Implicit hydromechanical representation of fractures using a continuum approach

Fractures control fluid flow, solute transport, and mechanical deformation in crystalline media. They can be modeled numerically either explicitly or implicitly via an equivalent continuum. The implicit framework implies lower computational cost and complexity. However, upscaling heterogeneous fract...

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Bibliographic Details
Published in:International journal of rock mechanics and mining sciences (Oxford, England : 1997) England : 1997), 2024-11, Vol.183, p.105916, Article 105916
Main Authors: Vaezi, Iman, Parisio, Francesco, Yoshioka, Keita, Alcolea, Andres, Meier, Peter, Carrera, Jesús, Olivella, Sebastià, Vilarrasa, Víctor
Format: Article
Language:English
Subjects:
Embedded model
Equivalent fracture layer
Fracture implicit representation
Fracture variable permeability
Hydraulic stimulation of fractures
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Summary:Fractures control fluid flow, solute transport, and mechanical deformation in crystalline media. They can be modeled numerically either explicitly or implicitly via an equivalent continuum. The implicit framework implies lower computational cost and complexity. However, upscaling heterogeneous fracture properties for its implicit representation as an equivalent fracture layer remains an open question. In this study, we propose an approach, the Equivalent Fracture Layer (EFL), for the implicit representation of fractures surrounded by low-permeability rock matrix to accurately simulate hydromechanical coupled processes. The approach assimilates fractures as equivalent continua with a manageable scale (≫1 μm) that facilitates spatial discretization, even for large-scale models including multiple fractures. Simulation results demonstrate that a relatively thick equivalent continuum layer (in the order of cm) can represent a fracture (with aperture in the order of μm) and accurately reproduce the hydromechanical behavior (i.e., fluid flow and deformation/stress behavior). There is an upper bound restriction due to the Young's modulus because the equivalent fracture layer should have a lower Young's modulus than that of the surrounding matrix. To validate the approach, we model a hydraulic stimulation carried out at the Bedretto Underground Laboratory for Geosciences and Geoenergies in Switzerland by comparing numerical results against measured data. The method further improves the ability and simplicity of continuum methods to represent fractures in fractured media. •We propose a representation method to model fractures as an equivalent continuum medium.•The method can reproduce accurately the HM response of a single fracture.•The method is validated with a field-injection experiment at the Bedretto site.
ISSN:1365-1609
1873-4545
DOI:10.1016/j.ijrmms.2024.105916