A comprehensive mathematical model for spontaneous imbibition in oil-saturated fractured tight sandstones: Incorporating fracture distribution, displacement pressure, gravity, and buoyancy effects

doi:10.1063/5.0153532

Cited by 8 publications

(2 citation statements)

References 55 publications

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“…At present, many scholars have studied the imbibition process of shale, fractured gas reservoir, and sandstone through laboratory tests, − but there are few studies on coal imbibition. Yue et al − used the traditional slice method, water-sensitive indicator method, and resistivity method to study the evolution behavior of water absorption volume and water absorption height of coal with water absorption time in the process of self-absorption.…”

Section: Introductionmentioning

confidence: 99%

Study on the Evolution Law and Mechanism of Fracture Imbibition in Loaded Coal Based on Micro-CT

Yu,

Li,

Gao

et al. 2023

Energy Fuels

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Section: Introductionmentioning

confidence: 99%

Study on the Evolution Law and Mechanism of Fracture Imbibition in Loaded Coal Based on Micro-CT

Yu,

Li,

Gao

et al. 2023

Energy Fuels

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“…Simultaneously, the effects of factors such as fracture distribution, temperature, displacement pressure, and surfactants on the imbibition process are currently the focal points of research. − In fact, numerous scholars have conducted extensive research on various influencing factors through laboratory experiments, mathematical models, and numerical simulations . For instance, Wang and Yue proposed a comprehensive mathematical model that integrates various aspects of fracture distribution in imbibition processes within tight rock formations, encompassing parameters such as fractal dimension, the number of fractures, fracture size, and their influence on the imbibition mechanisms. Using the phase-field method, Shi et al found, based on the developed nonisothermal oil–water imbibition flow model, that temperature influences the imbibition process by altering the oil–water contact angles, oil–water IFT, and the viscosity ratio between oil and water.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study of Surfactant-Aided Dynamic Spontaneous Imbibition in Tight Oil Reservoirs: The Effect of Fluid Flow, Displacement Pressure, Temperature, and Fracture

Wang,

Zeng,

Wang

et al. 2023

Energy Fuels

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Spontaneous imbibition has emerged as a crucial mechanism for enhancing oil recovery in tight oil reservoirs. However, most of the existing spontaneous imbibition experiments have been static in nature. The dynamic effects of fluid flow, fluid type, displacement pressure, and fractures on the imbibition oil recovery have not been adequately addressed in previous studies. To fill this gap in knowledge and gain a comprehensive understanding of the mechanisms underlying surfactant-aided dynamic spontaneous imbibition, we conducted a series of experiments on tight cores extracted from the Chang 8 formation in the Ordos Basin in Northwest China. The experiments comprised static imbibition, dynamic imbibition, and water flooding displacement, and the impacts of fractures, temperature, type of imbibition fluid, and flow rate on imbibition recovery were analyzed. The results of the experiments showed that fractures have a significant impact on the imbibition oil recovery rate, with the ultimate recovery factor of the fractured core ranging from 16 to 29%, which is higher than that of the matrix core. Dynamic imbibition, on average, resulted in a recovery of 16%, which was higher than that with static imbibition. The use of surfactant solutions enhanced the oil recovery of cores, particularly in dynamic imbibition processes. This was attributed to the acceleration of emulsification between surfactants and crude oil, which led to an increased imbibition rate and oil recovery factor. Displacement was found to be an effective method for recovering the oil not produced through imbibition. The total oil recovery factors of the core samples after imbibition and displacement are in the ranges of 25% and 61%. This study is aimed at investigating the underlying mechanisms of various imbibition processes and examining the influence of various factors on the efficiency of spontaneous imbibition, with the ultimate goal of recovery enhancement in tight oil reservoirs.

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An experimental study on the imbibition characteristics in heterogeneous porous medium

Yuan,

Zhou,

et al. 2023

Physics of Fluids

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Capillary imbibition plays an essential role in the flow behavior of unconventional reservoirs. The severe heterogeneity of pore structures in unconventional formations can lead to different imbibition processes and flow dynamics compared to conventional reservoirs. This study investigates the imbibition process in heterogeneous pore networks by first examining the imbibition process between different pores using an ideal capillary model with interacting microchannel micromodels. The results reveal that water preferentially imbibes into small microchannels rather than large ones, and the imbibition velocity decreases with the microchannel width due to crossflow between different microchannels. Furthermore, heterogeneous matrix–fracture micromodels are used to examine the influence of boundary conditions, pressure conditions, and pore structure distribution on the imbibition process. The results show that the imbibition pattern is primarily governed by the boundary condition and is unaffected by the driving pressure condition. The conventional dimensionless time model fails to capture the spontaneous imbibition characteristics due to the interaction of different pores and the change in the imbibition pattern. Both increasing the injection pressure and increasing boundary openness can lead to higher oil recovery enhancement, and the distribution of the pore structure also influences the final oil recovery. Finally, the imbibition characteristics in the core scale are monitored using Nuclear Magnetic Resonance, demonstrating the similar phenomenon that water can imbibe into small pores and displace oil into larger pores. These findings enhance our understanding of the imbibition mechanism in heterogeneous porous media.

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A comprehensive mathematical model for spontaneous imbibition in oil-saturated fractured tight sandstones: Incorporating fracture distribution, displacement pressure, gravity, and buoyancy effects

Cited by 8 publications

References 55 publications

Study on the Evolution Law and Mechanism of Fracture Imbibition in Loaded Coal Based on Micro-CT

Study on the Evolution Law and Mechanism of Fracture Imbibition in Loaded Coal Based on Micro-CT

Experimental Study of Surfactant-Aided Dynamic Spontaneous Imbibition in Tight Oil Reservoirs: The Effect of Fluid Flow, Displacement Pressure, Temperature, and Fracture

An experimental study on the imbibition characteristics in heterogeneous porous medium

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