Polymer Injection to Unlock Bypassed Oil in a Giant Carbonate Reservoir: Bridging the Gap Between Laboratory and Large Scale Polymer Project

C. Fabbri, H. A. Al Saadi, Ke-hui Wang, F. Maire, C. Romero, P. Cordelier, C. Prinet, S. Jouenne, O. Garnier, Siqing Xu, J. Leon, M. Baslaib, S. Masalmeh
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引用次数: 3

Abstract

Polymer flooding has long been proposed to improve sweep efficiency in heterogeneous reservoirs where polymer enhances cross flow between layers and forces water into the low permeability layers, leading to more homogeneous saturation profile. Although this approach could unlock large volumes of by-passed oil in layered carbonate reservoirs, compatibility of polymer solutions with high salinity - high temperature carbonate reservoirs has been hindering polymer injection projects in such harsh conditions. The aim of this paper is to present the laboratory work, polymer injection field test results and pilot design aimed to unlock target tertiary oil recovery in a highly heterogeneous mixed to oil-wet giant carbonate reservoir. This paper focuses on a highly layered limestone reservoir with various levels of cyclicity in properties. This reservoir may be divided in two main bodies, i.e., an Upper zone and a Lower zone with permeability contrast of up to two orders of magnitude. The main part of the reservoir is currently under peripheral and mid-flank water injection. Field observations show that injected water tends to channel quickly through the Upper zone along the high permeability layers and bypass the oil in the Lower zone. Past studies have indicated that this water override phenomenon is caused by a combination of high permeability contrast and capillary forces which counteract gravity forces. In this setting, adequate polymer injection strategy to enhance cross-flow between these zones is investigated, building on laboratory and polymer injection test field results. A key prerequisite for defining such EOR development scenario is to have representative static and dynamic models that captures the geological heterogeneity of this kind of reservoirs. This is achieved by an improved and integrated reservoir characterization, modelling and water injection history matching procedure. The history matched model was used to investigate different polymer injection schemes and resulted in an optimum pilot design. The injection scheme is defined based on dynamic simulations to maximize value, building on results from single-well polymer injection test, laboratory work and on previous published work, which have demonstrated the potential of polymer flooding for this reservoir. Our study evidences the positive impact of polymer propagation at field scale, improving the water-front stability, which is a function of pressure gradient near producer wells. Sensitivities to the position and number of polymer injectors have been performed to identify the best injection configuration, depending on the existing water injection scheme and the operating constraints. The pilot design proposed builds on laboratory work and field monitoring data gathered during single-well polymer injection field test. Together, these elements represent building blocks to enable tertiary polymer recovery in giant heterogeneous carbonate reservoirs with high temperature - high salinity conditions.
聚合物注入解锁巨型碳酸盐岩储层的旁路油:弥合实验室与大规模聚合物项目之间的差距
聚合物驱长期以来一直被提出用于提高非均质油藏的波及效率,聚合物增强了层间的交叉流动,迫使水进入低渗透层,从而获得更均匀的饱和剖面。尽管这种方法可以在层状碳酸盐岩储层中释放大量的旁通油,但聚合物溶液与高盐度、高温碳酸盐岩储层的相容性一直阻碍着聚合物注入项目在如此恶劣的条件下进行。本文的目的是介绍实验室工作、聚合物注入现场测试结果和试点设计,旨在解锁高度非均质混合-油湿型巨型碳酸盐岩储层的三次采收率目标。本文研究了具有不同旋回性的高层状灰岩储层。该储层可划分为两个主体,即上带和下带,渗透率对比可达两个数量级。目前储层主体部分处于外围和中侧翼注水状态。现场观察表明,注入的水往往沿着高渗透层快速流过上部区域,绕过下部区域的石油。过去的研究表明,这种水覆盖现象是由高渗透率对比和毛细力共同作用造成的,毛细力抵消了重力。在这种情况下,根据实验室和聚合物注入测试现场的结果,研究了适当的聚合物注入策略,以增强这些层之间的交叉流动。定义此类EOR开发方案的一个关键先决条件是拥有具有代表性的静态和动态模型,以捕获此类储层的地质非均质性。这是通过改进的综合油藏描述、建模和注水历史匹配程序来实现的。历史匹配模型用于研究不同的聚合物注入方案,并得出最佳的先导设计。注入方案是根据单井聚合物注入测试、实验室工作和先前发表的研究结果,根据动态模拟来确定的,以实现价值最大化,这些研究结果已经证明了该油藏的聚合物驱潜力。我们的研究证明了聚合物在油田规模上的积极影响,提高了水面稳定性,这是生产井附近压力梯度的函数。根据现有的注水方案和操作限制条件,对聚合物注入器的位置和数量进行敏感性测试,以确定最佳的注入配置。提出的试点设计基于实验室工作和在单井注聚合物现场测试中收集的现场监测数据。总之,这些元素代表了在高温高盐度条件下的大型非均质碳酸盐岩储层中实现三级聚合物采收率的基本单元。
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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