Shut-In Effect in Removing Water Blockage in Shale-Oil Reservoirs With Stress-Dependent Permeability Considered

Wijaya, Nur; Sheng, James J.

doi:10.2118/195696-pa

Cited by 27 publications

(10 citation statements)

References 33 publications

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“…Generally, there are two important mechanisms on the effect of shut-in time on imbibition. On one hand, shut-in allows for a fracturing fluid in fractures to imbibe into the matrix, so that oil/gas is expelled from the matrix to the fractures, which is beneficial to imbibition . On the other hand, the water saturation in the matrix increases as a result of imbibition, and thus, the oil/gas relative permeability decreases, and the resistance of oil/gas discharge increases; therefore, they are not beneficial to imbibition, especially in counter-current imbibition.…”

Section: Eor By Imbibition In Reservoir Developmentmentioning

confidence: 99%

A Critical Review of Enhanced Oil Recovery by Imbibition: Theory and Practice

Tian

Gao

et al. 2021

Energy Fuels

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Imbibition is very common, occurring in life, material, chemistry, and energy. It plays an important role in enhanced oil recovery (EOR). The development of many reservoirs is beneficial to the imbibition process, such as fractured reservoirs, conventional reservoirs developed by a water-injection mode of huff-n-puff in their later development, and unconventional reservoirs with abundant micro–nanopores developed by the fracturing technology. Here, we present a critical review of EOR through imbibition. First, the mechanisms of EOR through imbibition are reviewed, including the mechanical analysis of imbibition in a capillary, imbibition models for rocks, and the scaling law. Then, the governing factors of EOR by imbibition are summarized, including the properties of rocks and fluids and the effects of the temperature and pressure. Besides, the EOR by imbibition in the oil and gas development is discussed, including the roles of surfactants, nanofluids, salinity, shut-in time, and injection/production rates. Finally, conclusions and outlooks are presented. This review provides systematic and recent insights about EOR by imbibition and a direction for future research on this topic, which can help for a better understanding of EOR by imbibition.

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Section: Eor By Imbibition In Reservoir Developmentmentioning

confidence: 99%

A Critical Review of Enhanced Oil Recovery by Imbibition: Theory and Practice

Tian

Gao

et al. 2021

Energy Fuels

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“…Well shut-in for a specific time after hydraulic fracturing is the technical way to improve the efficiency of liquid utilization. Shut-in time after fracturing is an important factor influencing the utilization efficiency of fracturing fluid [34][35][36]. In this study, the dualmedium single-stage fracturing model was used to study the utilization law of fracturing fluid during shut-in after fracturing and the effect of shut-in time on the efficiency of fracturing fluid utilization.…”

Section: Well Shut-in Timementioning

confidence: 99%

Insight into the Methods for Improving the Utilization Efficiency of Fracturing Liquid in Unconventional Reservoirs

Xu¹,

Lei

Cheng-mei³

et al. 2021

Geofluids

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A large amount of fracturing fluid will be injected into the unconventional reservoirs during hydraulic fracturing. At present, the maximum amount of fracturing fluid injected into shale oil reaches 70000 m3 in Jimsar. The main function of fracturing fluid is to make fractures for traditional reconstruction of fracturing; for unconventional reservoirs, fracturing fluid is also used to increase formation energy by large-scale injection. It is of great significance to improve the utilization efficiency of large-scale hydraulic fracturing fluid for shale oil to increase production and recovery. In this study, the method of improving the utilization efficiency of the large-scale hydraulic fracturing fluids is explored by experiment, numerical simulation, and field test of Jimsar shale oil formation. This research shows that fracture complexity can effectively increase the contact area between the fracturing fluids and the formation. The water absorption rate of the fractured core is increased, which lays the foundation for improving the liquid utilization efficiency. Reasonably, well shutting before production ensures the pressure balance in the fractures, and the fluid pressure can be transmitted to the far end, which improves the fracture effectiveness, increases formation energy, and promotes imbibition and oil displacement. By using the additive of enhanced imbibition displacement, the displacement efficiency and the displacement amount of crude oil in the micro-nanopores can be greatly improved, and the utilization ratio of liquid can be further enhanced. The experiment adopted in the field proves that improving energy utilization efficiency has an important impact on production. This study has great guiding significance for the efficient development and practical production of unconventional reservoirs.

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“…Common methods on this research currently include laboratory experiment, numerical simulation, and micromechanical analytical equation. To be specific, the laboratory experimental method employed by Wijaya and Sheng [10], Crawford et al [6], and Kim et al [11] aims to build the empirical model of the variation of porosity with pore pressure macroscopically by fitting the experimental data, whereas such a type of model still covers certain empirical parameters and exhibits relatively poor applicability to the microscopic scale. e numerical simulation method adopted by Stoxreiter et al [12,13] largely complies with the use of finite element techniques to analyze the pore deformation characteristics during triaxial compression.…”

Section: Introductionmentioning

confidence: 99%

Study on Two-phase Flow Mechanisms in Nanopore Considering Microcosmic Deformation and Dynamic Capillary Force

et al. 2022

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Coring experiments show that nanopores are extensively distributed in shale oil reservoirs and tend to be deformed when a significant pressure variation exists, and thus the dynamic capillary force phenomenon and flow mechanisms in nanopores can be significantly changed. To characterize the two-phase flow mechanisms in nanopores influenced by the synergistic effect of microcosmic pore deformation and dynamic capillary force, models based on Gassmann’s theory are established to describe the variations of pore radius and roughness in a dynamic pressure field. And then, innovative methods to quantify the dynamic capillary force phenomenon under comprehensive influence of pore size, roughness, and pressure are developed. Meanwhile, mathematical models, considering the effect of the pore deformation and dynamic capillary force, are furtherly derived to characterize the water-oil two-phase flow behavior for relatively large nanopores in shale oil reservoir, which can be used to investigate the influence of the vital parameters. The results indicate that the dynamic capillary force phenomenon turns out to be more significant when variations of pore structure and pressure are considered simultaneously. Moreover, the pore deformation and dynamic capillary force caused by pressure change can exert remarkable synergistic influence on the transport capacity for typical flow modes. Bulk modulus is one of the key factors to determine the degree of influence. An optimal pressure can be obtained to coordinate the competitive effect of seepage channel and capillary force for water-drive-oil mode with limited driving force. Based on that, emphasis should be placed on pressure control during the shale oil development process. This work theoretically underpins the quantitative characterization and the analysis of two-phase flow in shale reservoirs at the nanopore scale.

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Shut-In Effect in Removing Water Blockage in Shale-Oil Reservoirs With Stress-Dependent Permeability Considered

Cited by 27 publications

References 33 publications

A Critical Review of Enhanced Oil Recovery by Imbibition: Theory and Practice

A Critical Review of Enhanced Oil Recovery by Imbibition: Theory and Practice

Insight into the Methods for Improving the Utilization Efficiency of Fracturing Liquid in Unconventional Reservoirs

Study on Two-phase Flow Mechanisms in Nanopore Considering Microcosmic Deformation and Dynamic Capillary Force

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