Evaluating Long-Term Strength and Time to Failure of Sandstone with Different Initial Damage

Long-term strength (LTS) of rock materials is important for the long-term stability analysis and the failure prediction of structures in rock engineering. Numerous studies have been carried out on the LTS for various kinds of rock; however, the effects of initial damage on the LTS and creep failure time of rock have not been conducted. In the present study, the creep experiment with controllable initial damage state of rock was designed. Then, the LTS of rock specimens with different initial damage was determined by four methods (i.e., the isochronous stress-strain curve method, the steady creep discriminated method, the volumetric strain inflexion point determined method, and the intersection of the steady creep rate method). The results show that, with the increase in the initial damage, the LTS of rock decreases and the relationship between the initial damage and the LTS of rock can be described as a linear function. Finally, an evaluation method for predicting the creep failure time of rock under a single stress level was proposed. In addition, the creep failure time of rock with different initial damage under different creep stress levels was obtained by the method. The results indicate that both the initial damage and the creep stress levels have a great influence on creep failure time, i.e., greater initial damage or creep stress leads to a shorter period for rock failure. Thus, for analyzing the long-term stability of rock mass structure, not only the influence of in situ stress but also the initial damage state of the surrounding rock should be considered.

[1]  Shuguang Zhang,et al.  Creep energy damage model of rock graded loading , 2019, Results in Physics.

[2]  Yugui Yang,et al.  Experimental research on rock fracture failure characteristics under liquid nitrogen cooling conditions , 2018, Results in Physics.

[3]  S. Tang,et al.  The Influence of Water Saturation on the Short- and Long-Term Mechanical Behavior of Red Sandstone , 2018, Rock Mechanics and Rock Engineering.

[4]  Y. Nara,et al.  Evaluating long-term strength of rock under changing environments from air to water , 2017 .

[5]  Wancheng Zhu,et al.  The Influence of Temperature on Time-Dependent Deformation and Failure in Granite: A Mesoscale Modeling Approach , 2017, Rock Mechanics and Rock Engineering.

[6]  Jia-wen Zhou,et al.  Failure Mechanisms and Evolution Assessment of the Excavation Damaged Zones in a Large-Scale and Deeply Buried Underground Powerhouse , 2017, Rock Mechanics and Rock Engineering.

[7]  Sheng-Qi Yang,et al.  Nonlinear visco-elastic and accelerating creep model for coal under conventional triaxial compression , 2015 .

[8]  Wang Lu,et al.  Experimental study on creep deformation and long-term strength of unloading-fractured marble , 2015 .

[9]  Y. Nara Effect of Anisotropy on the Long-Term Strength of Granite , 2015, Rock Mechanics and Rock Engineering.

[10]  Chuangbing Zhou,et al.  Contributions of In-Situ Stress Transient Redistribution to Blasting Excavation Damage Zone of Deep Tunnels , 2015, Rock Mechanics and Rock Engineering.

[11]  Won-Jin Cho,et al.  A Comparative Evaluation of Stress–Strain and Acoustic Emission Methods for Quantitative Damage Assessments of Brittle Rock , 2015, Rock Mechanics and Rock Engineering.

[12]  Shanyong Wang,et al.  Rheological Characteristics of Weak Rock Mass and Effects on the Long-Term Stability of Slopes , 2014, Rock Mechanics and Rock Engineering.

[13]  Tao Xu,et al.  A numerical analysis of rock creep-induced slide: a case study from Jiweishan Mountain, China , 2014, Environmental Earth Sciences.

[14]  N. Chandler Quantifying long-term strength and rock damage properties from plots of shear strain versus volume strain , 2013 .

[15]  J. Shao,et al.  An Experimental Investigation and an Elastoplastic Constitutive Model for a Porous Rock , 2013, Rock Mechanics and Rock Engineering.

[16]  J. Chen,et al.  Time-Dependent Damage Investigation of Rock Mass in an In Situ Experimental Tunnel , 2012, Materials.

[17]  Charles Fairhurst,et al.  Evidence for a Long-Term Strength Threshold in Crystalline Rock , 2010 .

[18]  Y. Nara,et al.  Subcritical crack growth and long-term strength in rock and cementitious material , 2010 .

[19]  N. A. Chandler,et al.  The progressive fracture of Lac du Bonnet granite , 1994 .

[20]  LI Lian-chon Time-dependent deformation of rock slopes based on long-term strength characteristics of rocks , 2014 .

[21]  M. Kwaśniewski,et al.  ISRM Suggested Methods for Determining the Creep Characteristics of Rock , 2013, Rock Mechanics and Rock Engineering.

[22]  Sun Jun,et al.  ROCK RHEOLOGICAL MECHANICS AND ITS ADVANCE IN ENGINEERING APPLICATIONS , 2007 .

[23]  Fu Zhiliang EXPERIMENTAL STUDY ON RHEOLOGY PROPERTIES AND LONG-TERM STRENGTH OF ROCKS , 2006 .