Options
Valley, Benoît
Résultat de la recherche
Development of connected permeability in massive crystalline rocks through hydraulic fracture propagation and shearing accompanying fluid injection
2016, Preisig, Giona, Eberhardt, Erik, Gischig, Valentin, Roche, Vincent, van de Baan, Mirko, Valley, Benoît, Kaiser, Peter K., Duff, Damien, Lowther, R., Gleeson, T., Ingebritse, E.
Development of connected permeability in massive crystalline rocks through hydraulic fracture propagation and shearing accompanying fluid injection
2014-2, Preisig, Giona, Eberhardt, E., Gischig, V., Roche, V., Van der Baan, M., Valley, Benoît, Kaiser, P.K., Duff, D., Lowther, R.
The ability to generate deep flow in massive crystalline rocks is governed by the interconnectivity of the fracture network and its permeability, which in turn is largely dependent on the in situ stress field. The increase of stress with depth reduces fracture aperture, leading to a decrease in rock mass permeability. The frequency of natural fractures also decreases with depth, resulting in less connectivity. The permeability of crystalline rocks is typically reduced to about 1017–1015 m2 at targeted depths for enhanced geothermal systems (EGS) applications, that is, >3 km. Therefore, fluid injection methods are required to hydraulically fracture the rock and increase its permeability. In the mining sector, fluid injection methods are being investigated to increase rock fragmentation and mitigate high-stress hazards due to operations moving to unprecedented depths. Here as well, detailed understanding of permeability and its enhancement is required. This paper reports findings from a series of hydromechanically coupled distinct-element models developed in support of a hydraulic fracture experiment testing hypotheses related to enhanced permeability, increased fragmentation, and modified stress fields. Two principal injection designs are tested as follows: injection of a high flow rate through a narrow-packed interval and injection of a low flow rate across a wider packed interval. Results show that the development of connected permeability is almost exclusively orthogonal to the minimum principal stress, leading to strongly anisotropic flow. This is because of the stress transfer associated with opening of tensile fractures, which increases the confining stress acting across neighboring natural fractures. This limits the hydraulic response of fractures and the capacity to create symmetric isotropic permeability relative to the injection wellbore. These findings suggest that the development of permeability at depth can be improved by targeting a set of fluid injections through smaller packed intervals instead of a single longer injection in open boreholes.