Effect of Convective Mixing Process on Storage of CO2 in Saline Aquifers with Layered Permeability

A. Taheri, Ntnu Trondheim Norway Petroleum, O. Torsæter, E. Lindeberg, N. Hadia, D. Wessel-Berg
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引用次数: 5

Abstract

Convective mixing of free-phase CO2 and brine in saline aquifers is an established technique to accelerate the CO2 dissolution process. Correct estimation of the convection onset time and rate of CO2 dissolution into brine are two crucial parameters regarding safety issues, as the timescale for dissolution corresponds to the same time over which the free-phase CO2 has a chance to leak out from the storage site. In real practice, underground formations are heterogeneous with a layered structure, but the convective mixing in heterogeneous porous media has received less attention than the homogeneous one. This study aims to develop a basic understanding of the role of layered permeability media (layered structure with variation in permeability vertically) on the behavior of convective mixing via well-controlled laboratory experiments. The effects of layering and layer properties on the rate of dissolution of CO2 in water and geometries of the formed convection fingers are studied using a precise experimental set-up with layered-permeability Hele-Shaw cell geometry. Qualitative (snapshots of convection fingers) and quantitative data (amount of the dissolved CO2 into water) are collected simultaneously for a better understanding of the process. The behavior of convection fingers (after the onset of convection) and the effects of model properties on this mixing process are also discussed.
对流混合过程对层状渗盐含水层CO2储存的影响
在含盐含水层中对流混合自由相CO2和盐水是一种加速CO2溶解过程的成熟技术。正确估计对流开始时间和CO2溶解到盐水中的速率是涉及安全问题的两个关键参数,因为溶解的时间尺度对应于自由相CO2有机会从储存地点泄漏的时间。在实际应用中,地下地层是非均质层状结构,但非均质多孔介质中的对流混合受到的关注较少。本研究旨在通过控制良好的实验室实验,对层状渗透介质(渗透率垂直变化的层状结构)对对流混合行为的作用有一个基本的认识。利用层状渗透Hele-Shaw槽几何结构的精密实验装置,研究了层状和层状性质对CO2在水中溶解速率和对流指形状的影响。定性(对流指的快照)和定量数据(溶解在水中的二氧化碳量)同时收集,以便更好地了解这一过程。本文还讨论了对流手指(在对流开始后)的行为以及模型性质对混合过程的影响。
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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