基于混合耦合理论的可变形双重孔隙介质溶质运移模型

IF 2.2 4区 工程技术 Q3 ENGINEERING, GEOLOGICAL Environmental geotechnics Pub Date : 2023-04-18 DOI:10.1680/jenge.22.00029
K. Wang, Wenjie Tan, Yanxiao Si, Yue Ma, Xiaohui Chen, A. Ding
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引用次数: 0

摘要

岩石、土壤和许多类似多孔材料通常是破碎或结构化的介质,可以表现出双重孔隙行为。由于多重物理耦合效应以及裂隙(或大孔隙)与多孔基质之间的复杂相互作用,对可变形双重孔隙介质中溶质运移的研究仍然具有挑战性。尽管已有几项关于可变形双重孔隙中耦合行为的本构模型的研究,但先前开发的模型在热力学框架中并不系统。本文提出了一种基于非平衡热力学的混合耦合理论方法,建立了考虑双重孔隙介质中流体力学耦合的溶质运移模型(简称ST-HM模型)。本文推导了双重孔隙介质中完全水力-机械耦合行为的本构方程,并考虑了水力和机械场对孔隙和裂缝孔隙度的影响。因此,ST-HM的控制方程能够预测双重孔隙介质中具有完全水力-机械耦合效应的非反应性溶质运移。然后,将该模型与现有模型进行了对比验证,并通过相关实验结果进行了验证。此外,一个数值例子表明,与以前的模型相比,所提出的模型显著提高了孔隙度、流体压力和溶质浓度预测的准确性,而以前的模型忽略了对溶质传输的完全水力-机械耦合效应。
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A Mixture Coupling Theory based model for solute transport in deformable dual-porosity media
Rock, soil and many porous-like materials are often fractured or structured media, which can exhibit dual-porosity behaviour. Studies on solute transport in deformable dual-porosity media remain challenging due to the multi-physics coupled effects and the complex interaction between fracture (or macropore) and porous matrix. Though several studies exist on constitutive modelling of coupled behaviour in deformable dual-porosity, the previously developed models are not systematic in thermodynamical frameworks. This paper proposes a Mixture Coupling Theory approach based on nonequilibrium thermodynamics to develop the solute transport model with consideration of hydro-mechanical coupling in dual-porosity media (referred to as the ST-HM model). This paper derives the constitutive equations of fully hydro-mechanical coupled behaviour in dual-porosity media and considers the pore and fracture porosity evolution influenced by both hydro and mechanical fields. Therefore, the governing equations of ST-HM are capable of predicting non-reactive solute transport with a fully hydro-mechanical coupled effect in dual-porosity media. Then, the model was verified against existing models and validated by relevant experimental results. Further, a numerical example shows that the presented model significantly improves the accuracy of the prediction of porosity, fluid pressure, and solute concentration compared with previous models, which ignore the fully hydro-mechanical coupled effects on solute transport.
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来源期刊
Environmental geotechnics
Environmental geotechnics Environmental Science-Water Science and Technology
CiteScore
6.20
自引率
18.20%
发文量
53
期刊介绍: In 21st century living, engineers and researchers need to deal with growing problems related to climate change, oil and water storage, handling, storage and disposal of toxic and hazardous wastes, remediation of contaminated sites, sustainable development and energy derived from the ground. Environmental Geotechnics aims to disseminate knowledge and provides a fresh perspective regarding the basic concepts, theory, techniques and field applicability of innovative testing and analysis methodologies and engineering practices in geoenvironmental engineering. The journal''s Editor in Chief is a Member of the Committee on Publication Ethics. All relevant papers are carefully considered, vetted by a distinguished team of international experts and rapidly published. Full research papers, short communications and comprehensive review articles are published under the following broad subject categories: geochemistry and geohydrology, soil and rock physics, biological processes in soil, soil-atmosphere interaction, electrical, electromagnetic and thermal characteristics of porous media, waste management, utilization of wastes, multiphase science, landslide wasting, soil and water conservation, sensor development and applications, the impact of climatic changes on geoenvironmental, geothermal/ground-source energy, carbon sequestration, oil and gas extraction techniques, uncertainty, reliability and risk, monitoring and forensic geotechnics.
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