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Assessment of extended Derjaguin–Landau–Verwey–Overbeek‐based water film on multiphase transport behavior in shale microfractures
Author(s) -
Wang Dongying,
Yao Jun,
Chen Zhangxin,
Song Wenhui,
Sun Hai,
Yan Xia
Publication year - 2021
Publication title -
aiche journal
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.958
H-Index - 167
eISSN - 1547-5905
pISSN - 0001-1541
DOI - 10.1002/aic.17162
Subject(s) - disjoining pressure , relative permeability , slippage , percolation theory , permeability (electromagnetism) , water transport , petroleum engineering , oil shale , capillary pressure , chemistry , geology , materials science , mechanics , soil science , porous medium , water flow , geotechnical engineering , conductivity , wetting , composite material , porosity , membrane , physics , paleontology , biochemistry
This study presents a novel model to predict gas–water two‐phase transport behaviors in shale microfractures by incorporating a mobile water film with varying thickness according to the extended Derjaguin–Landau–Verwey–Overbeek theory as well as multiple fluid transport mechanisms (i.e., real gas transport controlled by the Knudsen number and water slippage). This model is implemented in real shale microfractures via digital‐core imaging. A gas–water displacement process is modeled by the invasion percolation theory, while a local multiphase distribution is determined by combining disjoining pressure with capillary force. Key findings reveal that gas relative permeability decreases by 17% and water RP enhances by 33.5%, when the mean aperture decreases from 1.67 to 0.0418 μm. Neglecting water film brings a decrease in water RP and an overestimation of gas transport ability. Moreover, two critical microfracture apertures are determined, which enhances an understanding of the water film impact on gas–water transport properties in application.