Oil/Brine Screening for Improved Fluid/Fluid Interactions during Low-Salinity Water Flooding

Jose Villero-Mandon, P. Pourafshary, M. Riazi
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Abstract

Low-salinity water flooding/smart water flooding (LSWF/SWF) are used for enhanced oil recovery (EOR) because of the improved extraction efficiency. These methods are more environmentally friendly and in many scenarios more economical for oil recovery. They are proven to increase recovery factors (RFs) by between 6 and 20%, making LSWF/SWF technologies that should be further evaluated to replace conventional water flooding or other EOR methods. Fluid/fluid interaction improvements include interfacial tension (IFT) reduction, viscoelastic behavior (elastic properties modification), and microemulsion generation, which could complement the main mechanisms, such as wettability alteration. In this research, we evaluate the importance of fluid/fluid mechanisms during LSWF/SWF operations. Our study showed that a substantial decrease in IFT occurs when the oil asphaltene content is in the range of 0% to 3 wt.%. An IFT reduction was observed at low salinity (0–10,000 ppm) and a specific oil composition condition. Optimal IFT occurs at higher divalent ion concentrations when oil has low asphaltene content. For the oil with high asphaltene content, the sulfates concentration controls the IFT alteration. At high asphaltene concentrations, the formation of micro-dispersion is not effective to recover oil, and only a 5% recovery factor improvement was observed. The presence of asphaltene at the oil/low-salinity brine interface increases the energy required to disrupt it, inducing significant changes in the elastic moduli. In cases of low asphaltene content, the storage modulus demonstrates optimal performance at higher divalent concentrations. Conversely, at high asphaltene concentrations, the dominant factors to control the interface are paraffin content and temperature.
油/盐水筛选,改善低盐度水淹没期间的流体/液体相互作用
低盐度水浸法/智能水浸法(LSWF/SWF)可提高开采效率,因此被用于提高石油采收率(EOR)。这些方法更加环保,在许多情况下采油更加经济。实践证明,这些方法可将采收率(RF)提高 6% 到 20%,因此 LSWF/SWF 技术应进一步评估,以取代传统的水淹法或其他 EOR 方法。流体/流体相互作用的改善包括降低界面张力(IFT)、粘弹性行为(弹性特性改变)和微乳化液的产生,这可以补充润湿性改变等主要机制。在这项研究中,我们评估了 LSWF/SWF 操作过程中流体/流体机制的重要性。我们的研究表明,当沥青质油含量在 0% 到 3 wt.% 之间时,IFT 会大幅下降。在低盐度(0-10,000 ppm)和特定的油成分条件下,IFT 会降低。当油中沥青质含量较低时,二价离子浓度较高时,IFT 会达到最佳状态。对于沥青质含量高的油类,硫酸盐浓度控制着 IFT 的改变。在沥青质浓度较高的情况下,微分散的形成对采油效果不佳,采收率仅提高了 5%。石油/低盐度盐水界面上沥青质的存在增加了破坏界面所需的能量,导致弹性模量发生显著变化。在沥青质含量较低的情况下,存储模量在二价浓度较高时表现出最佳性能。相反,在沥青质浓度较高的情况下,控制界面的主要因素是石蜡含量和温度。
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