Modelling fluid injection-induced fracture activation, damage growth, seismicity occurrence and connectivity change in naturally fractured rocks

We develop a fully-coupled hydro-mechanical model to simulate fluid injection-induced activation of pre-existing fractures, propagation of new damages, development of seismic activities, and alteration of network connectivity in naturally fractured rocks. The natural fracture system is represented b...

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Bibliographic Details
Published in:International journal of rock mechanics and mining sciences (Oxford, England : 1997) England : 1997), 2021-02, Vol.138, p.104598, Article 104598
Main Authors: Lei, Qinghua, Gholizadeh Doonechaly, Nima, Tsang, Chin-Fu
Format: Article
Language:English
Subjects:
Computational fluid dynamics
Connectivity
Crack propagation
Earthquake damage
Enhanced geothermal systems
Evolution
Finite element method
Fluid flow
Fluid injection
Fracture network
Fractures
Geoengineering
Geomechanics
Hydraulic stimulation
Hydro-mechanical coupling
Induced seismicity
Injection
Mathematical models
Mechanical properties
Numerical models
Percolation
Permeability
Pore pressure
Pore water pressure
Porous media
Rock masses
Rocks
Seismic activity
Seismicity
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Summary:We develop a fully-coupled hydro-mechanical model to simulate fluid injection-induced activation of pre-existing fractures, propagation of new damages, development of seismic activities, and alteration of network connectivity in naturally fractured rocks. The natural fracture system is represented by a discrete fracture network. The stress and strain fields of the fractured porous media are solved in the framework of a finite element model, which mimics the damage evolution in rock matrix based on an elasto-brittle failure criterion and simulates the normal/shear displacement of natural discontinuities based on a non-linear constitutive law. The coupled geomechanics and fluid flow processes in the fractured rock are computed honouring essential coupling mechanisms such as pore pressure-induced shear slip of pre-existing fractures, poro-elastic response of rock matrix, and stress-dependent permeability/storativity of both fractures and rocks. We use the numerical model developed to investigate the hydro-mechanical behaviour of two cases of deeply buried fractured rock in response to high-pressure fluid injection, one case with fracture density just below the percolation threshold and the other above the threshold. We observe a strong control of natural fracture network connectivity on the damage emergence, seismicity occurrence and connectivity change in the rock mass subject to hydraulic stimulation. We also highlight the strong poro-elastic effect that tends to drive heterogeneous connectivity evolution of fracture systems during fluid injection. The results of our research and insights obtained have important implications for injection-related geoengineering activities such as the development of enhanced geothermal systems and extraction of hydrocarbon resources.
ISSN:1365-1609
1873-4545
1873-4545
DOI:10.1016/j.ijrmms.2020.104598