Mixed-Mode Fracture Modelling of the Near-Wellbore Interaction Between Hydraulic Fracture and Natural Fracture

The interaction between hydraulic fractures (HF) and natural fractures (NF) is one of the most fundamental phenomena in hydraulic fracturing. The near-wellbore interaction between HF and NF significantly affects fracking-related operations including the injected fluid flow, proppant transport and we...

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Bibliographic Details
Published in:Rock mechanics and rock engineering 2022-09, Vol.55 (9), p.5433-5452
Main Authors: Xi, Xun, Shipton, Zoe K., Kendrick, Jackie E., Fraser‑Harris, Andrew, Mouli-Castillo, Julien, Edlmann, Katriona, McDermott, Christopher I., Yang, Shangtong
Format: Article
Language:English
Subjects:
Civil Engineering
Cohesion
Coupled modes
Criteria
Deflection
Earth and Environmental Science
Earth Sciences
Exact solutions
Finite element method
Flow rates
Flow velocity
Fluid dynamics
Fluid flow
Friction
Geophysics/Geodesy
Hydraulic fracturing
Injection
Interfaces
Literature reviews
Mathematical models
Mechanical properties
Modes
Mohr-Coulomb theory
Numerical analysis
Numerical methods
Original Paper
Shear
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Summary:The interaction between hydraulic fractures (HF) and natural fractures (NF) is one of the most fundamental phenomena in hydraulic fracturing. The near-wellbore interaction between HF and NF significantly affects fracking-related operations including the injected fluid flow, proppant transport and well productivity. However, the nature of fracturing modes, combined with hydro-mechanical coupling, poses great difficulties and challenges in addressing this problem. Literature review suggests that little research has been undertaken on near-wellbore interaction, especially considering the fully coupled hydro-mechanical mixed-mode fracturing process. This paper develops a new fracture model incorporating the Mohr–Coulomb criterion with the cohesive crack model. The model is implemented into ABAQUS solver by in-house FORTRAN subroutines. The rock matrix and cohesive crack interfaces are both coupled with fluid flow. The developed model is then validated by comparing the results with analytical solutions and experimental results. Moreover, the effects of approach angle, NF location, in situ stress, cohesion strength and friction angle of NF, and flow rate on the near-wellbore interaction are investigated. Three interaction modes, i.e., cross, deflect and offset, are reproduced through the numerical method. The crack deflection into NF is a shear-dominated mixed-mode fracture. A high injection pressure in the wellbore tends to drive the HF to cross a NF located close to the wellbore. The smaller the cohesion strength and friction angle of NF is, the larger the offsetting ratio is. A low injection flow rate can help activate natural fractures near the wellbore when intersected by HF. Highlights A mixed-mode fracture model incorporating Mohr-Coulomb shear criterion with the fluid cohesive crack model is developed. Three interaction modes, i.e., cross, deflect and offset, are reproduced through the numerical method. The crack deflection into natural fracture is a shear-dominated mixed-mode fracture. A high injection pressure in the wellbore tends to drive the hydraulic fracture to cross a natural fracture located close to the wellbore. The smaller the cohesion strength and friction angle of NF is, the larger the offsetting ratio is.
ISSN:0723-2632
1434-453X
DOI:10.1007/s00603-022-02922-8