Two-Phase Flow Model for Numerical Investigation of Impact of Water Retention on Shale Gas Production

In this work, a triple-porosity, two-phase flow model was established to fill the knowledge gap of previous models focusing on gas production characteristics while ignoring the impacts of water injection. The proposed model considers the water flow in the fracture systems and clay minerals and the g...

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Bibliographic Details
Published inGeofluids Vol. 2021; pp. 1 - 17
Main Authors Xu, Ershe, Yu, Lingjie, Fan, Ming, Chen, Tianyu, Pan, Zhejun, Tan, Yuling, Cui, Guanglei
Format Journal Article
LanguageEnglish
Published Chichester Hindawi 20.12.2021
Hindawi Limited
Wiley
Subjects
Adsorption
Analysis
Clay minerals
Depletion
Economics
Equilibrium
Gas flow
Gas production
Gas wells
Goodness of fit
Hydraulic fracturing
Hydraulic measurements
Hydraulics
Influence
Injection
Investigations
Mathematical models
Minerals
Multiphase flow
Natural gas
Oil and gas production
Oil wells
Organic matter
Partial differential equations
Permeability
Porosity
Pressure
Production data
Profitability
Reservoirs
Sedimentary rocks
Shale
Shale gas
Shale oils
Shales
Tensile strength
Two phase flow
Water
Water flooding
Water flow
Water injection
China
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Summary:In this work, a triple-porosity, two-phase flow model was established to fill the knowledge gap of previous models focusing on gas production characteristics while ignoring the impacts of water injection. The proposed model considers the water flow in the fracture systems and clay minerals and the gas flow in the organic matter, inorganic pore, and fracture systems. The proposed model is solved using a finite element approach with COMSOL Multiphysics (Version 5.6) and verified with field data. Then, the evolutions of the intrinsic and relative permeabilities during water injection and gas production are examined. Furthermore, the impacts of water injection time and pressure are investigated. Good verification results are obtained; the goodness-of-fit value is 0.92, indicating that the proposed model can replicate both the water stimulation and the gas production stages. The relative gas permeability declines during water injection but recovers in the gas depletion stage. Furthermore, the intrinsic permeability increases during the water injection stage but decreases during the gas production stage. A higher water injection pressure and longer injection time would enlarge the intrinsic permeability, thus improving flow capacity. However, it would reduce gas relative permeability, thereby hindering gas flow. The shale gas production characteristic is controlled by the two abovementioned competing mechanisms. There exists a perfect combination of water injection pressure and injection time for achieving the maximum profitability of a shale gas well. This work can give a better understanding of the two-phase flow process in shale reservoirs and shed light on the field application of hydraulic fracturing.
ISSN:1468-8115
1468-8123
DOI:10.1155/2021/2637217