Microemulsion in Enhanced Oil Recovery

Shehzad Ahmed, K. Elraies
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引用次数: 16

Abstract

The success of surfactant flooding for enhanced oil recovery (EOR) process depends on the efficiency of designed chemical formula. In this chapter, a thorough discussion on Winsor Type III microemulsion was included which is considered the most desirable condition for achieving an ultra-low interfacial tension during surfactant-flooding process. A brief literature review on chemicals, experimental approaches, and methods used for the generation of the desirable phase was presented. Phase behavior studies of microemulsion are a very important tool in describing the interaction of an aqueous phase containing surfactant with hydrocarbon phase to form the Type III microemulsion. Microemulsion highly depends on brine salinity and the interfacial tension (IFT) changes as microemulsion phase transition occurs. At optimal salinity, Type III microemulsion forms, whereas salinity greater or lower than optimal value causes a significant increase in the IFT, resulting in insufficient oil displacement efficiency. Type III microemulsion at optimum salinity is characterized by ultra-low IFT, and extremely high oil recovery can be achieved. In addition, this chapter also stated various other mechanisms relating to oil entrapment, microemulsion phase transition, and surfactant loss in porous media.
微乳液在提高原油采收率中的应用
表面活性剂驱提高采收率的成功与否取决于所设计的化学配方的效率。在本章中,对Winsor III型微乳液进行了深入的讨论,该微乳液被认为是表面活性剂驱过程中实现超低界面张力的最理想条件。简要回顾了化学物质,实验方法,以及用于生成所需相的方法。微乳液的相行为研究是描述含表面活性剂的水相与烃类相相互作用形成III型微乳液的重要工具。微乳液高度依赖于卤水盐度,界面张力随微乳液相变的发生而变化。在最佳矿化度下,形成III型微乳液,而矿化度高于或低于最佳矿化度会导致IFT显著升高,导致驱油效率不足。最佳矿化度下的III型微乳液具有超低IFT的特点,可实现极高的采收率。此外,本章还阐述了多孔介质中与油捕获、微乳液相变和表面活性剂损失有关的各种其他机制。
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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