Prediction of three-phase relative permeabilities of Berea sandstone using lattice Boltzmann method

Li, Sheng; Jiang, Fei; Wei, Bei; Hou, Jirui; Liu, Haihu

doi:10.1063/5.0050727

Cited by 19 publications

(3 citation statements)

References 69 publications

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“…In this study, we adopt the LBM to calculate the flow field in the complex pore spaces. The LBM is an efficient and accurate method for both single‐phase and multiphase flow simulation (Jiang et al., 2022; Jiang, Matsumura, et al., 2021; Li et al., 2021; Liu et al., 2021; Zhang et al., 2022) directly on the raw images of rocks. The LBM can approximately recover Navier Strokes equations from kinetic theory (Shan et al., 2006).…”

Section: Methodsmentioning

confidence: 99%

Upscaling Permeability Using Multiscale X‐Ray‐CT Images With Digital Rock Modeling and Deep Learning Techniques

Jiang

Guo

Tsuji

et al. 2023

Water Resources Research

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This study presents a workflow to predict the upscaled absolute permeability of the rock core direct from CT images whose resolution is not sufficient to allow direct pore‐scale permeability computation. This workflow exploits the deep learning technique with the data of raw CT images of rocks and their corresponding permeability value obtained by performing flow simulation on high‐resolution CT images. The permeability map of a much larger region in the rock core is predicted by the trained neural network. Finally, the upscaled permeability of the entire rock core is calculated by the Darcy flow solver, and the results showed a good agreement with the experiment data. This proposed deep learning based upscaling method allows estimating the permeability of large‐scale core samples while preserving the effects of fine‐scale pore structure variations due to the local heterogeneity.

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Section: Methodsmentioning

confidence: 99%

Upscaling Permeability Using Multiscale X‐Ray‐CT Images With Digital Rock Modeling and Deep Learning Techniques

Jiang

Guo

Tsuji

et al. 2023

Water Resources Research

Self Cite

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“…LBM can bridge the differences between micro-molecular dynamics and macro-fluid behavior, making it an effective tool for dealing with complex fluid flow problems, especially in complex geometric conditions such as porous media (Zuo, 2015). It was proven to be very accurate and has demonstrated high consistency with experimental data (Boek & Venturoli, 2010;Li et al, 2021) in simulating isothermal and incompressible flow (Kutay et al, 2006;Succi, 2001). In LBM, the fluid domain is divided into a lattice grid, where each lattice point represents a specific location in space.…”

Section: Flow Simulationmentioning

confidence: 99%

Knowledge Extraction via Machine Learning Guides a Topology‐Based Permeability Prediction Model

Zhang,

Ma,

Yang

et al. 2024

Water Resources Research

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The complexity and heterogeneity of pore structure present significant challenges in accurate permeability estimation. Commonly used empirical formulas neglect its microscopic and topological characteristics, thus lacking accuracy and adaptability. While machine learning (ML) and deep learning (DL) models demonstrate promising performance, but encounter challenges of data availability, computational cost, and model interpretability. The present study aims to develop a more robust and accurate permeability prediction model via knowledge extraction from ML model. We first establish an ML model between permeability and the geometry‐topology characteristics of porous media using Extreme Gradient Boosting (XGBoost) algorithm. The data set used to fit ML model is prepared from 458 samples of different types of porous media. Using the SHapley Additive exPlanations (SHAP) value, the influence of each feature on permeability prediction is quantified. It is found that the closeness centrality (topology feature), tortuosity, porosity (macroscopic features) and throat diameter, throat length, pore diameter (pore network features) are vital for permeability prediction. Guided by partial dependence calculation, the unknown function relationship between permeability and the top six important features is established. The novel permeability prediction model incorporating topology feature improves the prediction accuracy and demonstrates strong applicability across diverse data sets. This new model presents an optimal balance between simplicity and performance, rendering it a compelling alternative for permeability prediction in porous media. The research provides a novel referable framework of knowledge extraction via ML to reveal the important features and establish the potential relationship that can be extended and applied in other research fields.

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“…Unlike traditional CFD methods based on direct discretization of the macroscopic conservation equations, the lattice Boltzmann (LB) method is a pseudo-molecular method based on microscopic models and mesoscopic kinetic equations consisting of particle distribution functions, where macroscopic quantities can be obtained from the particle distribution functions through moment integration [32]. Due to its kinetic nature and the ability of dealing with complex geometries, the LB method has become one of the most popular tools for pore-scale simulation of single-phase and multiphase flows through porous media [33][34][35][36]. In contrast to the success in pore-scale simulations, the LB method is rarely applied for macroscopic-scale simulation of two-phase flows through porous media, which limits the development of multiscale method coupling pore-scale and macroscopic-scale simulations in the LB framework.…”

Section: Introductionmentioning

confidence: 99%

A Buckley-Leverett Theory Based Lattice Boltzmann Method for Immiscible Two-Phase Flow with Viscous Coupling in Porous Media

Yang Wang,

Liang Shi,

Yong Liu

et al. 2024

AAMM

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In this paper, a lattice Boltzmann method is developed to simulate the water displacement of oil in porous media at the macroscopic-scale, which is built upon the generalized Darcy's law while incorporating cross terms to consider the viscous coupling between two phases. The Buckley-Leverett equation is applied to describe the saturation front advance, thus allowing the determination of water saturation at shock front by using the Welge's graphic method. We explore the effect of viscous coupling on the displacement by comparing the positions of the shock front under the conditions with different degrees of coupling and without viscous coupling. Results show that the advancing speed of shock front increases with the degree of coupling when the viscosity ratio of oil to water remains at 5. We also find that the effect of viscous coupling on the displacement can be neglected when the tolerance quantifying the degree of coupling equals the reciprocal of viscosity ratio. In addition, the effect of viscous coupling on the displacement is very sensitive to the change of viscosity ratio, which decreases monotonously with the decrease of viscosity ratio under the same coupling degree.

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Prediction of three-phase relative permeabilities of Berea sandstone using lattice Boltzmann method

Cited by 19 publications

References 69 publications

Upscaling Permeability Using Multiscale X‐Ray‐CT Images With Digital Rock Modeling and Deep Learning Techniques

Upscaling Permeability Using Multiscale X‐Ray‐CT Images With Digital Rock Modeling and Deep Learning Techniques

Knowledge Extraction via Machine Learning Guides a Topology‐Based Permeability Prediction Model

A Buckley-Leverett Theory Based Lattice Boltzmann Method for Immiscible Two-Phase Flow with Viscous Coupling in Porous Media

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