孔隙尺度结晶和沉淀直接数值模拟的半拉格朗日方法

Sarah Perez, Jean-Matthieu Etancelin, Philippe Poncet
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引用次数: 0

摘要

本文介绍了一种新的高效粒子方法,用于对通过 X 射线断层扫描提取的真实岩石几何结构的孔隙尺度上的结晶和沉淀进行数值模拟。该方法基于多孔介质表层速度模型和使用过渡态理论的拉格朗日化学描述之间的耦合,涉及底层网格。该模型成功计算溶解过程的能力已在过去得到证实,目前正通过吸附建模将其推广到沉淀和结晶。提供了矿物二氧化碳捕集的数值模拟,显示了堵塞/非堵塞机制的证据,主要成果之一是引入了表征该特征所需的新的非维数。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A semi-Lagrangian method for the direct numerical simulation of crystallization and precipitation at the pore scale
This article introduces a new efficient particle method for the numerical simulation of crystallization and precipitation at the pore scale of real rock geometries extracted by X-Ray tomography. It is based on the coupling between superficial velocity models of porous media, Lagrangian description of chemistry using Transition-State-Theory, involving underlying grids. Its ability to successfully compute dissolution process has been established in the past and is presently generalized to precipitation and crystallization by means of adsorption modeling. Numerical simulations of mineral CO2 trapping are provided, showing evidence of clogging/non-clogging regimes, and one of the main results is the introduction of a new non-dimensional number needed for this characterization.
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