A study of changes in deep fractured rock permeability due to coupled hydro-mechanical effects

This paper presents a numerical study of the hydro-mechanical behaviour of a fractured rock domain at 1000m depth below the land surface as a function of different levels of fluid pore pressure. A 2D fractured rock domain is adopted based on data obtained from outcrop mapping, displaying multiple fr...

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Bibliographic Details
Published in:International journal of rock mechanics and mining sciences (Oxford, England : 1997) England : 1997), 2015-10, Vol.79 (C), p.70-85
Main Authors: Figueiredo, Bruno, Tsang, Chin-Fu, Rutqvist, Jonny, Niemi, Auli
Format: Article
Language:English
Subjects:
Flow paths
Fractured rock
GEOSCIENCES
Stress-dependent permeability
Tension failure regions
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Summary:This paper presents a numerical study of the hydro-mechanical behaviour of a fractured rock domain at 1000m depth below the land surface as a function of different levels of fluid pore pressure. A 2D fractured rock domain is adopted based on data obtained from outcrop mapping, displaying multiple fracture sets, fracture intersections, dead-end and curved fractures. A continuum based numerical model is used to evaluate the effects of compressive boundary stresses, cracking by tension failure in the intact rock and fractures and shear displacement along fractures on its equivalent permeability. Two in situ stress boundary conditions are considered: an isotropic case SR1 with the two horizontal boundary compressive stresses having the same magnitude, and an anisotropic case SR2 with the ratio between these compressive stress components set to be 2. In the SR2 case, changes in the local stress and stress ratio distributions due to different fluid pore pressure levels are anisotropic and more significant than in the SR1 case, because of tension failures in the intact rock forming bridges between fractures. These failure regions opened new flow connections between fractures and thereby caused important anisotropic changes in the flow paths, and significant decrease in local gradients of fluid pore pressure. The equivalent permeability increases sharply when the fluid pore pressure is approximately 90% of the magnitude of the minimum stress at the boundaries of the fractured rock domain. Results show that the equivalent permeability of the fractured rock domain is most sensitive to the fractures normal stiffness, the permeability of the tension failure regions and the power-law exponent for permeability change. •Hydro-mechanical effects are studied for a realistic fractured rock domain.•Stress distribution over 2D fracture network studied as a function of pore pressure.•Failure or fracturing occurs not as fracture extensions but as failure of a region.•A pore pressure increase changes pressure gradient distribution and flow paths.
ISSN:1365-1609
1873-4545
1873-4545
DOI:10.1016/j.ijrmms.2015.08.011