Qinzhi Li, Yiwen Wang, B. Wei, Lele Wang, Jun Lu, Jinyu Tang
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引用次数: 0
Abstract
: Despite the promising results obtained from the utilization of interfacial-active additives in enhancing imbibition-based oil recovery from tight reservoirs, the predominant mechanisms governing this process remain inadequately understood. In this work, a meticulously designed workflow is implemented to conduct experiments and modeling focusing on imbibition tests performed on tight sandstone cores while utilizing surfactant and microemulsion. Our primary objective is to investigate the response of oil recovery to these additives and to develop a robust and reliable model that incorporates the intricate interactions, thereby elucidating the underlying mechanisms. Two imbibition fluids are designed, namely, surfactant and microemulsion. A comprehensive investigation is performed to analyze the physicochemical properties of these fluids, encompassing phase behavior, density, viscosity, and wettability alteration, with the aim of establishing fundamental knowledge in the field. Three imbibition tests are carried out to observe the response of oil production and optimize the experimental methodology. A numerical model is developed that fully couples the evolution of relative permeability and capillary pressure with the dynamic processes of emulsification, solubilization and molecular diffusion. The results demonstrate the crucial role of emulsification/solubilization in the imbibition process.
CapillarityPhysics and Astronomy-Surfaces and Interfaces
CiteScore
7.10
自引率
0.00%
发文量
15
审稿时长
2~3 weeks
期刊介绍:
Capillarity publishes high-quality original research articles and current reviews on fundamental scientific principles and innovations of capillarity in physics, chemistry, biology, environmental science and related emerging fields. All advances in theoretical, numerical and experimental approaches to capillarity in capillary tube and interface dominated structure and system area are welcome.
The following topics are within (but not limited to) the scope of capillarity:
i) Capillary-driven phenomenon in natural/artificial tubes, porous and nanoporous materials
ii) Fundamental mechanisms of capillarity aided by theory and experiments
iii) Spontaneous imbibition, adsorption, wicking and related applications of capillarity in hydrocarbon production, chemical process and biological sciences
iv) Static and dynamic interfacial processes, surfactants, wettability, film and colloids
v) New approaches and technologies on capillarity
Capillarity is a quarterly open access journal and free to read for all. The journal provides a communicate platform for researchers who are interested in all fields of capillary phenomenon.
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