Sage Journals: Discover world-class research

Abstract

Stress-induced instability is associated with rock damage. Here, the progressive brittle fracturing process in Jinping marble is studied by introducing two types of true triaxial pre-peak unloading tests, namely, the incrementally cyclic loading-unloading minimum principal stress test (ICM test) and the incrementally cyclic loading-unloading maximum and minimum principal stress test (ICMM test). By comprehensively analysing the irreversible strains, dissipated energy, acoustic emission (AE) characteristics and scanning electron microscopy (SEM) results, the rock damage evolution can be quantified and divided into two distinctive damage stages. At the boundary point, the irreversible strain increments reach their minimum values. In the gentle damage stage, the normalized irreversible strains increase linearly, and this process is associated with a small number of AE hits with low amplitude. The rapid damage stage is characterized by a nonlinear increase in the normalized irreversible strains, and this process is associated with a large number of AE hits with high amplitude. The dissipated energy mainly increases in the rapid damage stage. In addition, the rapid damage stage in the ICMM test mainly occurs in the last five cycles, due to the differences in the deviatoric stresses in each cycle. In both of these tests, the failure mode is principally characterized by tensile failure. Moreover, the precursory signals of rock fracturing and the influence of the loading paths on the strength are discussed.

Keywords

True triaxial pre-peak unloading test damage evolution irreversible strains dissipated energy acoustic emission

Get full access to this article

View all access options for this article.

References

Al-Ajmi

Zimmerman

(2005) Relation between the Mogi and the Coulomb failure criteria. International Journal of Rock Mechanics and Mining Sciences 42(3): 431–439.

Brace

Paulding

Scholz

(1966) Dilatancy in the fracture of crystalline rocks. Journal of Geophysical Research 71(16): 3939–3953.

Cai

(2008) Influence of intermediate principal stress on rock fracturing and strength near excavation boundaries – Insight from numerical modeling. International Journal of Rock Mechanics and Mining Sciences 45(5): 763–772.

Carpinteri

Lacidogna

Corrado

, et al. (2016) Cracking and crackling in concrete-like materials: A dynamic energy balance. Engineering Fracture Mechanics 155: 130–144.

Chang

Haimson

(2012) A failure criterion for rocks based on true triaxial testing. Rock Mechanics and Rock Engineering 45(6): 1007–1010.

Diederichs

Kaiser

Eberhardt

(2004) Damage initiation and propagation in hard rock during tunnelling and the influence of near-face stress rotation. International Journal of Rock Mechanics and Mining Sciences 41(5): 785–812.

Tao

, et al. (2016) Experimental study of slabbing and rockburst induced by true-triaxial unloading and local dynamic disturbance. Rock Mechanics and Rock Engineering 49(9): 3437–3417.

Eberhardt

Stead

Stimpson

, et al. (1998) Identifying crack initiation and propagation thresholds in brittle rock. Canadian Geotechnical Journal 35(2): 222–233.

Eberhardt

Stead

Stimpson

(1999) Quantifying progressive pre-peak brittle fracture damage in rock during uniaxial compression. International Journal of Rock Mechanics and Mining Sciences 36(3): 361–380.

10.

Feng

, et al. (2016a) Comprehensive field monitoring of deep tunnels at Jinping underground laboratory (CJPL-II) in China. Chinese Journal of Rock Mechanics and Engineering 4: 649–657.

11.

Feng

Qiu

, et al. (2018) In situ observation of rock spalling in the deep tunnels of the China Jinping underground laboratory (2400 m depth). Rock Mechanics and Rock Engineering 51(4): 1193–1213.

12.

Feng

Yang

, et al. (2020) Influence of loading and unloading stress paths on the deformation and failure features of Jinping marble under true triaxial compression. Rock Mechanics and Rock Engineering 53(7): 3287–3301.

13.

Feng

(2010) Damage micromechanics for constitutive relations and failure of microcracked quasi-brittle materials. International Journal of Damage Mechanics 19(8): 911–948.

14.

Feng

Zhang

Kong

, et al. (2016b) A novel Mogi type true triaxial testing apparatus and its use to obtain complete stress–strain curves of hard rocks. Rock Mechanics and Rock Engineering 49(5): 1649–1662.

15.

Feng

Zhang

Yang

, et al. (2017) Evaluation and reduction of the end friction effect in true triaxial tests on hard rocks. International Journal of Rock Mechanics and Mining Sciences 97: 144–148.

16.

Gao

Feng

(2019) Study on damage evolution of intact and jointed marble subjected to cyclic true triaxial loading. Engineering Fracture Mechanics 215: 224–234.

17.

Gao

Feng

Zhang

, et al. (2018) Characteristic stress levels and brittle fracturing of hard rocks subjected to true triaxial compression with low minimum principal stress. Rock Mechanics and Rock Engineering 51(12): 3681–3697.

18.

Gao

Zhang

Roe

(2010) A study on the effect of the stress state on ductile fracture. International Journal of Damage Mechanics 19(1): 75–94.

19.

Haimson

(2007) Micromechanisms of borehole instability leading to breakouts in rocks. International Journal of Rock Mechanics and Mining Sciences 44(2): 157–173.

20.

Miao

Feng

(2010) Rock burst process of limestone and its acoustic emission characteristics under true-triaxial unloading conditions. International Journal of Rock Mechanics and Mining Sciences 47(2): 286–298.

21.

Iturrioz

Lacidogna

Carpinteri

(2014) Acoustic emission detection in concrete specimens: Experimental analysis and lattice model simulations. International Journal of Damage Mechanics 23(3): 327–358.

22.

Yuan

Kuo

(2012) Novel strain energy based coupled elastoplastic damage and healing models for geomaterials – Part I: Formulations. International Journal of Damage Mechanics 21(4): 525–549.

23.

Kong

Feng

Zhang

, et al. (2018) Study on crack initiation and damage stress in sandstone under true triaxial compression. International Journal of Rock Mechanics and Mining Sciences 106: 117–123.

24.

Cao

Shen

, et al. (2018) A damage model of mechanical behavior of porous materials: Application to sandstone. International Journal of Damage Mechanics 27(9): 1325–1351.

25.

(2015) True triaxial strength and failure modes of cubic rock specimens with unloading the minor principal stress. Rock Mechanics and Rock Engineering 48(6): 2185–2196.

26.

Feng

, et al. (2012) In situ monitoring of rockburst nucleation and evolution in the deeply buried tunnels of Jinping II hydropower station. Engineering Geology 137-138(7): 85–96.

27.

Liang

, et al. (2017) Mechanical and acoustic emission characteristics of rock: Effect of loading and unloading confining pressure at the postpeak stage. Journal of Natural Gas Science and Engineering 44: 54–64.

28.

Liu

Cai

(2018) A damage model for modeling the complete stress–strain relations of brittle rocks under uniaxial compression. International Journal of Damage Mechanics 27(7): 1000–1019.

29.

Liu

(2015) Analysis on damage mechanical characteristics of marble exposed to high temperature. International Journal of Damage Mechanics 24(8): 1180–1193.

30.

Lockner

Byerlee

Kuksenko

, et al. (1991) Quasi-static fault growth and shear fracture energy in granite. Nature 350(6313): 39–42.

31.

Martin

Chandler

(1994) The progressive fracture of Lac du bonnet granite. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts 31(6): 643–659.

32.

Mogi

(1972) Effect of the triaxial stress system on fracture and flow of rocks. Physics of the Earth and Planetary Interiors 5: 318–324.

33.

Ortlepp

Stacey

(1994) Rockburst mechanisms in tunnels and shafts. Tunnelling and Underground Space Technology 9(1): 59–65.

34.

Qiu

Feng

Xiao

, et al. (2014) An experimental study on the pre-peak unloading damage evolution of marble. Rock Mechanics and Rock Engineering 47(2): 401–419.

35.

Chen

Woody Ju

, et al. (2019) Experimental study of the dynamically induced rockburst of a rock wall with double free faces. International Journal of Damage Mechanics 28(4): 611–637.

36.

Tiwari

Rao

(2007) Response of an anisotropic rock mass under polyaxial stress state. Journal of Materials in Civil Engineering 19(5): 393–403.

37.

Zhao

Feng

Zhang

, et al. (2018) Brittle-ductile transition and failure mechanism of Jinping marble under true triaxial compression. Engineering Geology 232: 160–170.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.37 MB

Experimental study on the damage process of marble under true triaxial pre-peak unloading conditions

Abstract

Keywords

Get full access to this article

References

Supplementary Material