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以净零排放为目标的封存驱动型CO₂提高采收率方法 Article

刘月亮, 芮振华

《工程（英文）》 2022年第18卷第11期页码 79-87 doi: 10.1016/j.eng.2022.02.010

摘要：本研究提出了一种新型的CO₂提高采收率（EOR）方法，即封存驱动型CO₂提高采收率，其主要目标是通过在油藏中封存尽可能多的CO₂来实现CO封存驱动型CO₂ EOR方法在提高波及效率方面优于传统的CO₂ EOR，尤其是在采油后期更为明显；同时，封存驱动型CO₂ EOR比传统的CO₂ EOR可更有效地提高原油采收率。此外，通过封存驱动型CO₂ EOR封存的CO₂量远超采出原油燃烧产生的碳排放总量。

关键词： CO₂ EOR CO₂净排放量二甲醚封存驱动型CO₂ EOR CO₂封存

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A review on the application of nanofluids in enhanced oil recovery

《化学科学与工程前沿（英文）》 2022年第16卷第8期页码 1165-1197 doi: 10.1007/s11705-021-2120-4

摘要： Enhanced oil recovery (EOR) has been widely used to recover residual oil after the primary or secondary oil recovery processes. Compared to conventional methods, chemical EOR has demonstrated high oil recovery and low operational costs. Nanofluids have received extensive attention owing to their advantages of low cost, high oil recovery, and wide applicability. In recent years, nanofluids have been widely used in EOR processes. Moreover, several studies have focused on the role of nanofluids in the nanofluid EOR (N-EOR) process. However, the mechanisms related to N-EOR are unclear, and several of the mechanisms established are chaotic and contradictory. This review was conducted by considering heavy oil molecules/particle/surface micromechanics; nanofluid-assisted EOR methods; multiscale, multiphase pore/core displacement experiments; and multiphase flow fluid-solid coupling simulations. Nanofluids can alter the wettability of minerals (particle/surface micromechanics), oil/water interfacial tension (heavy oil molecules/water micromechanics), and structural disjoining pressure (heavy oil molecules/particle/surface micromechanics). They can also cause viscosity reduction (micromechanics of heavy oil molecules). Nanofoam technology, nanoemulsion technology, and injected fluids were used during the EOR process. The mechanism of N-EOR is based on the nanoparticle adsorption effect. Nanoparticles can be adsorbed on mineral surfaces and alter the wettability of minerals from oil-wet to water-wet conditions. Nanoparticles can also be adsorbed on the oil/water surface, which alters the oil/water interfacial tension, resulting in the formation of emulsions. Asphaltenes are also adsorbed on the surface of nanoparticles, which reduces the asphaltene content in heavy oil, resulting in a decrease in the viscosity of oil, which helps in oil recovery. In previous studies, most researchers only focused on the results, and the nanoparticle adsorption properties have been ignored. This review presents the relationship between the adsorption properties of nanoparticles and the N-EOR mechanisms. The nanofluid behaviour during a multiphase core displacement process is also discussed, and the corresponding simulation is analysed. Finally, potential mechanisms and future directions of N-EOR are proposed. The findings of this study can further the understanding of N-EOR mechanisms from the perspective of heavy oil molecules/particle/surface micromechanics, as well as clarify the role of nanofluids in multiphase core displacement experiments and simulations. This review also presents limitations and bottlenecks, guiding researchers to develop methods to synthesise novel nanoparticles and conduct further research.

关键词： nanofluid EOR mechanism nanoparticle adsorption interface property internal property

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Frontier science and challenges on offshore carbon storage

《环境科学与工程前沿（英文）》 2023年第17卷第7期 doi: 10.1007/s11783-023-1680-6

摘要：

● The main direct seal up carbon options and challenges are reviewed.

关键词： Offshore carbon storage Direct CO₂ injection CO₂-CH₄ replacement CO₂-EOR CCS hubs CO₂ transport

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Pore-scale simulation of water/oil displacement in a water-wet channel

Jin Zhao, Guice Yao, Dongsheng Wen

《化学科学与工程前沿（英文）》 2019年第13卷第4期页码 803-814 doi: 10.1007/s11705-019-1835-y

摘要： Water/oil flow characteristics in a water-wet capillary were simulated at the pore scale to increase our understanding on immiscible flow and enhanced oil recovery. Volume of fluid method was used to capture the interface between oil and water and a pore-throat connecting structure was established to investigate the effects of viscosity, interfacial tension (IFT) and capillary number ( ). The results show that during a water displacement process, an initial continuous oil phase can be snapped off in the water-wet pore due to the capillary effect. By altering the viscosity of the displacing fluid and the IFT between the wetting and non-wetting phases, the snapped-off phenomenon can be eliminated or reduced during the displacement. A stable displacement can be obtained under high number conditions. Different displacement effects can be obtained at the same number due to its significant influence on the flow state, i.e., snapped-off flow, transient flow and stable flow, and ultralow IFT alone would not ensure a very high recovery rate due to the fingering flow occurrence. A flow chart relating flow states and the corresponding oil recovery factor is established.

关键词： VOF pore scale immiscible displacement EOR snap-off Ca

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温室气体提高采收率的资源化利用及地下埋存

沈平平,江怀友

《中国工程科学》 2009年第11卷第5期页码 54-59

摘要：

全球气候变化是人类迄今面临的既重大又复杂的环境问题,由于温室气体大量排放而引起的全球气候变暖问题日趋严峻，正在严重地威胁着人类赖以生存的环境，国际社会必须采取积极有效措施。2006年中国国家科技部批准国家“九七三”项目——温室气体提高石油采收率的资源化利用及地下埋存研究。建立适合中国国情的CO₂高效利用和埋存体系；实现CO₂减排的社会效益和CO₂高效利用的经济效益；发展适合中国国情的CO₂埋存地下理论、多相多组分相态理论、多相多组分非线性渗流理论和CO₂捕集与储运理论。通过上述基础研究，形成具有自主知识产权的CO₂地质埋存和高效利用的综合技术，使中国CO₂安全埋存—高效利用研究处于国际水平。必将为全球资源和环境的高水平、高效益开发和可持续发展提供理论及实践依据。

关键词：温室气体资源化利用 CO2地下埋存提高采收率