底含水层驱动天然裂缝性油藏表面活性剂提高采收率评价

Samir Alakbarov, A. Behr
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引用次数: 1

摘要

裂缝性强含水层油藏作为一、二次采油的手段,既可以采用注水开发,也可以利用含水层本身的自然能量进行开发。裂缝与基质块之间的高渗透率对比,以及天然裂缝性储层与油湿性的良好混合,使得水驱和主要生产方法大多效率低下,导致含油基质块中大量的石油无法开采。由于没有足够的压力梯度,储层岩石的润湿性决定了驱替流体通过毛细力和重力侵入基质块体的速度。化学提高采收率(cEOR)机制旨在通过影响这些作用力来提高采收率。实验室和现场试验表明,无论是在水湿型还是油湿型裂缝性油藏中,表面活性剂都是一种很有前途的cEOR剂,可以提高基质区块的采收率。对于本文所研究的案例,分析表面活性剂在裂缝性油藏中的应用需要解决以下挑战:通过数学模型解释和再现提高采收率机理——将提高采收率效果适应和整合到全油田模型中——在给定的油藏条件下开发合适的表面活性剂注入技术。本文的目的是介绍在具有强底驱含水层的裂缝性油藏中分析和识别表面活性剂应用的讨论和工作流程。引入捕获数(考虑毛细和键数)作为标度参数,可以评估毛细、粘性和重力对油脱饱和度的综合影响。为了将捕获数集成到商用模拟器中,在此工作范围内开发了一个特殊的接口。在离散矩阵区块的单孔隙度数值模型上评价了表面活性剂的提高采收率效果。为了将作为质量交换项的比采收率机制提升为全场双孔隙度模型,引入了一种特殊的耦合解。拟毛管压力是将单孔隙模型转化为双孔隙模型的中间函数。开发的创新技术提出了一种特殊的注入和开采策略,以获得更有效的面积波及效率,并改变注入水的化学性质,将表面活性剂驱入目标区域,而不会对含水层造成高损失。该技术和所描述的工作流程都被用于对天然裂缝型碳酸盐岩储层表面活性剂提高采收率潜力的高级估计。基于毛管驱替向重力驱替过渡的表面活性剂辅助采油机制对该油藏的最终采收率有增强作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaluation of Surfactant Application to Increase Oil Recovery in Bottom Aquifer-Driven Naturally Fractured Reservoir
As means of primary and secondary recovery, the fractured reservoirs with strong aquifer can be developed either by water injection or by utilizing the natural energy of the aquifer itself. High permeability contrast between fracture and matrix blocks and preferably mixed to oil-wet nature of the naturally fractured reservoirs makes waterflooding and primary methods of production mostly inefficient leaving vast amount of oil unrecovered in the oil-bearing matrix blocks. Due to the absence of a sufficient pressure gradient, wettability of the reservoir rock determines the rate of the displacing fluid invasion into the matrix blocks by capillary and gravity forces. Chemical Enhanced Oil Recovery (cEOR) mechanisms are aimed to intensify oil recovery by affecting these forces. Laboratory and field pilot tests showed the application of surfactant to be a promising cEOR agent for increasing oil recovery from the matrix blocks, both in water-wet and oil-wet fractured reservoirs. For the case studied in this paper, analysis of the surfactant application in the fractured reservoir required the solution of the following challenges: –Interpretation and reproduction of the EOR mechanisms by mathematical modelling–Adaptation and integration of the EOR effects into the full field model–Development of the proper technology for surfactant injection under the given reservoir conditions The aim of the paper is to present the discussions and the workflow for analyzing and identification of the surfactant application in the fractured reservoir with strong bottom driven aquifer. Introduction of the trapping number (accounting the capillary and Bond numbers) as a scaling parameter enabled to evaluate the combined effect of capillary, viscous and gravity forces on oil desaturation. To integrate the trapping number into commercial simulator, a special interface was developed within the scope of this work. The EOR effects of surfactant were evaluated on the single porosity numerical models representing a discretized matrix block. To upscale the specific recovery mechanism as a mass exchange term into full field dual porosity model a special coupling solution was introduced. A pseudo-capillary pressure is suggested as an intermediate function to translate the recovery mechanism from single to dual porosity model. The developed innovative technology proposes a special injection and production strategy for more effective areal sweep efficiency as well as alteration of injection water chemistry to drive the surfactant into target areas without high losses into the aquifer. This technology and the described workflow, both were employed for advanced estimation of surfactant EOR potential in a naturally fractured carbonate reservoir. The surfactant aided recovery mechanism based on transition from capillary to gravity dominated displacement showed enhanced effect on ultimate oil recovery from this reservoir.
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