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Rock Mechanics and Rock Engineering

Erschienen in:

25.03.2016 | Original Paper

Investigation of Macroscopic Brittle Creep Failure Caused by Microcrack Growth Under Step Loading and Unloading in Rocks

verfasst von: Xiaozhao Li, Zhushan Shao

Erschienen in: Rock Mechanics and Rock Engineering | Ausgabe 7/2016

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Abstract

The growth of subcritical cracks plays an important role in the creep of brittle rock. The stress path has a great influence on creep properties. A micromechanics-based model is presented to study the effect of the stress path on creep properties. The microcrack model of Ashby and Sammis, Charles’ Law, and a new micro–macro relation are employed in our model. This new micro–macro relation is proposed by using the correlation between the micromechanical and macroscopic definition of damage. A stress path function is also introduced by the relationship between stress and time. Theoretical expressions of the stress–strain relationship and creep behavior are derived. The effects of confining pressure on the stress–strain relationship are studied. Crack initiation stress and peak stress are achieved under different confining pressures. The applied constant stress that could cause creep behavior is predicted. Creep properties are studied under the step loading of axial stress or the unloading of confining pressure. Rationality of the micromechanics-based model is verified by the experimental results of Jinping marble. Furthermore, the effects of model parameters and the unloading rate of confining pressure on creep behavior are analyzed. The coupling effect of step axial stress and confining pressure on creep failure is also discussed. The results provide implications on the deformation behavior and time-delayed rockburst mechanism caused by microcrack growth on surrounding rocks during deep underground excavations.

Vorheriger Artikel Time-Dependent Behaviors of Granite: Loading-Rate Dependence, Creep, and Relaxation

Nächster Artikel Determination of the Geotechnical Characteristics of Hornfelsic Rocks with a Particular Emphasis on the Correlation Between Physical and Mechanical Properties

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Ashby MF, Hallam SD (1986) The failure of brittle solids containing small cracks under compressive stress states. Acta Metall 34(3):497–510CrossRef

Ashby MF, Sammis CG (1990) The damage mechanics of brittle solids in compression. Pure Appl Geophys 133(3):489–521CrossRef

Atkinson BK (1979) A fracture mechanics study of subcritical tensile cracking of quartz in wet environments. Pure Appl Geophys 117(5):1011–1024CrossRef

Atkinson BK (1984) Subcritical crack growth in geological materials. J Geophys Res 89(B6):4077–4114CrossRef

Aydan Ö, Ito T, Özbay U, Kwasniewski M, Shariar K, Okuno T, Özgenoğlu A, Malan DF, Okada T (2014) ISRM suggested methods for determining the creep characteristics of rock. Rock Mech Rock Eng 47(1):275–290CrossRef

Baud P, Meredith PG (1997) Damage accumulation during triaxial creep of darley dale sandstone from pore volumometry and acoustic emission. Int J Rock Mech Min Sci 34(3–4):24.e1–24.e10

Bellenger E, Bussy P (2001) Phenomenological modeling and numerical simulation of different modes of creep damage evolution. Int J Solids Struct 38(4):577–604CrossRef

Bhat HS, Sammis CG, Rosakis AJ (2011) The micromechanics of Westerley granite at large compressive loads. Pure Appl Geophys 168(12):2181–2198CrossRef

Boukharov GN, Chanda MW, Boukharov NG (1995) The three processes of brittle crystalline rock creep. Int J Rock Mech Min Geomech Abstr 32(4):325–335CrossRef

Brantut N, Baud P, Heap MJ, Meredith PG (2012) Micromechanics of brittle creep in rocks. J Geophys Res 117:B08412CrossRef

Bristow JR (1960) Microcracks, and the static and dynamic elastic constants of annealed and heavily cold-worked metals. Br J Appl Phys 11(2):81–85CrossRef

Challamel N, Lanos C, Casandjian C (2005) Creep damage modelling for quasi-brittle materials. Eur J Mech A Solids 24(4):593–613CrossRef

Chandler NA (2013) Quantifying long-term strength and rock damage properties from plots of shear strain versus volume strain. Int J Rock Mech Min Sci 59:105–110

Charles RJ (1958) Static fatigue of glass. I. J Appl Phys 29(11):1549–1553CrossRef

Chen ZH, Tang CA, Huang RQ (1997) A double rock sample model for rockbursts. Int J Rock Mech Min Sci 34(6):991–1000CrossRef

Costin LS (1985) Damage mechanics in the post-failure regime. Mech Mat 4(2):149–160CrossRef

Cruden DM (1970) A theory of brittle creep in rock under uniaxial compression. J Geophys Res 75(17):3431–3442CrossRef

Damjanac B, Fairhurst C (2010) Evidence for a long-term strength threshold in crystalline rock. Rock Mech Rock Eng 43(5):513–531CrossRef

Deshpande VS, Evans AG (2008) Inelastic deformation and energy dissipation in ceramics: a mechanism-based constitutive model. J Mech Phys Solids 56(10):3077–3100CrossRef

Eslami J, Hoxha D, Grgic D (2012) Estimation of the damage of a porous limestone using continuous wave velocity measurements during uniaxial creep tests. Mech Mater 49:51–65CrossRef

Evans AG (1972) A method for evaluating the time-dependent failure characteristics of brittle materials—and its application to polycrystalline alumina. J Mater Sci 7(10):1137–1146CrossRef

Fabre G, Pellet F (2006) Creep and time-dependent damage in argillaceous rocks. Int J Rock Mech Min Sci 43(6):950–960CrossRef

Grgic D, Amitrano D (2009) Creep of a porous rock and associated acoustic emission under different hydrous conditions. J Geophys Res 114:B10201CrossRef

He MC, Miao JL, Feng JL (2010) Rock burst process of limestone and its acoustic emission characteristics under true-triaxial unloading conditions. Int J Rock Mech Min Sci 47(2):286–298CrossRef

He MC, Nie W, Zhao ZY, Guo W (2012) Experimental investigation of bedding plane orientation on the rockburst behavior of sandstone. Rock Mech Rock Eng 45(3):311–326CrossRef

Heap MJ, Baud P, Meredith PG, Bell AF, Main IG (2009) Time-dependent brittle creep in Darley Dale sandstone. J Geophys Res 114:B07203CrossRef

Heap MJ, Baud P, Meredith PG, Vinciguerra S, Bell AF, Main IG (2011) Brittle creep in basalt and its application to time-dependent volcano deformation. Earth Planet Sci Lett 307(1–2):71–82CrossRef

Jin F, Zhang CH, ASCE M, Wang G, Wang GL (2003) Creep modeling in excavation analysis of a high rock slope. J Geotech Geoenviron Eng 129(9):849–857CrossRef

Johnson LR, Sammis CG (2001) Effects of rock damage on seismic waves generated by explosions. Pure Appl Geophys 158(11):1869–1908CrossRef

Kachanov ML (1982) A microcrack model of rock inelasticity part II: propagation of microcracks. Mech Mater 1(1):29–41CrossRef

Kachanov LM (1986) Introduction to continuum damage mechanics. Martinus Nijhoff, DordrechtCrossRef

Kostrov VV (1974) Seismic moment and energy of earthquakes, and seismic flow of rock. Izv Acad Sci USSR Phys Solid Earth 1:23–44

Krajcinovic D (1983) Constitutive equations for damaging materials. J Appl Mech 50(2):355–360CrossRef

Kranz RL (1979) Crack growth and development during creep of Barre granite. Int J Rock Mech Min Sci Geomech Abstr 16(1):23–35CrossRef

Lacroix P, Amitrano D (2013) Long-term dynamics of rockslides and damage propagation inferred from mechanical modeling. J Geophys Res 118(4):2292–2307CrossRef

Lemaitre J, Plumtree A (1979) Application of damage concepts to predict creep-fatigue failures. J Eng Mater Technol 101(3):284–292CrossRef

Liu GT, Gao H, Chen FQ (2002) Microstudy on creep of concrete at early age under biaxial compression. Cem Concr Res 32(12):1865–1870CrossRef

Lockner D, Byerlee J (1977) Acoustic emission and creep in rock at high confining pressure and differential stress. B Seismol Soc Am 67(2):247–258

Ma L, Daemen JJK (2006) An experimental study on creep of welded tuff. Int J Rock Mech Min Sci 43(2):282–291CrossRef

Mallet C, Fortin J, Guéguen Y, Bouyer F (2014) Evolution of the crack network in glass samples submitted to brittle creep conditions. Int J Fract 190(1–2):111–124CrossRef

Mallet C, Fortin J, Guéguen Y, Bouyer F (2015) Brittle creep and subcritical crack propagation in glass submitted to triaxial conditions. J Geophys Res 120(2):879–893CrossRef

Martin CD, Chandler NA (1994) The progressive fracture of Lac du Bonnet granite. Int J Rock Mech Min Sci Geomech Abstr 31(6):643–659CrossRef

Miura K, Okui Y, Horii H (2003) Micromechanics-based prediction of creep failure of hard rock for long-term safety of high-level radioactive waste disposal system. Mech Mater 35(3):587–601CrossRef

Munson DE (1997) Constitutive model of creep in rock salt applied to underground room closure. Int J Rock Mech Min Sci 34(2):233–247CrossRef

Nara Y, Takada M, Mori D, Owada H, Yoneda T, Kaneko K (2010) Subcritical crack growth and long-term strength in rock and cementitious material. Int J Fract 164(1):57–71CrossRef

Nara Y, Yamanaka H, Oe Y, Kaneko K (2013) Influence of temperature and water on subcritical crack growth parameters and long-term strength for igneous rocks. Geophys J Int 193(1):47–60CrossRef

Ohnaka M (1983) Acoustic emission during creep of brittle rock. Int J Rock Mech Min Sci Geomech Abstr 20(3):121–134CrossRef

Ranaivomanana N, Multon S, Turatsinze A (2013) Tensile, compressive and flexural basic creep of concrete at different stress levels. Cem Concr Res 52:1–10CrossRef

Rice JR (1975) Continuum mechanics and thermodynamics of plasticity in relation to microscale deformation mechanisms. Constitutive equations in plasticity. Massachusetts Institute of Technology Press, Cambridge, pp 23–79

Scholz CH (1968) Mechanism of creep in brittle rock. J Geophys Res 73(10):3295–3302CrossRef

She CX, Cui X (2010) Influence of high pore water pressure on creep properties of rock. Chin J Rock Mech Eng 29(8):1603–1609

Singh DP (1975) A study of creep of rocks. Int J Rock Mech Min Sci Geomech Abstr 12(9):271–276CrossRef

Walsh JB (1965a) The effect of cracks on the compressibility of rock. J Geophys Res 70(2):381–389CrossRef

Walsh JB (1965b) The effect of cracks in rocks on Poisson’s ratio. J Geophys Res 70(20):5249–5257CrossRef

Wan LH, Cao P, Huang YH, Wang YX (2010) Study on subcritical crack growth of rocks and threshold values in different environments. Chin J Rock Soil Mech 31(9):2737–2742

Wang TJ, Lou ZW (1990) A continuum damage model for weld heat affected zone under low cycle fatigue loading. Eng Fract Mech 37(4):825–829CrossRef

Wang B, Zhu JB, Wu AQ, Hu JM, Xiong ZM (2008) Experimental study on mechanical properties of jinping marble under loading and unloading stress paths. Chin J Rock Mech Eng 27(10):2138–2145

Weibull W (1951) A statistical distribution function of wide applicability. J Appl Mech 18(2):293–297

Xia CC, Yan ZJ, Wang XD, Zhang CS, Zhao X (2009) Research on elasto-viscoplastic constitutive relation of marble under unloading condition. Chin J Rock Mech Eng 28(3):459–466

Yang C, Daemen JJK (1997) Temperature effects on creep of tuff and its time-dependent damage analysis. Int J Rock Mech Min Sci Geomech Abstr 34(3):383–384CrossRef

Yang W, Zhang Q, Li S, Wang S (2014) Time-dependent behavior of diabase and a nonlinear creep model. Rock Mech Rock Eng 47(4):1211–1224CrossRef

Zhang M, Li ZK, Su X (2005) Probabilistic volume element modeling in elastic damage analysis of quasi-brittle materials. Chin J Rock Mech Eng 24(23):4282–4288

Zhang ZL, Xu WY, Wang W, Wang RB (2012) Triaxial creep tests of rock from the compressive zone of dam foundation in Xiangjiaba Hydropower Station. Int J Rock Mech Min Sci 50:133–139CrossRef

Titel: Investigation of Macroscopic Brittle Creep Failure Caused by Microcrack Growth Under Step Loading and Unloading in Rocks
verfasst von: Xiaozhao Li
Zhushan Shao
Publikationsdatum: 25.03.2016
Verlag: Springer Vienna
Erschienen in: Rock Mechanics and Rock Engineering / Ausgabe 7/2016
Print ISSN: 0723-2632
Elektronische ISSN: 1434-453X
DOI: https://doi.org/10.1007/s00603-016-0953-9

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