Creep properties and damage constitutive model of salt rock under uniaxial compression

To study the creep property of salt rock, uniaxial compression creep tests on salt rock specimens were carried out. The test results indicate that there is no steady creep of the salt rock used in this test in a strict sense. Even in the steady creep stage, the creep rate of salt rock changes continuously over time, but with a relatively smaller change range. When the axial stress does not exceed 9.5 MPa, the isochronous stress–strain curve of salt rock is approximately straight. While the axial stress exceeds 9.5 MPa, the isochronous stress–strain curve deflects to the strain axis, and the larger the axial stress, the more obvious the deflection. Thus, the long-term strength of the salt rock used in this test can be determined as 9.5 MPa. A mathematical expression for predicting the creep failure time of rock is proposed on the basis of assuming the change rule of rock strength over time conforms to the Usher function. Then starting from the variation in deformation modulus with respect to time in the creep process of salt rock, the elastic modulus of the damaged rock material is characterized by the deformation modulus, and the creep damage evolution equation of rock is established. Combined with the continuous damage mechanics theory, a new creep damage constitutive model for rock is proposed. The rationality of the model is verified using the uniaxial compression creep test results of salt rock. The results show that the new model can not only describe the attenuation and the steady creep of salt rock under low stress level, but also reflect the whole creep failure process under high stress level. The predicted curves under different axial stresses are all in good agreement with the test data.

[1]  Lance A. Roberts,et al.  Cyclic Loading Effects on the Creep and Dilation of Salt Rock , 2015, Rock Mechanics and Rock Engineering.

[2]  Z. Shao,et al.  A microcrack growth-based constitutive model for evaluating transient shear properties during brittle creep of rocks , 2018 .

[3]  Katsunori Fukui,et al.  Time-Dependent Behaviors of Granite: Loading-Rate Dependence, Creep, and Relaxation , 2016, Rock Mechanics and Rock Engineering.

[4]  Elham Mahmoudi,et al.  Probabilistic Analysis of a Rock Salt Cavern with Application to Energy Storage Systems , 2016, Rock Mechanics and Rock Engineering.

[5]  X. Pei,et al.  A new rock creep model based on variable-order fractional derivatives and continuum damage mechanics , 2018, Bulletin of Engineering Geology and the Environment.

[6]  Cem Şensöğüt,et al.  Measurement and mathematical modelling of the creep behaviour of Tuzköy rock salt , 2014 .

[7]  Chengzhi Qi,et al.  A micro-macro dynamic compressive-shear fracture model under static confining pressure in brittle rocks , 2018, International Journal of Impact Engineering.

[8]  Jie Chen,et al.  A nonlinear creep damage model for salt rock , 2018, International Journal of Damage Mechanics.

[9]  G. E. Motta,et al.  New constitutive equation for salt rock creep , 2014 .

[10]  Shaofeng Liu,et al.  Supply Chain Coordination under Trade Credit and Quantity Discount with Sales Effort Effects , 2018 .

[11]  D. Roehl,et al.  An assessment of the creep behaviour of Brazilian salt rocks using the multi-mechanism deformation model , 2016 .

[12]  S. Ahmad,et al.  Creep crack simulations using continuum damage mechanics and extended finite element method , 2019 .

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

[14]  R. Ajalloeian,et al.  Mechanical behavior of salt rock under uniaxial compression and creep tests , 2018, International Journal of Rock Mechanics and Mining Sciences.

[15]  Jianxun Chen,et al.  Investigation Progresses and Applications of Fractional Derivative Model in Geotechnical Engineering , 2016 .

[16]  P. Fan,et al.  A Variable-Parameter Creep Damage Model Incorporating the Effects of Loading Frequency for Rock Salt and Its Application in a Bedded Storage Cavern , 2017, Rock Mechanics and Rock Engineering.

[17]  Aditya Singh,et al.  Estimation of creep parameters of rock salt from uniaxial compression tests , 2018, International Journal of Rock Mechanics and Mining Sciences.

[18]  K. Nishimoto,et al.  Potential of storing gas with high CO 2 content in salt caverns built in ultra‐deep water in Brazil , 2018, Greenhouse Gases: Science and Technology.

[19]  Ping Cao,et al.  Study on nonlinear damage creep constitutive model for high-stress soft rock , 2016, Environmental Earth Sciences.

[20]  D. Krajcinovic,et al.  A Mesomechanical Model for Brittle Deformation Processes: Part II , 1989 .

[21]  Chao Yang,et al.  A Nonlinear Creep Damage Model of Layered Rock under Unloading Condition , 2018 .

[22]  Xiangqiao Yan,et al.  A new model of multiaxial fatigue life prediction with the influence of different mean stresses , 2019, International Journal of Damage Mechanics.

[23]  Fumio Koyama,et al.  The challenges involved in concrete works of Marmaray immersed tunnel with service life beyond 100 years , 2009 .

[24]  Guo-yu Li,et al.  Effect of freeze-thaw cycles in mechanical behaviors of frozen loess , 2018 .

[26]  Leon Mishnaevsky,et al.  A fractional derivative approach to full creep regions in salt rock , 2013 .

[27]  Feng Gao,et al.  Thermo-mechanical coupling damage constitutive model of rock based on the Hoek–Brown strength criterion , 2018 .

[28]  Xiuling Wang,et al.  Extreme deformation characteristics and countermeasures for a tunnel in difficult grounds in southern Shaanxi, China , 2018, Environmental Earth Sciences.

[29]  R. Chalaturnyk,et al.  Parametric assessment of salt cavern performance using a creep model describing dilatancy and failure , 2015 .

[30]  Lei Zhang,et al.  Experimental investigations of the creep–damage–rupture behaviour of rock salt , 2014 .

[31]  Yun-hai Wang,et al.  Changing regularity of rock damage variable and resistivity under loading condition , 2012 .

[32]  C. Qiao,et al.  Composite damage constitutive model of jointed rock mass considering crack propagation length and joint friction effect , 2018, Arabian Journal of Geosciences.

[33]  Jun Wang,et al.  An improved Maxwell creep model for rock based on variable-order fractional derivatives , 2015, Environmental Earth Sciences.

[34]  Z. Shao,et al.  A unified analytical method calculating brittle rocks deformation induced by crack growth , 2019, International Journal of Rock Mechanics and Mining Sciences.

[35]  Yanlong Chen,et al.  A Nonlinear Creep Damage Coupled Model for Rock Considering the Effect of Initial Damage , 2018, Rock Mechanics and Rock Engineering.

[36]  M. Ganjiani A thermodynamic consistent rate-dependent elastoplastic-damage model , 2018 .

[37]  Rong-kun Pan,et al.  The inducement of coal spontaneous combustion disaster and control technology in a wide range of coal mine closed area , 2018, Environmental Earth Sciences.

[38]  M. Dąbrowski,et al.  Nonlinear Viscoelastic Closure of Salt Cavities , 2018, Rock Mechanics and Rock Engineering.

[39]  J. Daemen,et al.  Discontinuous fatigue of salt rock with low-stress intervals , 2019, International Journal of Rock Mechanics and Mining Sciences.

[40]  H. Liu,et al.  A dynamic damage constitutive model for a rock mass with non-persistent joints under uniaxial compression , 2016 .

[41]  Analysis of viscoelastic behaviour of rock salt using hydraulic cylinder test , 2015, Bulletin of Engineering Geology and the Environment.

[42]  Yong Li,et al.  Mesomechanics coal experiment and an elastic-brittle damage model based on texture features , 2017, International Journal of Mining Science and Technology.

[43]  S. Penna,et al.  Discontinuous failure in micropolar elastic-degrading models , 2017 .

[44]  Xinrong Liu,et al.  A Nonlinear Creep Model of Rock Salt and Its Numerical Implement in FLAC3D , 2015 .

[45]  S. R. Bodner,et al.  A Damage Mechanics Treatment of Creep Failure in Rock Salt , 1997 .

[46]  Z. Song,et al.  Deformation behaviors and meso–structure characteristics variation of the weathered soil of Pisha sandstone caused by freezing–thawing effect , 2019, Cold Regions Science and Technology.

[47]  Zhang Yan,et al.  Experimental investigation on creep behavior of clastic rock , 2020, E3S Web of Conferences.

[48]  R. Habibi An investigation into design concepts, design methods and stability criteria of salt caverns , 2019, Oil & Gas Science and Technology – Revue d’IFP Energies nouvelles.

[49]  Hossein Salari-Rad,et al.  A study on the effect of utilizing different constitutive models in the stability analysis of an underground gas storage within a salt structure , 2016 .

[50]  D. Jiang,et al.  Comparison of the characteristics of rock salt exposed to loading and unloading of confining pressures , 2016 .

[51]  M. Cai,et al.  A damage model for modeling the complete stress–strain relations of brittle rocks under uniaxial compression , 2018 .

[52]  D. Jiang,et al.  Self-healing capacity of damaged rock salt with different initial damage , 2018 .

[53]  T. Popp,et al.  Steady-State Creep of Rock Salt: Improved Approaches for Lab Determination and Modelling , 2015, Rock Mechanics and Rock Engineering.

[54]  D. Jiang,et al.  Physical simulation of construction and control of two butted-well horizontal cavern energy storage using large molded rock salt specimens , 2019, Energy.

[55]  ST Nguyen,et al.  Generalized Maxwell model for micro-cracked viscoelastic materials , 2017, International Journal of Damage Mechanics.

[56]  Jinxing Lai,et al.  Response characteristics and preventions for seismic subsidence of loess in Northwest China , 2018, Natural Hazards.

[57]  L. Lankof,et al.  Potential capacity of gas storage caverns in rock salt bedded deposits in Poland , 2017 .

[58]  A. Pouya,et al.  Micro-Macro Analysis and Phenomenological Modelling of Salt Viscous Damage and Application to Salt Caverns , 2015, Rock Mechanics and Rock Engineering.

[59]  Majidreza Nazem,et al.  Assessing the effects of rock mass gradual deterioration on the long-term stability of abandoned mine workings and the mechanisms of post-mining subsidence – A case study of Castle Fields mine , 2019, Tunnelling and Underground Space Technology.

[60]  Guo-yu Li,et al.  Multiaxial creep of frozen loess , 2016 .

[61]  J. Shao,et al.  Experimental investigation of creep behavior of clastic rock in Xiangjiaba Hydropower Project , 2015 .

[62]  Dusan Krajcinovic,et al.  Statistical aspects of the continuous damage theory , 1982 .

[63]  Weijun Wang,et al.  Separation of Elastoviscoplastic Strains of Rock and a Nonlinear Creep Model , 2018 .