Evaluation of shear behavior of in-situ rock mass by numerical simulation using discontinuous analysis method.

The paper deals with the back analysis method in geotechnical engineering, that goal is evaluation the more objective and reliable parameters of the rock mass on the basis of in-situ measurements. Stress, deformational, strength and rheological parameters of the rock mass are usually determined by some inaccuracies and errors arising from the complexity and variability of the rock mass. This higher or lower degree of imprecision is reflected in the reliability of the mathematical modelling results. The paper presents the utilization of direct optimization back analysis method, based on the theory of analytical functions of complex variable and Kolosov-Muschelischvili relations, to the evaluation of initial stress state inside the rock massif.

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A displacement-based back-analysis method for rock mass modulus and horizontal in situ stress in tunneling – Illustrated with a case study

Tunnelling and Underground Space Technology ◽

10.1016/j.tust.2005.12.001 ◽

2006 ◽

Vol 21 (6) ◽

pp. 636-649 ◽

Cited By ~ 55

Author(s):

L.Q. Zhang ◽

Z.Q. Yue ◽

Z.F. Yang ◽

J.X. Qi ◽

F.C. Liu

Keyword(s):

Rock Mass ◽

Back Analysis ◽

In Situ Stress ◽

Analysis Method ◽

Rock Mass Modulus ◽

Displacement Based

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Study on the Rock Mass Caving and Surface Subsidence Mechanism Based on an In Situ Geological Investigation and Numerical Analysis

Mathematical Problems in Engineering ◽

10.1155/2018/6054145 ◽

2018 ◽

Vol 2018 ◽

pp. 1-18 ◽

Cited By ~ 1

Author(s):

Fengyu Ren ◽

Dongjie Zhang ◽

Jianli Cao ◽

Miao Yu ◽

Shaohua Li

Keyword(s):

Numerical Simulation ◽

Rock Mass ◽

Roof Rock ◽

Rapid Development ◽

Hanging Wall ◽

Surface Subsidence ◽

Engineering Project ◽

Geological Investigation ◽

Sublevel Caving

To deeply understand the mechanism of the rock mass caving and associated surface subsidence during sublevel caving mining, the Xiaowanggou iron mine was selected as an engineering project case study. The study area was analyzed by means of an in situ geological investigation and numerical simulation. First, a borehole television (BHTV) system and a GPS monitoring system were used to monitor the caving process of the roof rock mass and the development of the surface subsidence; the monitoring time was thirteen months. Then, a numerical simulation was used to analyze the damage evolution of the rock mass. Research shows the following: (1) in situ geological monitoring results indicate that the caving process of the roof rock mass presents intermittent characteristics, where slow caving and sudden caving are conducted alternatively and the arched-caving trend is more pronounced with continuous mining. The surface subsidence, horizontal displacement, and horizontal deformation of the hanging wall are higher than that of the footwall, and the subsidence center gradually deflects to the hanging wall in the late stage of the +45m sublevel mining. (2) Numerical simulation results indicate that the extension and penetration of the shear and tensile cracks along the joints and intact rock bridges are the main factors causing the rock mass caving and the existence of the stress arch and its evolution process is the fundamental reason for the intermittent caving of the rock mass. The rapid development of damage to the hanging wall (the damage angle reduced) is the main cause of the deflection of the subsidence center affected by joints and the mining size. (3) In the future of mining, large-scale subsidence will occur on the surface of the hanging wall.

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Stress initialization methods for dynamic numerical simulation of rock mass with high in-situ stress

Journal of Central South University ◽

10.1007/s11771-020-4535-3 ◽

2020 ◽

Vol 27 (10) ◽

pp. 3149-3162

Author(s):

Jia-cai Yang ◽

Ke-wei Liu ◽

Xu-dong Li ◽

Zhi-xiang Liu

Keyword(s):

Numerical Simulation ◽

Rock Mass ◽

In Situ Stress ◽

High In Situ Stress ◽

Dynamic Numerical Simulation

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Numerical simulation of in situ exploitation of oil shale by injecting high-temperature steam

Oil Shale ◽

10.3176/oil.2019.4.03 ◽

2019 ◽

Vol 36 (4) ◽

pp. 483

Author(s):

D Yang ◽

Y Zhao ◽

Z Kang

Keyword(s):

Numerical Simulation ◽

High Temperature ◽

Oil Shale ◽

High Temperature Steam

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Stress wave propagation in different number of fissured rock mass based on nonlinear analysis

International Journal of Nonlinear Sciences and Numerical Simulation ◽

10.1515/ijnsns-2019-0301 ◽

2020 ◽

Vol 0 (0) ◽

Author(s):

Xiaoming Lou ◽

Mingwu Sun ◽

Jin Yu

Keyword(s):

Numerical Simulation ◽

Rock Mass ◽

Confining Pressure ◽

Displacement Discontinuity ◽

Stress Wave Propagation ◽

Theoretical Derivation ◽

Mechanics Model ◽

Fissured Rock ◽

Deep Rock ◽

Theoretical Accuracy

AbstractThe fissures are ubiquitous in deep rock masses, and they are prone to instability and failure under dynamic loads. In order to study the propagation attenuation of dynamic stress waves in rock mass with different number of fractures under confining pressure, nonlinear theoretical analysis, indoor model test and numerical simulation are used respectively. The theoretical derivation is based on displacement discontinuity method and nonlinear fissure mechanics model named BB model. Using ABAQUS software to establish a numerical model to verify theoretical accuracy, and indoor model tests were carried out too. The research shows that the stress attenuation coefficient decreases with the increase of the number of fissures. The numerical simulation results and experimental results are basically consistent with the theoretical values, which verifies the rationality of the propagation equation.

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Structural Effect of En-echelon Fractures on Shear Behavior of Rock Mass Under Constant Normal Load Conditions: An Experimental Study

Rock Mechanics and Rock Engineering ◽

10.1007/s00603-021-02555-3 ◽

2021 ◽

Author(s):

Yuanchao Zhang ◽

Yujing Jiang ◽

Daisuke Asahina ◽

Zhi Wang

Keyword(s):

Experimental Study ◽

Rock Mass ◽

Normal Load ◽

Shear Behavior ◽

Structural Effect ◽

Constant Normal Load ◽

Load Conditions

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Experimental Evaluation of Shear Behavior of Stone Masonry Wall

Materials ◽

10.3390/ma14092313 ◽

2021 ◽

Vol 14 (9) ◽

pp. 2313

Author(s):

Maria Luisa Beconcini ◽

Pietro Croce ◽

Paolo Formichi ◽

Filippo Landi ◽

Benedetta Puccini

Keyword(s):

Shear Behavior ◽

Stone Masonry ◽

Masonry Walls ◽

Mechanical Parameters ◽

In Situ Tests ◽

Capacity Curves ◽

Historical Structures ◽

Definition Of

The evaluation of the shear behavior of masonry walls is a first fundamental step for the assessment of existing masonry structures in seismic zones. However, due to the complexity of modelling experimental behavior and the wide variety of masonry types characterizing historical structures, the definition of masonry’s mechanical behavior is still a critical issue. Since the possibility to perform in situ tests is very limited and often conflicting with the needs of preservation, the characterization of shear masonry behavior is generally based on reference values of mechanical properties provided in modern structural codes for recurrent masonry categories. In the paper, a combined test procedure for the experimental characterization of masonry mechanical parameters and the assessment of the shear behavior of masonry walls is presented together with the experimental results obtained on three stone masonry walls. The procedure consists of a combination of three different in situ tests to be performed on the investigated wall. First, a single flat jack test is executed to derive the normal compressive stress acting on the wall. Then a double flat jack test is carried out to estimate the elastic modulus. Finally, the proposed shear test is performed to derive the capacity curve and to estimate the shear modulus and the shear strength. The first results obtained in the experimental campaign carried out by the authors confirm the capability of the proposed methodology to assess the masonry mechanical parameters, reducing the uncertainty affecting the definition of capacity curves of walls and consequently the evaluation of seismic vulnerability of the investigated buildings.

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In Situ Tests on Creep Behavior of Rock Mass with Joint or Shearing Zone in Foundation of Large-Scale Hydroelectric Projects

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.261-263.1097 ◽

2004 ◽

Vol 261-263 ◽

pp. 1097-1102 ◽

Cited By ~ 2

Author(s):

Jian Liu ◽

Xia Ting Feng ◽

Xiu Li Ding ◽

Huo Ming Zhou

Keyword(s):

Rock Mass ◽

Creep Behavior ◽

Large Scale ◽

Time Dependent ◽

Three Gorges Project ◽

Three Gorges ◽

The Three Gorges ◽

The Three Gorges Project

The time-dependent behavior of rock mass, which is generally governed by joints and shearing zones, is of great significance for engineering design and prediction of long-term deformation and stability. In situ creep test is a more effective method than laboratory test in characterizing the creep behavior of rock mass with joint or shearing zone due to the complexity of field conditions. A series of in situ creep tests on granite with joint at the shiplock area of the Three-Gorges Project and basalt with shearing zone at the right abutment of the Xiluodu Project were performed in this study. Based on the test results, the stress-displacement-time responses of the joints and basalt are analyzed, and their time-dependent constitutive model and model coefficients are given, which is crucial for the design to prevent the creep deformations of rock masses from causing the failure of the operation of the shiplock gate at the Three-Gorges Project and long-term stability of the Xiluodu arc dam.

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