Complexity Model for Predicting Oil Displacement by Imbibition after Fracturing in Tight-Oil Reservoirs

Aijun Chen, Yiqing Zhou, Rulin Song, Yang Song, Hanlie Cheng, David Cadasse
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Abstract

With the increasing difficulty of conventional oil and gas exploration and development, oil and gas resources have developed from conventional to unconventional, and the exploration and development of tight-oil reservoirs are highly valued. In view of the complexity of the influencing factors of oil-water spontaneous seepage after fracturing and the instability of reservoir recovery, this paper takes the tight sandstone reservoir of Yanchang Formation in the southern Ordos Basin as the research object. Based on the micro-nano pore throat characteristics of tight sandstone, the seepage experiment is carried out, and the theoretical model of seepage suction is constructed. The mechanism and influencing factors of suction and oil displacement after fracturing in tight reservoirs are analyzed. Based on the analysis of fluid buoyancy and gravity, a mathematical model of the oil-water spontaneous flow after fracturing was established, and its influencing factors were analyzed. The experimental results show that the pore throats of tight sandstone are mainly in micron- and submicron scale, and the reservoir permeability is related to the pore throat structure, oil-water interfacial tension, and wettability. After fracturing, with the increase of the fracture length, the seepage velocity gradually decreases. With the increase of fracture opening, the influence of buoyancy and gravity on seepage velocity increases. With the increase of the fracture number, seepage velocity also increases. The fracture helps to reduce the adsorption of oil droplets on the core surface and improve the efficiency of spontaneous imbibition and oil displacement of the core. The research results provide theoretical data support for enhancing oil recovery and have important application guiding significance for the operational reliability of manufacturing systems with complex topology and the complexity and operability of production operations in manufacturing systems.
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致密油压裂后吸胀驱油预测的复杂性模型
随着常规油气勘探开发难度的增大,油气资源由常规向非常规发展,致密油储层的勘探开发受到高度重视。鉴于压裂后油水自发渗流影响因素的复杂性和储层采收率的不稳定性,本文以鄂尔多斯盆地南部延长组致密砂岩储层为研究对象。基于致密砂岩的微纳孔喉特征,开展了渗流实验,建立了渗流吸力理论模型。分析了致密储层压裂后吸油驱油机理及影响因素。在分析流体浮力和重力的基础上,建立了压裂后油水自发流动的数学模型,并对影响油水自发流动的因素进行了分析。实验结果表明,致密砂岩的孔喉以微米级和亚微米级为主,储层渗透率与孔喉结构、油水界面张力和润湿性有关。压裂后,随着裂缝长度的增加,渗流速度逐渐减小。随着裂缝开度的增大,浮力和重力对渗流速度的影响增大。随着裂缝数的增加,渗流速度也随之增大。裂缝有助于减少油滴在岩心表面的吸附,提高岩心的自吸和驱油效率。研究结果为提高采收率提供了理论数据支持,对复杂拓扑制造系统的运行可靠性以及制造系统生产操作的复杂性和可操作性具有重要的应用指导意义。
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