A fluid–solid coupling model for hydraulic fracture of deep coal seam based on finite element method

• Published in: Physics of fluids (1994) Vol. 36; no. 6
• Main Authors: Zhang, Dongxu, Wu, Chengxi, Shi, Zejin, Li, Yaqi, Zhao, Yulong, Wu, Xudong
• Format: Journal Article
• Language: English
• Published: Melville American Institute of Physics 01.06.2024
• Subjects: Coal; Coalbed methane; Computer simulation; Coupling; Deformation effects; Desorption; Finite element method; Gas flow; Horizontal wells; Hydraulic fracturing; Hydraulics; Permeability; Porosity; Seepage
• ISSN: 1070-6631; 1089-7666
• DOI: 10.1063/5.0213223

The fluid–solid coupling effect is more pronounced in the process of deep coal seam development compared to shallow coalbed methane, exerting a greater influence on production, and cannot be disregarded. Throughout the extraction process, the interaction between effective stress and gas desorption triggers deformation within the coal seam, leading to dynamic changes in both porosity and permeability. This paper has developed a fully coupled gas flow and deformation model that contains the coal matrix and discrete fractures to describe the dynamic gas seepage behavior and deformation of deep coal seams within a coupled wellbore–hydraulic fractures–matrix system. The model's validity is corroborated through the examination of fracture aperture, employing the finite element numerical simulation capabilities of COMSOL Multiphysics. Subsequent to the model's validation, an in-depth investigation into the permeability and production variations under diverse parametric conditions is conducted. This analysis also encompasses the assessment of hydraulic fracture geometry's impact. The simulation outcomes reveal that the permeability alterations during coal seam development are subject to the counteracting influences of gas desorption and effective stress. Moreover, it is observed that an increase in the Langmuir volume strain constant and initial porosity correlates with enhanced production, whereas a diminution in the hydraulic fracture compression coefficient leads to increased cumulative production. Notably, the optimal production is attained when hydraulic fractures are oriented vertically yet asymmetrically relative to the horizontal well.