Estimation Procedure of Influence Exerted by Trigger Effects in Rock Mass on Technical Condition of Long-Term Operated Underground Structures

The article presents a visual and instrumental research of the technical condition of the main rock-cut structures and their masonry additions, the documentation of their damages (cracks, crevices, destructions and erosions) and deformations, thorough complete laboratory studies of rock samples and their physical and mechanical characteristics, conceptual approaches to preventive and reinforcing measures necessary for the further safe survival of structures, as well as the comprehensive development and implementation of measures to prevent further damages (elimination of causes) and ensure the long-term existence of structures. Based on the analyses carried out, it is recommended to use a ready-made dry mixture mortar of the “Mapegrout'' brand produced by the Italian company “Mapei” to fill cracks if necessary. It is available in the market of the country and is successfully used in the reconstruction of tunnels and other underground structures. The issues of compatibility of reinforcing materials with sandstone rock are also considered on the basis of some averaged data of the main decisive physical and mechanical characteristics of the strength and deformation of sandstone.

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Design of underground structures and analysis of self-support capacity

Materials and Geoenvironment ◽

10.2478/rmzmag-2018-0010 ◽

2018 ◽

Vol 65 (2) ◽

pp. 59-70

Author(s):

Matej Nagy

Keyword(s):

Rock Mass ◽

Hard Rock ◽

In Situ Stress ◽

Stability Control ◽

Underground Structures ◽

Underground Powerhouse ◽

The Stability ◽

Methods Numerical

Abstract The complicated rock structures and the stability of surrounding rocks of the underground powerhouse are key ground mechanical challenges for hydropower projects. In this paper, an example of contributing self-support capacity of rock mass to evaluate optimised support for long-term usage of structure is given. It describes importance of investigations in the initial in situ stress distribution, rock mechanical and geological properties, engineering rock mass classifications by different methods, numerical modelling, comparison of tools for stability and support analysis and proper stability control for rock excavation and support. The results show that after underground excavations in hard rock, detailed analysis of measures to investigate deformation and self-supporting capacity creation is useful and a cost-saving procedure.

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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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Assessment of the technical condition of underground structures of the largest hydroelectric power station in the North Caucasus, the Chirkeyskaya HPP

Proceedings of Petersburg Transport University ◽

10.20295/1815-588x-2021-3-410-420 ◽

2021 ◽

Vol 18 (3) ◽

pp. 410-420

Author(s):

Vladimir N. KAVKAZKY ◽

◽

Yana V. MEL’NIK ◽

Alexey P. LEIKIN ◽

Andrey V. BENIN ◽

...

Keyword(s):

Large Scale ◽

Practical Importance ◽

Hydroelectric Power Plant ◽

Technical Condition ◽

Hydroelectric Power Station ◽

Hydroelectric Power ◽

Underground Structures ◽

North Caucasus ◽

The Caucasus ◽

The North

Objective: Chirkeyskaya HPP is by far the most powerful hydroelectric power plant in the North Caucasus with the highest arched dam in Russia and the second highest dam in the country after the Sayano-Shushenskaya HPP. This explains why it is called the pearl of the Caucasus. Methods: For the operation and maintenance of this unique structure, a large-scale complex of underground structures for various purposes was built, the technical condition of which must be constantly monitored. To carry out work on the survey of underground structures, the management of the design and survey institute of JSC “Lengidroproekt” decided to attract specialists from the Department of Tunnels and Subways and the Test Center “Strength” of Emperor Alexander I Petersburg State Transport University. The work was successfully carried out at the end of 2015. Results: The safety of underground structures was objectively assessed. Recommendations for the repair and further comprehensive reconstruction of the Chirkeyskaya HPP have been developed. Practical importance: Carry out work on the survey of underground structures of Chirkeyskaya HPP is allowes elaborate of complex measures on safety from Chirkeyskaya HPP.

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Index of time-dependency for rock and its application for the assessment of the long-term stability of underground structures

Rock Mechanics for Resources, Energy and Environment ◽

10.1201/b15683-138 ◽

2013 ◽

pp. 807-812 ◽

Cited By ~ 2

Author(s):

K Hashiba ◽

K Fukui

Keyword(s):

Time Dependency ◽

Underground Structures ◽

Term Stability ◽

Long Term Stability

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Observation of the rock slope thermal regime, coupled with crack meter stability monitoring

10.5194/gi-2021-5 ◽

2021 ◽

Author(s):

Ondřej Racek ◽

Jan Blahůt ◽

Filip Hartvich

Keyword(s):

Rock Mass ◽

Monitoring System ◽

Rock Slope ◽

Global Radiation ◽

Environmental Parameters ◽

Radiation Balance ◽

Rock Types ◽

Novel Approach ◽

First Results

Abstract. This article describes an innovative, complex and affordable monitoring system designed for joint observation of environmental parameters, rock block dilatations and temperature distribution inside the rock mass with a newly designed 3-meter borehole temperature sensor. Global radiation balance data are provided by pyranometers. The system introduces a novel approach for internal rock mass temperature measurement, which is crucial for the assessment of the changes in the stress field inside the rock slope influencing its stability. The innovative approach uses an almost identical monitoring system at different sites allowing easy setup, modularity and comparison of results. The components of the monitoring system are cheap, off-the-shelf and easy to replace. Using this newly designed system, we are currently monitoring three different sites, where the potential rock fall may endanger society assets below. The first results show differences between instrumented sites, although data time-series are relatively short. Temperature run inside the rock mass differs for each site significantly. This is very likely caused by different aspects of the rock slopes and different rock types. By further monitoring and data processing, using advanced modelling approaches, we expect to explain the differences among the sites, the influence of rock type, aspect and environmental variables on the long-term slope stability.

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Determination and quality classification of rock mass of the Diatomite mine, Algeria

News of the Ural State Mining University ◽

10.21440/2307-2091-2021-1-17-24 ◽

2021 ◽

Vol 1 ◽

pp. 17-24

Author(s):

Abdessattar LAMAMRA ◽

◽

Dmitriy Leonidovich NEGURITSA ◽

Samir BEDR ◽

Ariant A. REKA ◽

...

Keyword(s):

Mechanical Properties ◽

Rock Mass ◽

Underground Mining ◽

Physical And Mechanical Properties ◽

Friction Angle ◽

Classification Systems ◽

Natural Phenomenon ◽

Underground Structures ◽

Dilatancy Angle ◽

Mining Work

Reserch relaevance. Most ground movements are generally due to rock instability, this natural phenomenon poses a risk to humanity. The properties of the rock mass directly influence the type of movement especially in underground structures. Research aim. Our goal is to characterize and classify the rock mass of diatomite from the sig mine using geomechanical classification systems such as the RQD and RMR in order to determine the quality of the rocks in the sig mine Western Algeria from the determination of the physical and mechanical properties. Methodology. In this article, the characterization analysis of the diatomite rock mass of the sig mine was carried out. First, determinations of the physical properties and carried out the triaxial test to determine the mechanical properties (young’s modulus, the friction angle, the dilatancy angle, the cohesion, the poisson’s ratio). Secondly to classify the deposit and give a recommendation to avoid stability problems. Research results. The results from physical and mechanical analyzes, it can be said that the nature of the rock present in the diatomite (underground mine) does not have enough resistance. Conclusion. Our study definitively proves that the rock mass of sig diatomite is of very low quality and it will be very dangerous for the underground mining work of the mine especially in places where the mineralized layer is very deep. And we suggest to replace the mining technique room and pillar currently used in the diatomite mine and put another mining method which includes roof support system to ensure the safety both of the miners and the equipment.

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Application of Numerical and Block Geomechanical Modelling to Determine Parameters of Large-Section Chambers

Горная промышленность ◽

10.30686/1609-9192-2021-2-127-131 ◽

2021 ◽

pp. 127-131

Author(s):

M.A. Sonnov ◽

A.V. Trofimov ◽

A.E. Rumyantsev ◽

S.V. Shpilev

Keyword(s):

Rock Mass ◽

Strain State ◽

Stress And Strain ◽

Underground Structures ◽

Geomechanical Model ◽

Principal Stresses ◽

Mine Support ◽

History Of ◽

Crushing Plant ◽

Ore Pass

The study is exemplified by complex workings of a main ore pass that include a variety of underground structures, usually with unique dimensions which depend on the function and size of the equipment placed. The technical solutions for the underground crushing plant and associated structures envisage construction of chambers with the height of up to 35 m and the width of up to 20 m at the depths exceeding 800-1000 m. Such conditions call for a closer attention to be paid to the mine support parameters, especially the bolting depth. A block geomechanical model was designed in the Micromine Mining Software for the rock mass of the new main ore pass. Geotechnical boreholes logs and results of physical and mechanical rock tests were used as the input data for the model. Four domains were identified in the block geomechanical model for subsequent numerical modelling. A 3D model of the stress-and-strain state of the rock mass was made using the CAE Fidesys software based on the Micromine wire-frame model of the main ore pass. The history of the rock mass incremental loading was reconstructed for correct simulation of its stress-and-strain state. Prior to the excavation, the rock mass is pre-stressed by the weight of the rock strata. The excavation phase was then simulated in the stepwise manner. An array of points with the values of maximum principal stresses was downloaded from the numerical model post-processing program and interpolated into the block geomechanical model to refine the SRF parameter of the Barton's Q rating. Based on the obtained Q values, the mine support parameters for chambers were determined using the Barton, Hutchinson and Potvin empirical methods.

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