An Integrated WAG Characterization Study for an Offshore Oilfield

R. A. M. Vieira, M. A. Cardoso, J. Pizarro
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Abstract

Water-Alternating-Gas (WAG) injection is an enhanced recovery method that is being applied in some brazilian offshore oilfields as an alternative to combine effective pressure maintenance policies, flexible produced gas management strategies and increased recoveries. In this technology, gas plays the role of reducing residual oil saturation while water controls, by multiphase flow-in-porous-medium effects, gas adverse mobility. In addition to the extra engineering tasks needed to design development plans and production facilities, an intense characterization programme should be put in practice in order to reduce risks, increase predictability and optimize WAG floods. Much more complex laboratory tests than the ones usually performed for continuous water/gas floods should be done, particularly to tackle multiphase flow in porous medium phenomena. The proper characterization, modeling and simulation of these effects are vital for a representative WAG design and evaluation. This paper presents the results of a pragmatic and integrated laboratory characterization, modeling and simulation study for an offshore oilfield that was focused on relative permeability hysteresis effects. Firstly, it summarizes the best relative permeability hysteresis model (Larsen & Skauge) available in most commercial reservoir simulators. Then, it describes a special laboratory WAG multiphase flow-in-porous-media characterization program, designed and executed to obtain the parameters of this hysteresis model. Experiments were done at reservoir conditions and with rock and fluids from an actual offshore field. Following, results of these tests were evaluated in light of Larsen & Skauge model, in order to confirm its validity. Finally, WAG simulations of a sector of the target field were performed to access the impacts of including or neglecting relative permeability hysteresis phenomena. Conclusions of this work contribute to increase predictability and reduce uncertainties related to field-scale implementation of WAG technology. Knowledge acquired from this study promoted a better estimation of oil recovery, gas production and overriding. It also supports the design of subsea and topside equipment, which is critical in the offshore scenario.
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海上油田WAG综合表征研究
水-气交替注入(WAG)是一种提高采收率的方法,目前已在巴西的一些海上油田得到应用,作为一种结合了有效的压力维持政策、灵活的产出气管理策略和提高采收率的替代方法。在该技术中,气起到降低剩余油饱和度的作用,而水则通过多孔介质中多相流的作用控制气的不良流动性。除了设计开发计划和生产设施所需的额外工程任务外,还应实施密集的表征计划,以降低风险,提高可预测性并优化WAG洪水。应进行比通常用于连续水/气驱的复杂得多的实验室测试,特别是处理多孔介质中的多相流动现象。这些效应的适当表征、建模和仿真对于具有代表性的WAG设计和评估至关重要。本文介绍了针对某海上油田相对渗透率滞后效应进行的实用综合实验室表征、建模和仿真研究的结果。首先,总结了大多数商业油藏模拟软件中可用的最佳相对渗透率滞后模型(Larsen & Skauge)。然后,描述了一个专门的实验室WAG多孔介质多相流表征程序,设计并执行该程序以获得该滞后模型的参数。实验是在储层条件下进行的,并使用了实际海上油田的岩石和流体。接下来,根据Larsen & Skauge模型对这些测试的结果进行评估,以确认其有效性。最后,对目标场的一个区域进行WAG模拟,以获得包括或忽略相对渗透率滞后现象的影响。这项工作的结论有助于提高WAG技术的可预测性和减少与现场规模实施相关的不确定性。从这项研究中获得的知识有助于更好地估计石油采收率、天然气产量和覆盖。它还支持海底和上层设备的设计,这在海上场景中至关重要。
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