利用高效阳离子表面活性剂制备致密油自吸纳米乳液:实验与数值模拟

B. Wei, Runxue Mao, Haoran Tang, Lele Wang, Dianlin Wang, Yiwen Wang, Junyu You, Jun Lu
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引用次数: 1

摘要

自发渗吸是致密油储层加速裂缝与基质间物质交换的重要手段。然而,卤水和表面活性剂等常规体系的吸胀效果有限,因此基质中仍然存在大量的剩余油。纳米乳液由于具有良好的表面活性和纳米级的液滴,在提高致密油采收率方面具有很大的潜力,但目前还缺乏经济、简便的制备方法。为此,本文制备了一种低表面活性剂用量、低能耗的阳离子表面活性剂O/W纳米乳液,并通过实验和数值模拟对长庆露头岩心的自吸性能进行了评价。我们充分考虑了纳米乳液可能的吸胀机制,包括润湿性改变、IFT还原、增溶和乳化等,并成功应用于纳米乳液的吸胀模型。模型与实验数据吻合较好。结果表明,纳米乳在前100小时的吸胀速率和采收率低于盐水;在后期,我们观察到超低IFT纳米乳的平衡时间更长,吸油速度更快,吸油速率更高。最后,通过与不考虑增溶和乳化的模型对比,证实了增溶和乳化是纳米乳吸胀的主要机理之一。
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Facile Fabrication of Nanoemulsions through the Efficient Catanionic Surfactants for Spontaneous Imbibition in Tight Oil Reservoirs: Experimental and Numerical Simulation
Spontaneous imbibition (SI) is an essential method for accelerating mass exchange between fracture and matrix in tight oil reservoirs. However, conventional systems such as brine and surfactant solution have limited imbibition effects, so there is still abundant remaining oil in the matrix. Nanoemulsion holds the most promising potential in improving tight oil recovery owing to the favorable surface activity and nanoscale droplets, but it still lacks economic and facile methods to fabricate nanoemulsions. Therefore, in this paper, we prepared a kind of O/W nanoemulsion of catanionic surfactants with a low dosage of surfactant and energy consumption, which was then used to assess spontaneous imbibition performance in Changqing outcrop cores by experimental and numerical simulation. We have fully considered the possible imbibition mechanisms of nanoemulsion including wettability alteration, IFT reduction, solubilization and emulsification, etc., and successfully applied to the nanoemulsion imbibition model. The model and experimental data were found to be in good agreement. The results showed that the imbibition rate and oil recovery factor of the nanoemulsion in the first 100 hours are lower than that of brine. In the late stage, we observed a longer equilibrium time and a faster and higher oil imbibition process in nanoemulsion with ultralow IFT. Finally, we confirmed that solubilization and emulsification is one of the domiant mechanisms for nanoemulsion imbibition by comparing with the modelling without considering solubilization and emulsification.
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