Tunnel failure in hard rock with multiple weak planes due to excavation unloading of in-situ stress

Shao-jie Chen; Fan Feng; Ya-jun Wang; Di-yuan Li; Wan-peng Huang; Xing-dong Zhao; Ning Jiang

doi:10.1007/s11771-020-4515-7

Journal of Central South University ›› 2020, Vol. 27 ›› Issue (10) : 2864 -2882. DOI: 10.1007/s11771-020-4515-7

Article

Tunnel failure in hard rock with multiple weak planes due to excavation unloading of in-situ stress

Author information +

History +

PDF

Abstract

Natural geological structures in rock (e.g., joints, weakness planes, defects) play a vital role in the stability of tunnels and underground operations during construction. We investigated the failure characteristics of a deep circular tunnel in a rock mass with multiple weakness planes using a 2D combined finite element method/discrete element method (FEM/DEM). Conventional triaxial compression tests were performed on typical hard rock (marble) specimens under a range of confinement stress conditions to validate the rationale and accuracy of the proposed numerical approach. Parametric analysis was subsequently conducted to investigate the influence of inclination angle, and length on the crack propagation behavior, failure mode, energy evolution, and displacement distribution of the surrounding rock. The results show that the inclination angle strongly affects tunnel stability, and the failure intensity and damage range increase with increasing inclination angle and then decrease. The dynamic disasters are more likely with increasing weak plane length. Shearing and sliding along multiple weak planes are also consistently accompanied by kinetic energy fluctuations and surges after unloading, which implies a potentially violent dynamic response around a deeply-buried tunnel. Interactions between slabbing and shearing near the excavation boundaries are also discussed. The results presented here provide important insight into deep tunnel failure in hard rock influenced by both unloading disturbance and tectonic activation.

Keywords

rock tunnel / weak planes / excavation unloading / crack propagation / energy evolution / finite element method/discrete element method (FEM/DEM)

Cite this article

Download citation ▾

Shao-jie Chen, Fan Feng, Ya-jun Wang, Di-yuan Li, Wan-peng Huang, Xing-dong Zhao, Ning Jiang. Tunnel failure in hard rock with multiple weak planes due to excavation unloading of in-situ stress. Journal of Central South University, 2020, 27(10): 2864-2882 DOI:10.1007/s11771-020-4515-7

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	CHEN Jun-tao, ZHAO Jin-hai, ZHANG Shi-chuan, ZHANG Yi, YANG Fan, LI Ming. An experimental and analytical research on the evolution of mining cracks in deep floor rock mass [J]. Pure and Applied Geophysics, 2020. DOI: https://doi.org/10.1007/s00024-020-02550-9.

[2]	CaiM, KaiserP K. In-situ rock spalling strength near excavation boundaries [J]. Rock Mechanics and Rock Engineering, 2014, 47(2): 659-675

[3]	FengF, LiX-B, RostamiJ, PengD-X, LiD-Y, DuK. Numerical investigation of hard rock strength and fracturing under polyaxial compression based on mogi-coulomb failure criterion [J]. International Journal of Geomechanics, 2019, 19(4): 04019005

[4]	FengF, ChenS-J, LiD-Y, HuS-T, HuangW-P, LiB. Analysis of fractures of a hard rock specimen via unloading of central hole with different sectional shapes [J]. Energy Science & Engineering, 2019, 762265-2286

[5]	GuX-B, GuoW-Y, ZhaoT-B, ShenB-T, ZhangD-X. Biaxial physical simulation test of rock burst in circular tunnel under influence of lateral pressure [J]. Journal of Shandong University of Science and Technology (Natural Science), 2020, 39(1): 46-52(in Chinese)

[6]	LuoY, GongF-Q, LiX-B, WangS-Y. Experimental simulation investigation of influence of depth on spalling characteristics in circular hard rock tunnel [J]. Journal of Central South University, 2020, 27(3): 891-910

[7]	ZhaoZ-H, TanY-L, ChenS-J, MaQ, GaoX-J. Theoretical analyses of stress field in surrounding rocks of weakly consolidated tunnel in a high-humidity deep environment [J]. International Journal of Rock Mechanics and Mining Sciences, 2019, 122: 104064

[8]	LiX-B, CaoW-Z, ZhouZ-L, ZouY. Influence of stress path on excavation unloading response [J]. Tunnelling and Underground Space Technology, 2014, 42237-246

[9]	LiX-B, GongF-Q, TaoM, DongL-J, DuK, MaC-D, ZhouZ-L, YinT-B. Failure mechanism and coupled static-dynamic loading theory in deep hard rock mining: A review [J]. Journal of Rock Mechanics and Geotechnical Engineering, 2017, 9(4): 767-782

[10]	QinZ-C, ChenG-B, LiT, SunW, FuB. Experimental study on determining “key strata of energy” of rock burst [J]. Journal of Shandong University of Science and Technology (Natural Science), 2018, 37(6): 1-10(in Chinese)

[11]	VernikL, ZobackM D. Estimation of maximum horizontal principal stress magnitude from stress-induced well bore breakouts in the Cajon Pass Scientific Research borehole [J]. Journal of Geophysical Research: Solid Earth, 1992, 97(B4): 5109-5119

[12]	HuangW P, LiC, ZhangL W, YuanQ, ZhengY S, LiuY. In situ identification of water-permeable fractured zone in overlying composite strata [J]. International Journal of Rock Mechanics and Mining Sciences, 2018, 105: 85-97

[13]	PengK, LiuZ-P, ZouQ-L, ZhangZ-Y, ZhouJ-Q. Static and dynamic mechanical properties of granite from various burial depths [J]. Rock Mechanics and Rock Engineering, 2019, 52(10): 3545-3566

[14]	LiX-BRock dynamics fundamentals and applications [M], 2014, Beijing, Science Press

[15]	LiX-B, ZhouZ-L, LokT-S, HongL, YinT-B. Innovative testing technique of rock subjected to coupled static and dynamic loads [J]. International Journal of Rock Mechanics and Mining Sciences, 2008, 45(5): 739-748

[16]	FengF, LiX-B, RostamiJ, LiD-Y. Modeling hard rock failure induced by structural planes around deep circular tunnels [J]. Engineering Fracture Mechanics, 2019, 205: 152-174

[17]	JiaP, ZhuW-C. Dynamic-static coupling analysis on rockburst mechanism in jointed rock mass [J]. Journal of Central South University, 2012, 19(11): 3285-3290

[18]	ChenM, YangS-Q, RanjithP G, ZhangY-C. Cracking behavior of rock containing nonpersistent joints with various joints inclinations [J]. Theoretical and Applied Fracture Mechanics, 2020, 109: 102701

[19]	SnellingP E, GodinL, MckinnonS D. The role of geologic structure and stress in triggering remote seismicity in Creighton Mine, Sudbury, Canada [J]. International Journal of Rock Mechanics and Mining Sciences, 2013, 58166-179

[20]	LiuG-F, FengX-T, JiangQ, YaoZ-B, LiS-J. In situ observation of spalling process of intact rock mass at large cavern excavation [J]. Engineering Geology, 2017, 226: 52-69

[21]	LiX-B, FengF, LiD-Y. Numerical simulation of rock failure under static and dynamic loading by splitting test of circular ring [J]. Engineering Fracture Mechanics, 2018, 188: 184-201

[22]	FengX-T, XuH, QiuS-L, LiS-J, YangC-X, GuoH-S, ChengY, GaoY-H. In situ observation of rock spalling in the deep tunnels of the China Jinping underground laboratory (2400 m depth) [J]. Rock Mechanics and Rock Engineering, 2018, 51(4): 1193-1213

[23]	KonicekP, SchreiberJ. Heavy rockbursts due to longwall mining near protective Pillars: A case study [J]. International Journal of Mining Science and Technology, 2018, 28(5): 799-805

[24]	LiX-B, FengF, LiD-Y, DuK, RanjithP G, RostamiJ. Failure characteristics of granite influenced by sample height-to-width ratios and intermediate principal stress under true-triaxial unloading conditions [J]. Rock Mechanics and Rock Engineering, 2018, 51(5): 1321-1345

[25]	SepehriM, ApelD B, AdeebS, LeveilleP, HallR A. Evaluation of mining-induced energy and rockburst prediction at a diamond mine in Canada using a full 3D elastoplastic finite element model [J]. Engineering Geology, 2020, 266: 105457

[26]	ZhangC-Q, FengX-T, ZhouH, QiuS-L, WuW-P. Rockmass damage development following two extremely intense rockbursts in deep tunnels at Jinping II hydropower station, southwestern China [J]. Bulletin of Engineering Geology and the Environment, 2013, 72(2): 237-247

[27]	ZhouH, MengF-Z, ZhangC-Q, HuD-W, YangF-J, LuJ-J. Analysis of rockburst mechanisms induced by structural planes in deep tunnels [J]. Bulletin of Engineering Geology and the Environment, 2015, 74(4): 1435-1451

[28]	ChalivendraV B, HongS, AriasI, KnapJ, RosakisA, OrtizM. Experimental validation of large-scale simulations of dynamic fracture along weak planes [J]. International Journal of Impact Engineering, 2009, 36(7): 888-898

[29]	HuangF, ZhuH-H, XuQ-W, CaiY-C, ZhuangX-Y. The effect of weak interlayer on the failure pattern of rock mass around tunnel — Scaled model tests and numerical analysis [J]. Tunnelling and Underground Space Technology, 2013, 35207-218

[30]	YangS-Q, YinP-F, ZhangY-C, ChenM, ZhouX-P, JingH-W, ZhangQ-Y. Failure behavior and crack evolution mechanism of a non-persistent jointed rock mass containing a circular hole [J]. International Journal of Rock Mechanics and Mining Sciences, 2019, 114: 101-121

[31]	ChenM-L, JingH-W, MaX-J, SuH-J, DuM-R, ZhuT-T. Fracture evolution characteristics of sandstone containing double fissures and a single circular hole under uniaxial compression [J]. International Journal of Mining Science and Technology, 2017, 27(3): 499-505

[32]	LiuX-R, YangS-Q, HuangY-H, ChengJ-L. Experimental study on the strength and fracture mechanism of sandstone containing elliptical holes and fissures under uniaxial compression [J]. Engineering Fracture Mechanics, 2019, 205: 205-217

[33]	YangY, ZhangZ-N. Dynamic fracturing process of fissured rock under abrupt unloading condition: A numerical study [J]. Engineering Fracture Mechanics, 2020, 231: 107025

[34]	ManouchehrianA, CaiM. Analysis of rockburst in tunnels subjected to static and dynamic loads [J]. Journal of Rock Mechanics and Geotechnical Engineering, 2017, 9(6): 1031-1040

[35]	ManouchehrianA, CaiM. Numerical modeling of rockburst near fault zones in deep tunnels [J]. Tunnelling and Underground Space Technology, 2018, 80164-180

[36]	ElmoD, SteadD, EberhardtE, VyazmenskyA. Applications of finite/discrete element modeling to rock engineering problems [J]. International Journal of Geomechanics, 2013, 13(5): 565-580

[37]	HamdiP, SteadD, ElmoD. Damage characterization during laboratory strength testing: a 3D-finite-discrete element approach [J]. Computers and Geotechnics, 2014, 60: 33-46

[38]	LiX-Y, KimE, WaltonG. A study of rock pillar behaviors in laboratory and in situ scales using combined finite-discrete element method models [J]. International Journal of Rock Mechanics and Mining Sciences, 2019, 118: 21-32

[39]	YanC-Z, ZhengH, SunG-H, GeX-R. Combined finite-discrete element method for simulation of hydraulic fracturing [J]. Rock Mechanics and Rock Engineering, 2016, 49(4): 1389-1410

[40]	ZhangC-Q, FengX-T, ZhouH, QiuS-L, WuW-P. Case histories of four extremely intense rockbursts in deep tunnels [J]. Rock Mechanics and Rock Engineering, 2012, 45(3): 275-288

[41]	HajiabdolmajidV, KaiserP K, MartinC D. Modelling brittle failure of rock [J]. International Journal of Rock Mechanics and Mining Sciences, 2002, 39(6): 731-741

[42]	CaiM. Fracture initiation and propagation in a Brazilian disc with a plane interface: a numerical study [J]. Rock Mechanics and Rock Engineering, 2013, 46(2): 289-302

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

[44]	MitelmanA, deE D. Analysis of tunnel support design to withstand spalling induced by blasting [J]. Tunnelling and Underground Space Technology, 2016, 51: 354-361

[45]	ZhangZ X. An empirical relation between mode I fracture toughness and the tensile strength of rock [J]. International Journal of Rock Mechanics and Mining Sciences, 2002, 39(3): 401-406

[46]	LiD-Y, LiC C, LiX-B. Influence of sample height-to-width ratios on failure mode for rectangular prism samples of hard rock loaded in uniaxial compression [J]. Rock Mechanics and Rock Engineering, 2011, 44(3): 253-267

[47]	EichhublP, HookerJ N, LaubachS E. Pure and shear-enhanced compaction bands in Aztec Sandstone [J]. Journal of Structural Geology, 2010, 32(12): 1873-1886

[48]	MaX D, RudnickiJ W, HaimsonB C. Failure characteristics of two porous sandstones subjected to true triaxial stresses: Applied through a novel loading path [J]. Journal of Geophysical Research: Solid Earth, 2017, 122(4): 2525-2540

[49]	PatersonM S. Experimental deformation and faulting in wombeyan marble [J]. Geological Society of America Bulletin, 1958, 69(4): 465-476

[50]	MogiKExperimental rock mechanics[M], 2007, London, CRC Press

[51]	HoekE, BrownE T. Practical estimates of rock mass strength [J]. International Journal of Rock Mechanics and Mining Sciences, 1997, 34(8): 1165-1186

[52]	GongF-Q, SiX-F, LiX-B, WangS-Y. Experimental investigation of strain rockburst in circular Caverns under deep three-dimensional high-stress conditions [J]. Rock Mechanics and Rock Engineering, 2019, 52(5): 1459-1474

[53]	SiX-F, GongF-Q. Strength-weakening effect and shear-tension failure mode transformation mechanism of rockburst for fine-grained granite under triaxial unloading compression [J]. International Journal of Rock Mechanics and Mining Sciences, 2020, 131104347

[54]	JiangB-Y, GuS-T, WangL-G, ZhangG-C, LiW-S. Strainburst process of marble in tunnel-excavation-induced stress path considering intermediate principal stress [J]. Journal of Central South University, 2019, 26(4): 984-999

[55]	WongR H C, TangC A, ChauK T, LinP. Splitting failure in brittle rocks containing pre-existing flaws under uniaxial compression [J]. Engineering Fracture Mechanics, 2002, 69(17): 1853-1871