Item

Abstract

Enhanced geothermal systems (EGS) are engineered reservoirs developed to extract heat from low permeability and low porosity geological formations. Cyclic hydraulic stimulation treatments can be used in some cases to create hydraulic fractures and gain access to the target formation fluids, drain the geothermal fluid and increase the overall productivity of the reservoir. During these operations, successive cycles of injection at high flow rates are conducted to decrease the effective minimum principal stress to the tensile strength of the material, developing a mode I fracture. Opening of the newly developed fractures induces additional deformation of the reservoir rocks whose impact on the far field reservoir hydraulics has not been addressed so far for real case applications. These rates of compressive deformation can be significantly high in the context of cyclic stimulation treatments and can lead to a poroelastic pore pressure increase which spans quasi-instantaneously at greater distances than diffusive processes. In this study, such a poroelastic response resulting from cyclic deformation during hydraulic stimulation treatment of a well is investigated using hydromechanical coupling between pore pressure variations and rock deformation. The effects of this poroelastic response on the hydromechanical state of a reservoir is illustrated with field measurements of a cyclic hydraulic stimulation treatment conducted at the Groß Schönebeck geothermal research site in August 2007. This study demonstrates that the pore pressure increase monitored in a neighbor well located approximately away from the stimulated well at reservoir depth is controlled by diffusive processes responsible for the long-term increase of pore pressure, but also by poroelastic effects responsible for the quasi-instantaneous local peaks in pore pressure. The results from this applied study helped to quantify the relevance of the poroelastic behavior of stimulated reservoir rocks in a way than can improve current understanding of such hydraulic stimulation settings.