Investigation and analysis on crack propagation of surrounding rock mass in the AiGong Cave of Longyou

Rock excavation has experienced complex stress paths. The development of the original crack under the path of principal stress magnitude and principal stress direction is a key scientific problem that needs to be solved in rock underground engineering. The principal stress magnitude dominates the initiation and propagation of the crack and increases rock damage under the action of principal stress rotation. In this study, the theoretical calculation and numerical analysis method have been combined with the crack propagation conditions to study the stress-driven mechanism of brittle rock crack propagation under principal stress rotation. The results show that the “relative initial angle” of crack angle is being updated in time during the principal stress rotation process; once the stress is rotated, it will become the next initial crack angle; the crack propagation direction is deviated under the applied shear load, and it is always in the direction of minimum shear load, leading to a certain degree of inhibition of crack propagation depth in the initial direction. According to the results of numerical simulation, the effect of principal stress rotation caused by mining excavation is obvious and has a certain range of influence depth, the stress of surrounding rock of roadway is the highest within the depth range of 1∼2 m, and the maximum principal stress is as high as 26.89 MPa. The rotation of principal stress direction on the roadway surrounding rock surface is the strongest, which makes the surrounding rock more fragmented, and the middle principal stress and the maximum principal stress rotate about 90° counterclockwise along the Ox axis. Studying the action mechanism of principal stress rotation on fractured rock masses can provide scientific basis for geotechnical engineering design and rock mass surrounding support.

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Study on the Failure Mechanism for Coal Roadway Stability in Jointed Rock Mass Due to the Excavation Unloading Effect

Energies ◽

10.3390/en13102515 ◽

2020 ◽

Vol 13 (10) ◽

pp. 2515 ◽

Cited By ~ 3

Author(s):

Eryu Wang ◽

Guangbo Chen ◽

Xiaojie Yang ◽

Guofeng Zhang ◽

Wenbin Guo

Keyword(s):

Rock Mass ◽

Numerical Model ◽

Crack Propagation ◽

Failure Mechanism ◽

Jointed Rock ◽

Jointed Rock Mass ◽

Surrounding Rock ◽

Coal Roadway ◽

Roadway Stability ◽

Rock Structure

Aiming at the large deformation instability problem caused by the excavation unloading of a coal roadway in deep-buried slowly inclined jointed rock mass, the geomechanical parameters and deformation failure characteristics of an engineering geomechanical model were investigated. The in-situ stress state of the model was measured with the stress relief method. The geological and mechanical properties of roadway surrounding rock were described. The surrounding rock structure was revealed with the electron microscopy scanning method, micro-fractures and randomly distributed joints highly developed in roadway surrounding rock. Field investigation and monitoring indicated the cross-section of roadway surrounding rock shrank continuously and the deformation distribution was obviously asymmetric. Shotcrete spalling and cable broken failures frequently occurred in the middle and ride side of roof and right rib. Based on the geomechanical conditions of the coal roadway, a discrete element numerical model of coal roadway in gently inclined jointed rock mass was established. The parameters of rock mass in the numerical model were calibrated. The model ran in unsupported condition to restore the evolution process of stress, crack propagation and deformation in roadway surrounding rock due to gradual deviatoric stress release caused by excavation. On this basis, the space-time evolution characteristics and law of stress, crack propagation and deformation were obtained and then the asymmetric large fragmentation and dilatation deformation failure mechanism of roadway surrounding rock in deep-buried slowly inclined jointed rock mass was revealed. The failure reasons of the support structure were analyzed, and the relevant support principles were proposed. The research results can provide scientific references for the stability control of roadways excavated in jointed rock mass.

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Influence exerted by underground excavation shape and by effective stresses on the formation of a tensile strain zone at a depth greater than 1 km

MINING INFORMATIONAL AND ANALYTICAL BULLETIN ◽

10.25018/0236-1493-2020-6-0-67-75 ◽

2020 ◽

pp. 67-75

Author(s):

Van Min Nguyen ◽

V. A. Eremenko ◽

M. A. Sukhorukova ◽

S. S. Shermatova

Keyword(s):

Rock Mass ◽

Cross Sections ◽

Tensile Strain ◽

Rock Fracture ◽

Strain Analysis ◽

Surrounding Rock ◽

Underground Excavation ◽

Secondary Stress ◽

Principal Stresses ◽

Mining Depth

The article presents the studies into the secondary stress field formed in surrounding rock mass around underground excavations of different cross-sections and the variants of principal stresses at a mining depth greater than 1 km. The stress-strain analysis of surrounding rock mass around development headings was performed in Map3D environment. The obtained results of the quantitative analysis are currently used in adjustment of the model over the whole period of heading and support of operating mine openings. The estimates of the assumed parameters of excavations, as well as the calculations of micro-strains in surrounding rock mass by three scenarios are given. During heading in the test area in granite, dense fracturing and formation of tensile strain zone proceeds from the boundary of e ≥ 350me and is used to determine rough distances from the roof ( H roof) and sidewalls ( H side) of an underground excavation to the 3 boundary e = 350me (probable rock fracture zone). The modeling has determined the structure of secondary stress and strain fields in the conditions of heading operations at great depths.

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Multi-factors influence of anchorage force on surrounding rock under coupling effect of creep rock mass and bolt/cable

Geomatics Natural Hazards and Risk ◽

10.1080/19475705.2021.1872717 ◽

2021 ◽

Vol 12 (1) ◽

pp. 328-346

Author(s):

Yuting Liu ◽

Pengqiang Zheng ◽

Pu Wang

Keyword(s):

Rock Mass ◽

Coupling Effect ◽

Surrounding Rock

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Timeliness of collinear crack propagation in rock mass

AIP Advances ◽

10.1063/5.0050868 ◽

2021 ◽

Vol 11 (6) ◽

pp. 065120

Author(s):

Min Bao ◽

Zhonghui Chen ◽

Zihan Zhou ◽

Lingfan Zhang ◽

Jianming Wang

Keyword(s):

Rock Mass ◽

Crack Propagation ◽

Collinear Crack

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Hydro-Mechanical Coupled Analysis of the Stability of Surrounding Rock Mass of Underground Water-Sealed Oil Storage

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.405-408.402 ◽

2013 ◽

Vol 405-408 ◽

pp. 402-405 ◽

Cited By ~ 1

Author(s):

Yun Jie Zhang ◽

Tao Xu ◽

Qiang Xu ◽

Lin Bu

Keyword(s):

Rock Mass ◽

Underground Water ◽

Surrounding Rock ◽

Comsol Multiphysics ◽

Coupled Analysis ◽

Coupling Theory ◽

Oil Storage ◽

Stability Of Surrounding Rock ◽

Straight Wall ◽

The Stability

Based on the fluid-solid coupling theory, we study the stability of surrounding rock mass around underground oil storage in Huangdao, Shandong province, analyze the stress of the surrounding rock mass around three chambers and the displacement change of several key monitoring points after excavation and evaluate the stability of surrounding rock mass using COMSOL Multiphysics software. Research results show that the stress at both sides of the straight wall of cavern increases, especially obvious stress concentration forms at the corners of the cavern, and the surrounding rock mass moves towards the cavern after excavation. The stress and displacement of the surrounding rock mass will increase accordingly after setting the water curtains, but the change does not have a substantive impact on the stability of surrounding rock mass.

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Application of ABAQUS in Surrounding Rock Stability Analysis of Shallow Large Cross-Section Tunnel

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.777.8 ◽

2015 ◽

Vol 777 ◽

pp. 8-12 ◽

Cited By ~ 1

Author(s):

Lin Zhen Cai ◽

Cheng Liang Zhang

Keyword(s):

Numerical Simulation ◽

Rock Mass ◽

Strong Support ◽

Surrounding Rock ◽

Tunnel Engineering ◽

Tunnel Excavation ◽

Rock Stability ◽

Rock Bolting ◽

Excavation Support ◽

The Stability

HuJiaDi tunnel construction of Dai Gong highway is troublesome, the surrounding-rock mass give priority to full to strong weathering basalt, surrounding rock integrity is poor, weak self-stability of surrounding rock, and tunnel is prone to collapse. In order to reduce disturbance, taking advantage of the ability of rock mass, excavation adopt the method of "more steps, short footage and strong support". The excavation method using three steps excavation, The excavation footage is about 1.2 ~ 1.5 m; The surrounding rock bolting system still produce a large deformation after completion of the first support construction, it shows that the adopted support intensity cannot guarantee the stability of the tunnel engineering. Using ABAQUS to simulate tunnel excavation support, optimizing the support parameters of the tunnel, conducting comparative analysis with Monitoring and Measuring and numerical simulation results, it shows that the displacement - time curves have a certain consistency in numerical simulation of ABAQUS and Monitoring and Measuring.

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Precise grading of surrounding rock based on the numerical calculation of the jointed rock mass

Proceedings of the Institution of Civil Engineers - Geotechnical Engineering ◽

10.1680/jgeen.21.00155 ◽

2022 ◽

pp. 1-32

Author(s):

Dan Huang ◽

Xiao-Qing Li ◽

Wen-Chao Song

Keyword(s):

Rock Mass ◽

Numerical Calculation ◽

Calculation Method ◽

Jointed Rock ◽

Jointed Rock Mass ◽

Surrounding Rock ◽

Geological Survey ◽

Survey Method ◽

Synthetic Rock ◽

Numerical Calculation Method

In this study, grading of surrounding rock was based on rock mass basic quality (BQ) values according to the specifications in China. Numerical approach was to construct synthetic rock mass (SRM) model to represent the jointed rock mass, and obtain the strength of the rock mass. It represented intact rock by the bonded particle model (BPM), and represent joint behaviour by the smooth joint model (SJM) to construct the discrete fracture network (DFN). In the Hongtuzhang Tunnel, the micro properties of granite cores with different weathered degrees were determined by the validation process, and the calculation representative elementary volume (REV) of surrounding rock was 15 m×15 m. Five slightly weathered, three slightly to moderately weathered, and two moderately weathered granite surrounding rock mass models were established based on the probability distribution of joint sets in each borehole, the conversion BQ value was acquired according by the calculated strength of rock mass model. It was discussed the differences of surrounding rock grades between the geological survey method and the numerical calculation method, and then found that the geological survey report is higher than the numerical calculation method predicted. And the numerical calculation is consistent with the actual excavation of rock mass at borehole A1388.

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Study on Deformation and Damage of Rock Mass Subject to High In Situ Stress by Using a Elastoplastic Damage Model and Considering the Impact of Weak Planes

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.838-841.705 ◽

2013 ◽

Vol 838-841 ◽

pp. 705-709

Author(s):

Yun Hao Yang ◽

Ren Kun Wang

Keyword(s):

Rock Mass ◽

Large Scale ◽

Damage Model ◽

Back Analysis ◽

In Situ Stress ◽

Surrounding Rock ◽

High In Situ Stress ◽

Underground Caverns ◽

The Impact

Large scale underground caverns are under construction in high in-situ stress field at Houziyan hydropower station. To investigate deformation and damage of surrounding rock mass, a elastoplastic orthotropic damage model capable of describing induced orthotropic damage and post-peak behavior of hard rock is used, together with a effective approach accounting for the presence of weak planes. Then a displacement based back analysis was conducted by using the measured deformation data from extensometers. The computed displacements are in good agreement with the measured ones at most of measurement points, which confirm the validities of constitutive model and numerical simulation model. The result of simulation shows that damage of surrounding rock mass is mainly dominated by the high in-situ stress rather than the weak planes and heavy damage occur at the cavern shoulders and side walls.

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Numerical Simulation on Large Deformation of Weak Rock Mass Tunnel Under High Geostress

MATEC Web of Conferences ◽

10.1051/matecconf/201817503025 ◽

2018 ◽

Vol 175 ◽

pp. 03025

Author(s):

Feng Zhou ◽

Hongjian Jiang ◽

Xiaorui Wang

Keyword(s):

Rock Mass ◽

Large Deformation ◽

Lateral Pressure ◽

Simulation Analysis ◽

Pressure Coefficient ◽

Surrounding Rock ◽

Analog Simulation ◽

Lateral Pressure Coefficient ◽

High Geostress ◽

The Stability

The problem about the stability of tunnel surrounding rock is always an important research object of geotechnical engineering, and the right or wrong of the result from stability analysis on surrounding rock is related to success or failure of an underground project. In order to study the deformation rules of weak surrounding rock along with lateral pressure coefficient and burying depth varying under high geostress and discuss the dynamic variation trend of surrounding rock, the paper based on the application of finite difference software of FLAC3D, which can describe large deformation character of rock mass, analog simulation analysis of surrounding rock typical section of the class II was proceeded. Some conclusions were drawn as follows: (1) when burying depth is invariable, the displacements of tunnel surrounding rock have a trend of increasing first and then decreasing along with increasing of lateral pressure coefficient. The floor heave is the most sensitive to change of lateral pressure coefficient. The horizontal convergence takes second place. The vault subsidence is feeblish to change of lateral pressure coefficient. (2) The displacements of tunnel surrounding rock have some extend increase along with increasing of burying depth. The research conclusions are very effective in analyzing the stability of surrounding rock of Yunling tunnel. These are going to be a reference to tunnel supporting design and construction.

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