Pore-Scale Displacement Experiments Using Microfluidic Device to Investigate Fingering Mechanisms Using Both CO2 and N2: Implications for EOR and CO2 Geo-Storage

IF 1.3 4区 工程技术 Q3 CHEMISTRY, ORGANIC Petroleum Chemistry Pub Date : 2024-09-24 DOI:10.1134/S0965544124050104
Duraid Al-Bayati, Matthew Myers, Ali Saeedi
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Abstract

For water-wet porous media, the literature revealed a poor displacement efficiency for CO2 relative to N2. The overall average residual water saturation displaced by CO2 is ~50.0% compared to ~20.0% displaced by N2. Furthermore, based on the “Land” trapping model (Land, 1968), the non-wetting phase trapped during a subsequent imbibition displacement would also be reduced due to the low end-point saturation of the non-wetting phase achieved during the drainage flood. In this study, we hypothesize that for a drainage flood with a very low viscosity ratio (μdisplacingdisplaced <<1) and low flow rate (ca < 10–6) (i.e., conditions that are typical for the displacement of water by CO2, N2 in a strongly water-wet porous media) the end-point residual water saturation is predominantly controlled by the interfacial tension of the fluid-gas system. To test our hypothesis, we have performed six pore-scale displacement experiments on a micromodel using both CO2 and N2 to understand the influence of different fingering mechanisms (i.e., capillary vs. viscous) on flooding performance. It is observed that, for capillary-dominated floods, IFT values control the displacement efficiency. Therefore, we could conclude for capillary experiments that the poor displacement of the non-wetting (i.e., CO2) is due to a snap-off model which is closely related to the IFT value.

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利用微流体装置进行孔隙尺度位移实验,研究二氧化碳和 N2 的成膜机制:对 EOR 和二氧化碳地质封存的影响
对于水湿多孔介质,文献显示二氧化碳的置换效率比氮气低。被二氧化碳置换的残余水饱和度的总体平均值约为 50.0%,而被 N2 置换的残余水饱和度约为 20.0%。此外,根据 "Land "捕集模型(Land,1968 年),由于排水淹没期间非湿相的终点饱和度较低,在随后的浸泡置换过程中捕集的非湿相也会减少。在本研究中,我们假设在粘度比(μdisplacing/μdisplaced <<1)很低、流速(ca <10-6)很低(即在强水湿多孔介质中二氧化碳、氮气置换水的典型条件)的排水洪流中,终点残余水饱和度主要受流体-气体系统的界面张力控制。为了验证我们的假设,我们使用二氧化碳和 N2 在一个微模型上进行了六次孔隙尺度的置换实验,以了解不同的指涉机制(即毛细机制和粘性机制)对淹没性能的影响。实验结果表明,对于以毛细管为主的淹没,IFT 值控制着置换效率。因此,我们可以得出结论,在毛细管实验中,非润湿(即 CO2)置换效果差是由于与 IFT 值密切相关的快断模型造成的。
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来源期刊
Petroleum Chemistry
Petroleum Chemistry 工程技术-工程:化工
CiteScore
2.50
自引率
21.40%
发文量
102
审稿时长
6-12 weeks
期刊介绍: Petroleum Chemistry (Neftekhimiya), founded in 1961, offers original papers on and reviews of theoretical and experimental studies concerned with current problems of petroleum chemistry and processing such as chemical composition of crude oils and natural gas liquids; petroleum refining (cracking, hydrocracking, and catalytic reforming); catalysts for petrochemical processes (hydrogenation, isomerization, oxidation, hydroformylation, etc.); activation and catalytic transformation of hydrocarbons and other components of petroleum, natural gas, and other complex organic mixtures; new petrochemicals including lubricants and additives; environmental problems; and information on scientific meetings relevant to these areas. Petroleum Chemistry publishes articles on these topics from members of the scientific community of the former Soviet Union.
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