Fluid Transport in Porous Rocks. II. Hydrodynamic Model of Flow and Intervoxel Coupling

Journal of Magnetic Resonance, Series A Pub Date : 1996-10-01 DOI:10.1006/jmra.1996.0190

P. Mansfield , B. Issa

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引用次数: 10

Abstract

In a preceding paper [P. Mansfield and B. Issa,J. Magn. Reson. A122, 137–148 (1996)], a stochastic model of fluid flow in porous rocks based upon the experimental observation of water flow through a Bentheimer sandstone core was proposed. The flow maps were measured by NMR-imaging techniques. The stochastic theory led to a Gaussian velocity distribution with a mean value in accord with Darcy's law. Also predicted was a linear relationship between flow variance and mean fluid flow through rock, the Mansfield–Issa equation, originally proposed as an empirical relationship. In the present work a flow coupling mechanism between voxels is proposed. Examination of the flow coupling between isolated voxel pairs leads to a complementary explanation of the Gaussian velocity distribution, and also gives further details of the Mansfield–Issa equation. These details lead to a new expression for the connectivity, 〈C〉, between voxels with an experimental value of 〈C〉 = 5.64 × 10⁻⁹for Bentheimer sandstone.

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多孔岩石中的流体输运。2流体力学模型与体素间耦合

在先前的一篇论文中[P.]曼斯菲尔德和B.伊萨，J。粉剂。的原因。A122, 137 - 148(1996)),流体在多孔岩石的随机模型基于水流通过Bentheimer砂岩的实验观测提出了核心。血流图通过核磁共振成像技术测量。随机理论使速度呈高斯分布，其平均值符合达西定律。还预测了流量方差和平均流体通过岩石的流量之间的线性关系，即最初作为经验关系提出的曼斯菲尔德-伊萨方程。本文提出了一种体素间的流耦合机制。对孤立体素对之间的流动耦合的检查导致高斯速度分布的补充解释，并且还提供了曼斯菲尔德-伊萨方程的进一步细节。这些细节导致了Bentheimer砂岩体素之间连通性的新表达式< C >，实验值< C > = 5.64 × 10−9。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Magnetic Resonance, Series A

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