NUMERICAL SIMULATION OF GAS AND WATER FILTRATION IN POROUS MEDIUM MICROMODELS

IF 0.3 Q4 ENGINEERING, CHEMICAL
A. A. Mirzayanov, V.A. Nitsenko, L.Z. Kazina, Y. Pityuk, A.Yu. Lomukhin
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引用次数: 0

Abstract

To select and justify effective compositions for limiting water inflow into gas wells, an understanding of the behavior of the multiphase system on the scale of individual pores is necessary. In turn, capillary forces depend on the interfacial tension and wettability of the pore surface. As part of this work, computational microfluidics methods were used using the OpenFOAM platform to analyze the effect of rock wettability on the features of two-phase filtration of water and gas in a T-shaped micromodel of a porous medium, which is a crack connected to an element of a porous matrix. A mathematical model was chosen that allows you to describe the movement of fluid in a fracture by the Navier-Stokes equation, and in elements of a porous matrix by the Darcy equation. A grid of a T-shaped micromodel of a porous medium was generated using a GMSH grid generator. The displacement of water by gas from the fracture and porous matrix was simulated. Multivariable analysis of water displacement by gas for hydrophobic and hydrophilic surface was carried out by varying wetting angles. The dependencies of the residual water of the micromodel on the contact angle and flow modes were conducted. It has been found that at low filtration rates, water enters the fracture from the porous medium, which blocks the direct flow of gas through the fracture. In the case of a hydrophilic surface, the water inflow from the porous matrix is greater than in the case of a hydrophobic surface, since blocking the fracture results in gas filtration through the porous medium and displacement of water therefrom. The proposed approach can be used to rank effective bottomhole treatment agents and select optimal filtration modes to limit water inflow into gas wells.
多孔介质微模型中气、水过滤的数值模拟
为了选择和证明有效的成分来限制水流入气井,了解多相体系在单个孔隙尺度上的行为是必要的。反过来,毛细力取决于界面张力和孔隙表面的润湿性。作为这项工作的一部分,在OpenFOAM平台上,使用计算微流体方法分析了岩石润湿性对多孔介质t形微模型中水和气两相过滤特征的影响,多孔介质是一个连接到多孔基质元素的裂缝。选择了一种数学模型,可以用Navier-Stokes方程来描述裂缝中的流体运动,用Darcy方程来描述多孔基质中的元素。利用GMSH网格发生器生成了多孔介质的t形微模型网格。模拟了裂缝和多孔基质中气体对水的驱替作用。在不同的润湿角度下,对疏水和亲水表面的气驱水量进行了多变量分析。研究了微模型残余水与接触角和流动方式的关系。研究发现,在低过滤速率下,水从多孔介质进入裂缝,阻碍了气体通过裂缝的直接流动。在亲水表面情况下,从多孔基质流入的水比疏水表面情况下流入的水大,因为堵塞裂缝会导致气体通过多孔介质过滤并从多孔介质中置换水。该方法可用于对有效的井底处理剂进行排序,并选择最佳过滤模式,以限制气井的水流入。
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来源期刊
Chemical and Petroleum Engineering
Chemical and Petroleum Engineering ENGINEERING, CHEMICAL-
CiteScore
0.60
自引率
33.30%
发文量
129
期刊介绍: Chemical and Petroleum Engineering publishes the latest research on Russian innovations in the field. Articles discuss developments in machinery and equipment, construction and design, processes, materials and corrosion control, and equipment-manufacturing technology. Chemical and Petroleum Engineering is a translation of the Russian journal Khimicheskoe i Neftegazovoe Mashinostroenie. The Russian Volume Year is published in English from April. All articles are peer-reviewed.
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