Abstract:In the construction of water conservancy, hydropower, underwater tunnels and other geotechnical engineering, rock materials with initial damage are under the coupling action of axial compression and hydraulic pressure for a long time, which seriously affects the long-term stability of geotechnical engineering. The fractured sandstone specimens obtained by preloading were taken as the research object in order to ensure the long-term stability of geotechnical engineering under the coupling of axial compression and hydraulic pressure. The single-stage loading creep tests on the fractured sandstone under the coupling action between axial compression and hydraulic pressure and its creep model were investigated by using a multi-channel rock rheological system. The effects of both the hydraulic pressure and the initial load on creep properties were mainly analyzed. The accuracy and rationality of the constructed creep model were discussed. The results showed that the axial creep of fractured sandstone decreased with the increase of hydraulic pressure. The maximum creep strain rate in the acceleration phase of creep increased with hydraulic pressure increasing. The maximum axial creep strain rate in the initial and the failure stage increased with the initial load increasing. Based on the damage theory, the nonlinear equation of the basic components of the creep model considering initial damage was established. According to the power function equation, a new accelerated creep viscoplastic model was proposed. According to the creep properties of fractured sandstone under the coupling of axial compression and hydraulic pressure, a one-dimensional nonlinear creep model considering aging damage was established. Based on the increment theory, a three-dimensional nonlinear creep model considering aging damage under axial compression was constructed. The creep curves predicted by the new creep models were highly correlated with creep experimental results, which indicated that the established creep model considering the aging damage can well describe the creep change characteristics of fractured rock under the coupling of axial presume and hydraulic pressure. It can provide a theoretical basis for evaluating the long-term stability of geotechnical engineering under the coupling of the in-situ stress and hydraulic pressure.