is proposed to better reproduce the behaviour of porous soft rocks. With the final goal of simulating pile penetration problems efficiency and scalability are two underlining features. The contact model is based on the macro-element theory and employs damage laws to govern the plastic deformations developing at the microscale. To attain (i) high porosity states, (ii) represent irregular shaped grains and (iii) incorporate the physical presence of bond fragments, the model is cast within a far-field interaction framework allowing for non-overlapping particles to transmit forces. After presenting a calibration procedure, the model is used to replicate the behaviour of Maastricht calcarenite. In particular, the mechanical response of this calcarenite is explored within the critical state theory framework. Finally, the efficiency, performance and scalability of the model is tested by simulating physical model experiments of cone-ended penetration tests in Maastricht calcarenite from the literature. To boost efficiency of the 3D numerical simulations, a coupled DEM-FDM (Finite Differential Method) framework is used. The good fit between the experimental and numerical results suggest that the new model can be used to unveil microscopic mechanism controlling the macroscopic response of soft-rock/structure interaction problems.

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高孔隙岩石的有效损伤-塑性DEM接触模型

为了更好地再现多孔软岩的特性，提出了一种新的离散元法（DEM）模型。最终目标是模拟桩突问题，效率和可扩展性是两个突出的特征。接触模型基于宏观单元理论，采用损伤规律来控制微观尺度上的塑性变形。为了达到(i)高孔隙率状态，（ii）表示不规则形状的颗粒，（iii）结合键碎片的物理存在，该模型在远场相互作用框架内铸造，允许非重叠粒子传递力。在提出一个校准程序后，该模型被用来复制马斯特里赫特钙屑岩的行为。特别地，在临界状态理论框架内探讨了这种方解岩的力学响应。最后，通过模拟文献中马斯特里赫特方解岩锥端侵彻试验的物理模型实验，验证了模型的有效性、性能和可扩展性。为了提高三维数值模拟的效率，采用了DEM-FDM （Finite Differential Method）耦合框架。实验结果与数值结果吻合较好，表明该模型可用于揭示控制软岩/结构相互作用问题宏观响应的微观机制。

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来源期刊

Rock Mechanics and Rock Engineering 工程技术-地球科学综合

CiteScore

10.90

自引率

11.30%

发文量

405

审稿时长

4.9 months

期刊介绍： Rock Mechanics and Rock Engineering covers the experimental and theoretical aspects of rock mechanics, including laboratory and field testing, methods of computation and field observation of structural behavior. The journal maintains the strong link between engineering geology and rock engineering, providing a bridge between fundamental developments and practical application. Coverage includes case histories on design and construction of structures in rock such as underground openings, large dam foundations and rock slopes. Fields of interest include rock mechanics in all its varied aspects including laboratory testing, field investigations, computational methods and design principles. The journal also reports on applications in tunneling, rock slopes, large dam foundations, mining, engineering and engineering geology.