Mechanical response and stability analysis of rock mass in high geostress underground powerhouse caverns subjected to excavation

Biao Li; Quan-fu Ding; Nu-wen Xu; Yi-fan Lei; Yuan Xu; Zhong-ping Zhu; Jing-fei Liu

doi:10.1007/s11771-020-4522-8

Journal of Central South University ›› 2020, Vol. 27 ›› Issue (10) : 2971 -2984. DOI: 10.1007/s11771-020-4522-8

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Mechanical response and stability analysis of rock mass in high geostress underground powerhouse caverns subjected to excavation

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Abstract

To investigate the stability of rock mass in high geostress underground powerhouse caverns subjected to excavation, a microseismic (MS) monitoring system was established and the discrete element method (DEM)-based numerical simulation was carried out. The tempo-spatial damage characteristics of rock mass were analyzed. The evolution laws of MS source parameters during the formation of a rock collapse controlled by high geostress and geological structure were investigated. Additionally, a three-dimensional DEM model of the underground powerhouse caverns was built to reveal the deformation characteristics of rock mass. The results indicated that the MS events induced by excavation of high geostress underground powerhouse caverns occurred frequently. The large-stake crown of the main powerhouse was the main damage area. Prior to the rock collapse, the MS event count and accumulated energy release increased rapidly, while the apparent stress sharply increased and then decreased. The amount and proportion of shear and mixed MS events remarkably increased. The maximum displacement was generally located near the spandrel areas. The MS monitoring data and numerical simulation were in good agreement, which can provide significant references for damage evaluation and disaster forecasting in high geostress underground powerhouse caverns.

Keywords

high geostress / underground powerhouse caverns / microseismic monitoring / discrete element modelling / stability analysis

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Biao Li, Quan-fu Ding, Nu-wen Xu, Yi-fan Lei, Yuan Xu, Zhong-ping Zhu, Jing-fei Liu. Mechanical response and stability analysis of rock mass in high geostress underground powerhouse caverns subjected to excavation. Journal of Central South University, 2020, 27(10): 2971-2984 DOI:10.1007/s11771-020-4522-8

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References

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

[1]	QianQ-H, ZhouX-P. Failure behaviors and rock deformation during excavation of underground cavern group for Jinping I Hydropower Station [J]. Rock Mechanics and Rock Engineering, 2018, 51(8): 2639-2651

[2]	XiaoY-X, FengX-T, FengG-L, LiuH-J, JiangQ, QiuS-L. Mechanism of evolution of stress-structure controlled collapse of surrounding rock in caverns: A case study from the Baihetan hydropower station in China [J]. Tunnelling and Underground Space Technology, 2016, 51: 56-67

[3]	XuN-W, LiT-B, DaiF, LiB, ZhuY-G, YangD-S. Microseismic monitoring and stability evaluation for the large scale underground caverns at the Houziyan hydropower station in Southwest China [J]. Engineering Geology, 2015, 188: 48-67

[4]	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

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

[6]	MartinC D, ReadR S, MartinoJ B. Observations of brittle failure around a circular test tunnel [J]. International Journal of Rock Mechanics and Mining Sciences, 1997, 34(7): 1065-1073

[7]	AnderssonJ C, MartinC D. The Äspö pillar stability experiment: Part I — experiment design [J]. International Journal of Rock Mechanics and Mining Sciences, 2009, 46(5): 865-878

[8]	MaejimaT, MoriokaH, MoriT, AokiK. Evaluation of loosened zones on excavation of a large underground rock cavern and application of observational construction techniques [J]. Tunnelling and Underground Space Technology, 2003, 18(23): 223-232

[9]	KwonS, LeeC S, ChoS J, JeonS W, ChoW J. An investigation of the excavation damaged zone at the Kaeri underground research tunnel [J]. Tunnelling and Underground Space Technology, 2009, 24(1): 1-13

[10]	YanC-B. Blasting cumulative damage effects of underground engineering rock mass based on sonic wave measurement [J]. Journal of Central South University, 2007, 14(2): 230-235

[11]	LiS-J, YuH, LiuY-X, WuF-J. Results from in-situ monitoring of displacement, bolt load, and disturbed zone of a powerhouse cavern during excavation process [J]. International Journal of Rock Mechanics and Mining Sciences, 2008, 45: 1519-1525

[12]	YanP, LuW-B, ChenM, HuY-G, ZhouC-B, WuX-X. Contributions of in-situ stress transient redistribution to blasting excavation damage zone of deep tunnels [J]. Rock Mechanics and Rock Engineering, 2015, 48(2): 715-726

[13]	LesniakA, IsakowZ. Space-time clustering of seismic events and hazard assessment in the Zabrze-Bielszowice coal mine, Poland [J]. International Journal of Rock Mechanics and Mining Sciences, 2009, 46: 918-928

[14]	HudymaM, PotvinY H. An engineering approach to seismic risk management in hardrock mines [J]. Rock Mechanics and Rock Engineering, 2010, 43: 891-906

[15]	MaJ, DongL-J, ZhaoG-Y, LiX-B. Focal mechanism of mining-induced seismicity in fault zones: A case study of Yongshaba Mine in China [J]. Rock Mechanics and Rock Engineering, 2019, 52: 3341-3352

[16]	CaiM, KaiserP K, MartinC D. Quantification of rock mass damage in underground excavations from microseismic event monitoring [J]. International Journal of Rock Mechanics and Mining Sciences, 2001, 38: 1135-1145

[17]	MaK, TangC-A, XuN-W, LiuF, XuJ-W. Failure precursor of surrounding rock mass around cross tunnel in high-steep rock slope [J]. Journal of Central South University, 2013, 20: 207-217

[18]	FengG-L, FengX-T, ChenB-R, XiaoY-Y, YuY. A microseismic method for dynamic warning of rockburst development processes in tunnels [J]. Rock Mechanics and Rock Engineering, 2015, 48: 2061-2076

[19]	FengG-L, FengX-T, ChenB-R, XiaoY-X. Microseismic sequences associated with rockbursts in the tunnels of the Jinping II hydropower station [J]. International Journal of Rock Mechanics and Mining Sciences, 2015, 80: 89-100

[20]	FengG-L, FengX-T, ChenB-R, XiaoY-X, LiuG-F, ZhangW, HuL. Characteristics of microseismicity during breakthrough in deep tunnels: Case study of Jinping-II hydropower station in China [J]. International Journal of Geomechanics, 2020, 20(2): 04019163

[21]	FengG-L, FengX-T, ChenB-R, XiaoY-X, ZhaoZ-N. Effects of structural planes on the microseismicity associated with rockburst development processes in deep tunnels of the Jinping-II Hydropower Station, China [J]. Tunnelling and Underground Space Technology, 2019, 84: 273-280

[22]	XuN-W, LiT-B, DaiF, ZhangR, TangC-A, TangL-X. Microseismic monitoring of Strainburst activities in deep tunnels at the Jinping II hydropower station, China [J]. Rock Mechanics and Rock Engineering, 2016, 49(3): 981-1000

[23]	DaiF, LiB, XuN-W, FanY-L, ZhangC-Q. Deformation forecasting and stability analysis of large-scale underground powerhouse caverns from microseismic monitoring [J]. International Journal of Rock Mechanics and Mining Sciences, 2016, 86269-281

[24]	DaiF, LiB, XuN-W, ZhuY-G. Microseismic early warning of surrounding rock mass deformation in the underground powerhouse of the Houziyan hydropower station, China [J]. Tunnelling and Underground Space Technology, 2017, 62: 64-74

[25]	DhawanK R, SinghD N, GuptaI D. Three-dimensional finite element analysis of underground caverns [J]. International Journal of Geomechanics, 2004, 4: 224-228

[26]	AlejanoaL R, Rez-OyangurenP, TaboadaJ. FDM predictive methodology for subsidence due to flat and inclined coal seam mining [J]. International Journal of Rock Mechanics and Mining Sciences, 1999, 36(4): 475-491

[27]	HaoY H, AzzamR. The plastic zones and displacements around underground openings in rock masses containing a fault [J]. Tunnelling and Underground Space Technology, 2005, 20(1): 49-61

[28]	JingL. Formulation of discontinuous deformation analysis (DDA)—An implicit discrete element model for block systems [J]. Engineering Geology, 1998, 49(3): 371-381

[29]	CaiM, KaiserP K, MoriokaH, MinamiM, MaejimaT, TasakaY, KuroseH. FLAC/PFC coupled numerical simulation of AE in large-scale underground excavations [J]. International Journal of Rock Mechanics and Mining Sciences, 2007, 44: 550-564

[30]	YazdaniM, SharifzadehM, KamraniK, GhorbaniM. Displacement-based numerical back analysis for estimation of rock mass parameters in Siah Bisheh powerhouse cavern using continuum and discontinuum approach [J]. Tunnelling and Underground Space Technology, 2012, 28: 41-48

[31]	Sichuan Dadu River Shuangjiangkou Hydropower Development Co., Ltd. Bidding document for the diversion system construction of the Shuangjiangkou hydropower station at the Dadu River, Sichuan Province [R]. 2016. (in Chinese)

[32]	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, 131: 104347

[33]	ZhangB-H, DengJ-H. Microseismic monitoring analysis methods for disaster prevention in underground engineering [J]. Disaster Advances, 2012, 5(4): 1420-1424

[34]	FengG-L, FengX-T, XiaoY-X, YaoZ-B, HuL, NiuW-J, LiT. Characteristic microseismicity during the development process of intermittent rockburst in a deep railway tunnel [J]. International Journal of Rock Mechanics and Mining Sciences, 2019, 124104135

[35]	WyssM, BruneJ N. Seismic moment, stress and source dimensions for earthquakes in the California-Nevada region [J]. Journal of Geophysical Research, 1968, 73(14): 4681-4694

[36]	ZhangP-H, YangT-H, YuQ-L, XuT, ZhuW-C, LiuH-L, ZhouJ-R, ZhaoY-C. Microseismicity induced by fault activation during the fracture process of a crown pillar [J]. Rock Mechanics and Rock Engineering, 2015, 48(4): 1673-1682

[37]	LiB, XuN-W, DaiF, ZhangG-L, XiaoP-W. Dynamic analysis of rock mass deformation in large underground caverns considering microseismic data [J]. International Journal of Rock Mechanics and Mining Sciences, 2019, 122104078

[38]	CaiM, KaiserP K, MartinC D. A Tensile model for the interpretation of microseismic events near underground openings [J]. Pure and Applied Geophysics, 1998, 15367-92

[39]	BoatwrightJ, FletcherJ B. The partition of radiated energy between P and S waves [J]. Bulletin of the Seismological Society of America, 1984, 74(2): 361-376