多孔介质在原位应力和孔隙压力下的孔隙结构和渗透行为：数字岩心上的离散元法模拟

IF 2.5 4区工程技术 Q2 ENGINEERING, MECHANICAL

Journal of Porous Media Pub Date : 2024-02-01 DOI:10.1615/jpormedia.2024051280

Jun Yao, Chunqi Wang, Xiaoyu Wang, Zhaoqin Huang, Fugui Liu, Quan Xu, Yongfei Yang

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引用次数: 0

摘要

在应力敏感型油气藏中，地层岩石在原位应力和孔隙压力作用下发生变形，从而影响岩石的孔隙度和渗透率。孔隙变形是其基本机制。然而，在孔隙尺度上对岩石孔隙度和渗透率进行数值模拟的文献并不多见。本文提出了一种基于离散元法的孔隙尺度数值模拟框架。采用数字岩心法对岩心的孔隙几何形态和渗透率演化进行了定量分析。首先，采用 CFM-DEM（耦合流体离散元法）模拟样品在不同应力和孔隙压力下的变形。然后，使用 Avizo 重建数字岩心。最后，分析孔隙几何拓扑结构，计算渗透率变化。结果表明，应力会降低孔隙度，改变孔隙形状，导致孔隙连通性和渗透性变差，而孔隙压力会削弱这种趋势。

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Pore structure and permeability behavior of porous media under in-situ stress and pore pressure: Discrete element method simulation on digital core

In stress-sensitive oil and gas reservoirs, formation rocks’ deformation occurs under in-situ stress and pore pressure, affecting the rock's porosity and permeability. Pore deformation is the fundamental mechanism. However, the literature on the numerical simulation of rock porosity and permeability at the pore scale is rare. In this paper, a numerical simulation framwork of pore scale is proposed based on the discrete element method. The pore geometry and permeability evolution of the core are quantitatively analyzed by digital core method. Firstly, the CFM-DEM (Coupled fluid discrete element method) is used to simulate the samples’ deformation under different stress and pore pressures. Then, reconstruct the digital core using Avizo. Finally, the pore geometric topological structure are analyzed, and the permeability changes are calculated. The results show that stress can reduce porosity, modify pore shape, and lead to poor porosity connectivity and permeability, while pore pressure can weaken such trends.

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来源期刊

Journal of Porous Media 工程技术-工程：机械

CiteScore

3.50

自引率

8.70%

发文量

审稿时长

12.5 months

期刊介绍： The Journal of Porous Media publishes original full-length research articles (and technical notes) in a wide variety of areas related to porous media studies, such as mathematical modeling, numerical and experimental techniques, industrial and environmental heat and mass transfer, conduction, convection, radiation, particle transport and capillary effects, reactive flows, deformable porous media, biomedical applications, and mechanics of the porous substrate. Emphasis will be given to manuscripts that present novel findings pertinent to these areas. The journal will also consider publication of state-of-the-art reviews. Manuscripts applying known methods to previously solved problems or providing results in the absence of scientific motivation or application will not be accepted. Submitted articles should contribute to the understanding of specific scientific problems or to solution techniques that are useful in applications. Papers that link theory with computational practice to provide insight into the processes are welcome.