Failure behavior around a circular opening in a rock mass with non-persistent joints: A parallel-bond stress corrosion approach

Xu-xu Yang; Hong-wen Jing; Kun-fu Chen; Sheng-qi Yang

doi:10.1007/s11771-017-3652-0

Journal of Central South University ›› 2017, Vol. 24 ›› Issue (10) : 2406 -2420. DOI: 10.1007/s11771-017-3652-0

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Failure behavior around a circular opening in a rock mass with non-persistent joints: A parallel-bond stress corrosion approach

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Abstract

The stability of underground excavations is influenced by discontinuities interspaced in surrounding rock masses as well as the stress condition. In this work, a numerical study was undertaken on the failure behavior around a circular opening in a rock mass having non-persistent open joints using PFC software package. A parallel-bond stress corrosion (PSC) approach was incorporated to drive the failure of rock mass around the circular opening, such that the whole progressive failure process after excavation was reproduced. Based on the determined micro parameters for intact material and joint segments, the failure process around the circular opening agrees very well with that obtained through laboratory experiment. A subsequent parametric study was then carried out to look into the influence of lateral pressure coefficient, joint dip angle and joint persistency on the failure pattern and crack evolution of the rock mass around the circular opening. Three failure patterns identified are step path failure, planar failure and rotation failure depending on the lateral pressure coefficient. Moreover, the increment of joint dip angle and joint persistency aggravates the rock mass failure around the opening. This study offers guideline on stability estimation of underground excavations.

Keywords

failure behavior / circular opening / non-persistent joint / PFC software package / stress corrosion

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Xu-xu Yang, Hong-wen Jing, Kun-fu Chen, Sheng-qi Yang. Failure behavior around a circular opening in a rock mass with non-persistent joints: A parallel-bond stress corrosion approach. Journal of Central South University, 2017, 24(10): 2406-2420 DOI:10.1007/s11771-017-3652-0

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References

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[1]	KulatilakeP H S W, MalamaB, WangJ L. Physical and particle flow modeling of jointed rock block behavior under uniaxial loading [J]. International Journal of Rock Mechanics and Mining Science, 2001, 38(5): 641-657

[2]	JiangQ, FengX T, HatzorY H, HaoX J, LiS J. Mechanical anisotropy of columnar jointed basalts: An example from the Baihetan hydropower station, China [J]. Engineering Geology, 2014, 175: 35-45

[3]	FortsakisP, NikasK, MarinosV, MarinosP. Anisotropic behavior of stratified rock masses in tunneling [J]. Engineering Geology, 2012, 141-142: 74-83

[4]	KimB H, KaiserP K, GrasselliG. Influence of persistence on behavior of fractured rock masses [J]. Geological Society, London, Special Publications, 2007, 284: 161-173

[5]	YangX X, KulatilakeP, HS W, ChenX, JingH W, YangS Q. Particle flow modeling of rock blocks with non-persistent open joints under uniaxial compression [J]. International Journal of Geomechanics, 2016, 16(6): 04016020

[6]	LajtaiE Z, LajtaiV N. The collapse of cavities [J]. International Journal of Rock Mechanics and Mining Science, 1975, 12: 81-86

[7]	LajtaiE Z, CarterB J, DuncanE J S. En echelon crack-arrays in potash salt rock [J]. Rock Mechanics and Rock Engineering, 1994, 27(2): 89-111

[8]	SagongM, ParkD, YooJ, LeeJ S. Experimental and numerical analyses of an opening in a jointed rock mass under biaxial compression [J]. International Journal of Rock Mechanics and Mining Science, 2011, 48(7): 1055-1067

[9]	WangS Y, SloanS W, TangC A, ZhuW C. Numerical simulation of the failure mechanism of circular tunnels in transversely isotropic rock masses [J]. Tunnelling and Underground Space Technology, 2012, 32231-244

[10]	WangT T, HuangT H. Anisotropic deformation of a circular tunnel excavated in a rock mass containing sets of ubiquitous joints: Theory analysis and numerical modeling [J]. Rock Mechanics and Rock Engineering, 2014, 47(2): 643-657

[11]	FakhimiA, CarvalhoF, IshidaT, LabuzJ F. Simulation of failure around a circular opening in rock [J]. International Journal of Rock Mechanics and Mining Science, 2002, 39: 507-515

[12]	LinP, WongR H C, TangC A. Experimental study of coalescence mechanism and failure under uniaxial compression of granite containing multiple holes [J]. International Journal of Rock Mechanics and Mining Science, 2015, 77: 313-327

[13]	WongR H C, LinP. Numerical study of stress distribution and crack coalescence mechanisms of a solid containing multiple holes [J]. International Journal of Rock Mechanics and Mining Science, 2015, 79: 41-54

[14]	JiaP, TangC A. Numerical study on failure mechanism of tunnel in jointed rock mass [J]. Tunnelling Underground Space Technology, 2008, 23(5): 500-507

[15]	WongR H C, LinP, YuZ X, TangC A, ChauK T. Creeping damage around an opening in rock-like material containing nonpersistent joints [J]. Engineering Fracture Mechanics, 2002, 69(17): 2015-2027

[16]	YangS Q, HuangY H, JingH W, LiuX R. Discrete element modeling on fracture coalescence behavior of red sandstone containing two unparallel fissures under uniaxial compression [J]. Engineering Geology, 2014, 178: 24-48

[17]	DingX B, ZhangL Y. A new contact model to improve the simulated ratio of unconfined compressive strength to tensile strength in bonded particle models [J]. International Journal of Rock Mechanics and Mining Science, 2014, 69: 111-119

[18]	ZhangY, SteadD. Modeling 3D crack propagation in hard rock pillars using a synthetic rock mass approach [J]. International Journal of Rock Mechanics and Mining Science, 2014, 72: 199-213

[19]	BahaaddiniM, SharrockG, HebblewhiteB K. Numerical investigation of the effect of joint geometrical parameters on the mechanical properties of a non-persistent jointed rock mass under uniaxial compression [J]. Computers and Geotechnics, 2013, 49: 206-225

[20]	FanX, KulatilakeP H S W, ChenX, CaoPing. Crack initiation stress and strain of jointed rock containing multi-cracks under uniaxial compressive loading: A particle flow code approach [J]. Journal of Central South University, 2015, 22: 638-645

[21]	YangX-x, KulatilakeP H S W, JingH-w, YangS-qi. Numerical simulation of a jointed rock block mechanical behavior adjacent to an underground excavation and comparison with physical model test results [J]. Tunnelling and Underground Space Technology, 2015, 50: 129-142

[22]	ChenW, KonietzkyH, Muntazir AbbasS. Numerical simulation of time-independent and dependent fracturing in sandstone [J]. Engineering Geology, 2015, 193: 118-131

[23]	PotyondyD O. Simulating stress corrosion with a bondedparticle model for rock [J]. International Journal of Rock Mechanics and Mining Science, 2007, 44: 677-691

[24]	Mas IvarsD, PierceM E, DarcelC, Reyes-MontesJ, PotyondyD O, YoungR P, CundallP A. The synthetic rock mass approach for jointed rock mass modeling [J]. International Journal of Rock Mechanics and Mining Science, 2011, 48(2): 219-244

[25]	Itasca Consulting Group Inc. PFC3D manual, version 4.0 [R]. Minneapolis, Minnesota, 2008.

[26]	PierceM, CundallP, PotyondyD O, Mas IvarsD. A synthetic rock mass model for jointed rock [C]//. Rock Mechanics: Meeting Society's Challenges and Demands, 2007341349

[27]	HoekE, BrownE TUnderground excavations in rock [M], 1980, London, Institution of Mining and Metallurgy

[28]	MartinC D, ReadR S, MartinoJ B. Observations of brittle failure around a circular test tunnel [J]. International Journal of Rock Mechanics and Mining Science, 1997, 34(7): 1063-1073