How to Make Sensitive Formations Produce Oil: Case Study of the Complex Laboratory Approach to Stimulation Fluid Optimization

O. Matar, Hamed AlGhadhban, Hassan AlDurazi, E.A.E. Ali, Ahmed Aljanahi, Sayed Abdelrady, Hassan Almannai, L. K. Teng, A. Yudin, Z. Al-jalal, Mohamed ElSebaee, Fahad Albaadi
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Abstract

The Bahrain field is one of the oldest developed oil fields in the Middle East, with over a dozen formations in production since the early 1930s. Currently, development of the shallow zones (<2,000 ft) of the Magwa and Ostracod formations is a challenge due to the unique complexity and extreme clay sensitivity. With previous fracturing attempts showing limited success, enhanced laboratory testing was undertaken to make fracturing treatments economic. Formation stabilization improvement is crucial in certain reservoir mineralogies, especially those with exposed shale streaks and high concentrations of clays that exhibit extremely high brine sensitivity. Lack of adequate stabilization of sensitive clays and shales risks the deconsolidation of those minerals into fines that may potentially damage the conductivity of the proppant pack in fracturing operations. Many problems associated with the use of water-based fluids in fracturing operations are caused by incompatibilities between the fracturing fluid and the shale minerals, resulting in a fines migration problem in the relatively low-permeability reservoir and a production decline after the fracturing operation. A scientific approach was applied to the selection of novel shale inhibitors to be used in fracturing applications. First, a laboratory testing program was followed to incorporate a new shale inhibitor into the fracturing fluid system. The fluid recipe was further optimized with a reduction in polymer loading, maximizing breaker concentration and ensuring fast shear recovery, because the stimulation design called for large-size proppant (up to 12/20 mesh) to be used in a low-temperature (124°F) environment. The laboratory results demonstrated that the new shale inhibitor significantly reduces alteration of the permeability of the treated core and improves shale stability. The new inhibitor was deployed in the field, as documented in several case histories. Production results of the treated wells demonstrated several-folds increase in production when compared to previously attempted proppant fracturing treatments. The pilot stimulation campaign proved the value of the laboratory research and brought on line two formations with large potential contribution to Bahrain's overall oil production. Although there is a substantial amount of literature on shale inhibition with water-based drilling fluid, the importance of the shale inhibition and the problems associated with shale reactivity during the fracturing operation remain largely unexplored. This paper presents the complex laboratory approach to stimulation fluid optimization in the Bahrain field. The novel solutions and comprehensive workflow description will benefit a broad variety of projects worldwide targeting water-sensitive or low-temperature formations that represent challenges to fracturing fluid selection.
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如何使敏感地层产油:复杂实验室方法优化增产液的案例研究
巴林油田是中东最早开发的油田之一,自20世纪30年代初以来,已有十多个地层在生产。目前,由于其独特的复杂性和对粘土的极端敏感性,Magwa和Ostracod地层的浅层(< 2000英尺)的开发是一个挑战。由于之前的压裂尝试效果有限,因此进行了更多的实验室测试,以提高压裂作业的经济性。在某些储层矿物学中,地层稳定性的提高是至关重要的,特别是那些具有暴露的页岩条纹和高浓度粘土的储层,它们对盐水的敏感性极高。在压裂作业中,如果敏感性粘土和页岩缺乏足够的稳定性,这些矿物质可能会分解成细小颗粒,从而破坏支撑剂充填层的导流能力。在压裂作业中使用水基流体的许多问题是由于压裂液与页岩矿物之间的不相容造成的,导致相对低渗透油藏的细粒运移问题,导致压裂作业后产量下降。一种科学的方法应用于选择用于压裂应用的新型页岩抑制剂。首先,进行了实验室测试,将一种新的页岩抑制剂加入压裂液体系中。由于增产设计要求在低温(124°F)环境下使用大尺寸支撑剂(高达12/20目),因此进一步优化了流体配方,减少了聚合物载荷,最大限度地提高了破碎剂浓度,并确保了快速剪切恢复。实验结果表明,新型页岩抑制剂显著降低了处理岩心渗透率的变化,提高了页岩的稳定性。正如几个案例记录的那样,新的抑制剂已在现场部署。经过处理的井的生产结果表明,与之前尝试的支撑剂压裂处理相比,产量增加了几倍。试验增产活动证明了实验室研究的价值,并带来了两个对巴林整体石油产量有巨大贡献的地层。尽管有大量关于水基钻井液对页岩的抑制作用的文献,但页岩抑制作用的重要性以及压裂作业中与页岩反应性相关的问题在很大程度上仍未得到探索。本文介绍了巴林油田增产液优化的复杂实验室方法。全新的解决方案和全面的工作流程描述将有利于全球范围内针对水敏感或低温地层的各种项目,这些项目对压裂液的选择提出了挑战。
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