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多孔介质中纳米辅助泡沫驱替替代气驱替机理的数值研究。

Numerical study of the mechanisms of nano-assisted foam flooding in porous media as an alternative to gas flooding.

作者信息

Bello Ayomikun, Dorhjie Desmond Batsa, Ivanova Anastasia, Cheremisin Alexander, Ilyasov Ilnur, Cheremisin Alexey

机构信息

Center for Petroleum Science and Engineering, Skolkovo Institute of Science and Technology, Skolkovo Innovation Center, 11 Sikorski Street, Moscow 143026, Russia.

JSC «Messoyakhaneftegaz», Russia.

出版信息

Heliyon. 2024 Feb 23;10(5):e26689. doi: 10.1016/j.heliyon.2024.e26689. eCollection 2024 Mar 15.

DOI:10.1016/j.heliyon.2024.e26689
PMID:38434408
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10907739/
Abstract

Oil reservoirs are nearing maturation, necessitating novel enhanced oil recovery (EOR) techniques to meet escalating global energy demands. This demand has spurred interest in reservoir production analysis and forecasting tools to enhance economic and technical efficiency. Accurate validation of these tools, known as simulators, using laboratory or field data is pivotal for precise reservoir productivity estimation. This study delves into the application of nanoparticles in foam flooding for mobility control to improve sweep efficiency. Foam generation can occur in-situ by simultaneous injection of surfactants and gas or through pre-generated foam injection into the reservoir. In this work, a series of systematic simulations were run to investigate how much injected fluids can reduce gas breakthrough while also increasing oil recovery. Subsequently, we analyzed the most effective optimization strategies, considering their economic limits. Our primary objective is to numerically model nanofoam flooding as an innovative EOR approach, synergizing foam flooding mechanisms with nanotechnology benefits. In this work, modeling of nanoparticles in foam liquid was represented by the interfacial properties provided to the injection fluid. Additionally, we simulated Water-Alternating-Gas (WAG) injection schemes across various cycles, comparing their outcomes. Our results showed that nanofoam injection achieved a higher recovery factor of at least 38% and 95% more than WAG and gas injections, respectively. The superior efficiency and productivity of foam injection compared to WAG and gas injection suggest an optimal EOR approach within the scope of our model. These simulated optimization techniques contribute to the future development of processes in this field.

摘要

油藏正接近成熟阶段,因此需要新的强化采油(EOR)技术来满足不断增长的全球能源需求。这种需求激发了人们对油藏生产分析和预测工具的兴趣,以提高经济和技术效率。使用实验室或现场数据对这些称为模拟器的工具进行准确验证,对于精确估计油藏产能至关重要。本研究深入探讨了纳米颗粒在泡沫驱油中用于控制流度以提高波及效率的应用。泡沫可以通过同时注入表面活性剂和气体在原地生成,或者通过将预先生成的泡沫注入油藏来产生。在这项工作中,进行了一系列系统模拟,以研究注入流体能够在多大程度上减少气体突破,同时提高原油采收率。随后,我们分析了最有效的优化策略,并考虑了它们的经济限制。我们的主要目标是将纳米泡沫驱油作为一种创新的EOR方法进行数值模拟,将泡沫驱油机制与纳米技术优势相结合。在这项工作中,泡沫液体中纳米颗粒的建模由提供给注入流体的界面性质表示。此外,我们模拟了不同周期的水交替气(WAG)注入方案,并比较了它们的结果。我们的结果表明,注入纳米泡沫分别比WAG和气体注入实现了至少38%和95%的更高采收率。与WAG和气体注入相比,泡沫注入的卓越效率和产能表明在我们的模型范围内这是一种最佳的EOR方法。这些模拟优化技术有助于该领域工艺的未来发展。

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The Role of Electrostatic Repulsion on Increasing Surface Activity of Anionic Surfactants in the Presence of Hydrophilic Silica Nanoparticles.在亲水性二氧化硅纳米颗粒存在下,静电排斥对提高阴离子表面活性剂表面活性的作用
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Pore-scale simulation of wettability and interfacial tension effects on flooding process for enhanced oil recovery.
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