Numerical Simulation of Cross-Layer Propagation Mechanisms for Hydraulic Fractures in Deep Coal-Rock Formations
Zhirong Jin1,*, Xiaorui Hou1, Yanrong Ge1, Tiankui Guo2, Ming Chen2, Shuyi Li2, Tianyu Niu2
1 Research Institute of Petroleum Engineering Technology, SINOPEC Jiangsu Oilfield Company, Yangzhou, 225009, China
2 School of Petroleum Engineering, China University of Petroleum (East China), Qingdao, 266580, China
* Corresponding Author: Zhirong Jin. Email: 
Energy Engineering https://doi.org/10.32604/ee.2025.070750
Received 23 July 2025; Accepted 12 September 2025; Published online 08 October 2025
Abstract
Hydraulic fracturing serves as a critical technology for reservoir stimulation in deep coalbed methane (CBM) development, where the mechanical properties of gangue layers exert a significant control on fracture propagation behavior. To address the unclear mechanisms governing fracture penetration across coal-gangue interfaces, this study employs the Continuum-Discontinuum Element Method (CDEM) to simulate and analyze the vertical propagation of hydraulic fractures initiating within coal seams, based on geomechanical parameters derived from the deep Benxi Formation coal seams in the southeastern Ordos Basin. The investigation systematically examines the influence of geological and operational parameters on cross-interfacial fracture growth. Results demonstrate that vertical stress difference, elastic modulus contrast between coal and gangue layers, interfacial stress differential, and interfacial cohesion at coal-gangue interfaces are critical factors governing hydraulic fracture penetration through these interfaces. High vertical stress differences (>3 MPa) inhibit interfacial dilation, promoting predominant cross-layer fracture propagation. Reduced interfacial stress contrasts and enhanced interfacial cohesion facilitate fracture penetration across interfaces. Furthermore, smaller elastic modulus contrasts between coal and gangue correlate with increased interfacial aperture. Finally, lower injection rates effectively suppress vertical fracture propagation in deep coal reservoirs. This study elucidates the characteristics and mechanisms governing cross-layer fracture propagation in coal–rock composites with interbedded partings, and delineates the dynamic evolution laws and dominant controlling factors involved. The findings provide critical theoretical insights for the optimization of fracture design and the efficient development of deep coalbed methane reservoirs.
Keywords
Deep coal-rock formations; cross-layer fracturing; fluid-solid coupling; fracture propagation behavior; numerical simulation
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