Hydromechanical interactions in a fractured carbonate reservoir inferred from hydraulic and mechanical measurements

• Published in: International journal of rock mechanics and mining sciences (Oxford, England : 1997) Vol. 42; no. 2; pp. 287 - 306
• Main Authors: Cappa, F., Guglielmi, Y., Fénart, P., Merrien-Soukatchoff, V., Thoraval, A.
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 01.02.2005; Elsevier Science
• Subjects: Applied sciences; Buildings. Public works; Exact sciences and technology; Fractured rocks; Geotechnics; Hydromechanical coupling; In situ measurements; Mechanical; Permeability; Soil mechanics. Rocks mechanics; France; Europe; In situ measurements; Fractured rocks; Permeability; Hydromechanical coupling; Mechanical; Discontinuity; Sensitivity analysis; Rock mechanics; Reservoir rock; In situ; Experimental study; Rock mass; Modeling; Carbonate rock; Experimental result; Numerical analysis; Hydrogeology; Hydromechanics; Analytical method; Jointed rock
• ISSN: 1365-1609; 1873-4545
• DOI: 10.1016/j.ijrmms.2004.11.006

Hydromechanical coupled processes in a shallow fractured carbonate reservoir rock were investigated through field experiments coupled with analytical and numerical analyses. The experiments consist of hydraulic loading/unloading of a water reservoir in which fluid flow occurs mainly inside a heterogeneous fracture network made up of vertical faults and bedding planes. Hydromechanical response of the reservoir was measured using six pressure–normal displacement sensors located on discontinuities and two surface tiltmeters. A dual hydraulic behavior was characterized for low-permeability bedding planes well connected to high-permeability faults. Displacement responses show high-variability, nonlinear changes, sometimes with high-frequency oscillations, and a large scattering of magnitudes. Initial normal stiffnesses and effective normal stresses along fault planes were estimated in the field by interpreting pressure–normal displacement relations with a nonlinear function between effective normal stress and normal displacement. Two-dimensional discontinuum modeling with transient fluid flow was performed to fit measurements during hydraulic loading tests. Results show that the hydromechanical behavior of the reservoir is restored if a high stiffness contrast is allocated between low- and high-permeability discontinuities. Thus, a dual-permeability network of discontinuities will likely also be a contrasting stiffness network, in which the deformation of major flow-conducting discontinuities is significantly influenced by the stiffness of the surrounding less-permeable discontinuities.