SmartWater Synergy with Microsphere Injection for Permeable Carbonates

D. Cao, M. Han, S. Saleh, S. Ayirala, A. Al-yousef
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Abstract

This paper presents a laboratory study on combination of SmartWater with microsphere injection to improve oil production in carbonates, which increases the sweep efficiency and oil displacement efficiency. In this study, the properties of a micro-sized polymeric microsphere were investigated including size distribution, rheology, and zeta potential in SmartWater, compared with conventional high salinity injection water. Coreflooding tests using natural permeable carbonate cores were performed to evaluate flow performance and oil production potential at 95°C and 3,100 psi pore pressure. The flow performance was evaluated by the injection of 1 pore volume microspheres, followed by excessive water injection. Oil displacement tests were also performed by injecting 1 pore volume of microspheres dissolved in SmartWater after conventional waterflooding. The median particle size of the microsphere in conventional injection water with a salinity of 57,670 ppm was about 0.25 µm. The particle size was increased by 50% to 100% with reduced elastic modulus when the microsphere dispersed in SmartWater with lower salinity. The zeta potential value of microsphere was decreased in SmartWater compared to that in conventional injection water, showing more negatively charge property. Flow performance of microsphere solutions in the carbonate cores was found to be dependent on their particle size, strength, and suspension stability. The results from coreflooding tests showed that the microsphere dispersed in SmartWater would result in higher differential pressure than that observed in conventional injection water. The SmartWater caused the microspheres swell to larger but softer particles with better suspension stability, which enhanced both the migration and blocking efficiency of microsphere injection. The oil displacement tests confirmed that the microsphere in SmartWater displaced more oil than that obtained with conventional injection water. This result was clearly supported by the higher differential pressure from microsphere injection in SmartWater. The oil bank appeared historically in the post water injection stage, which was quite different from the reported findings of typical mobility controlling agents in the existing knowledge. The microspheres were observed in the core flood produced fluids, indicating the improvement of microsphere migration by SmartWater. This work, for the first time, demonstrated that the combination of SmartWater and microsphere injection yields additional oil production. The proposed hybrid technique can provide a cost-effective way to improve waterflooding performance in heterogeneous carbonates.
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SmartWater协同微球注入用于渗透性碳酸盐
本文介绍了SmartWater与微球注入相结合的实验室研究,以提高碳酸盐岩油藏的产油量,提高波及效率和驱油效率。在这项研究中,研究了SmartWater中微尺寸聚合物微球的性质,包括尺寸分布、流变性和zeta电位,并与常规高矿化度注入水进行了比较。研究人员利用天然渗透性碳酸盐岩心进行了驱芯测试,以评估在95℃、3100 psi孔隙压力下的流动性能和产油量潜力。通过注入1孔体积的微球来评价其流动性能,然后进行过量注水。在常规水驱后,注入1孔隙体积的溶解在SmartWater中的微球进行驱油测试。在盐度为57,670 ppm的常规注入水中,微球的中位粒径约为0.25µm。当微球分散在盐度较低的SmartWater中时,粒径增加了50% ~ 100%,弹性模量降低。与常规注入水相比,SmartWater中微球的zeta电位值降低,表现出更多的负电荷性质。微球溶液在碳酸盐岩心中的流动性能取决于它们的粒径、强度和悬浮稳定性。岩心驱替试验结果表明,与常规注水相比,分散在SmartWater中的微球会产生更高的压差。SmartWater使微球膨胀成更大、更软的颗粒,具有更好的悬浮稳定性,提高了微球注入的迁移和堵塞效率。驱油测试证实,与常规注水相比,SmartWater中的微球驱油效果更好。SmartWater中微球注入的较高压差明显支持了这一结果。历史上,油库是在注水后阶段出现的,这与现有知识中报道的典型流动性控制剂的发现有很大不同。在岩心驱油产出液中观察到微球,表明SmartWater改善了微球运移。这项工作首次证明了SmartWater和微球注入相结合可以提高产油量。所提出的混合技术为提高非均质碳酸盐岩的水驱性能提供了一种经济有效的方法。
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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