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Your search keyword '"Rock stability"' showing total 4 results
Start Over Descriptor "Rock stability" Topic rock mechanics
4 results on '"Rock stability"'

1. Construction Mechanical Characteristics of TBM Pilot and Enlargement Method for Ventilation Tunnel of Wuhai Pumped Storage Power Station.

Author

Fan, Chuanjun, Qin, Jianmin, and Wang, Guixuan

Subjects
TUNNEL ventilation, BORING & drilling (Earth & rocks), CONSTRUCTION projects, STRESS concentration, ROCK mechanics, SHOULDER, POSTEROLATERAL corner, STORAGE
Abstract

Investigating the construction mechanics of a ventilation tunnel using the TBM (Tunnel Boring Machine) pilot and enlargement method with reliable rock mechanics parameters ensures the safety of on-site excavation operations. Leveraging the construction project of the ventilation tunnel at the Wuhai Pumped Storage Power Station, TGP sidewall forecasting was employed to explore the geological conditions within a 50 m range of the tunnel's side. A systematic study of the construction mechanics of the TBM pilot and enlargement method was conducted, along with corresponding construction recommendations and engineering applications. This research indicates that sidewall forecasting can supplement the deficiencies in geological exploration reports, with excavation revealing conditions consistent with the forecast. Deformation at the interface, including the arch crown and sidewall, mainly concentrates during the construction phase from the completion of full-section excavation to the beginning of expansion. As the working face advances, the upper rock mass within the ventilation tunnel outline experiences tension, with stress concentration in the shoulder and bottom corner rock masses. The plastic zone before expansion primarily concentrates within the ventilation tunnel outline, shifting to the sidewall after expansion, with the left shoulder's plastic zone depth slightly exceeding that of the right. The proposed method effectively ensures construction safety, and the research findings have valuable implications for similar projects. [ABSTRACT FROM AUTHOR]

Published
2024
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2. Role of Brittle Behaviour of Soft Calcarenites Under Low Confinement: Laboratory Observations and Numerical Investigation.

Author

Lollino, Piernicola and Andriani, Gioacchino

Subjects
*ROCK mechanics, *GEOTECHNICAL engineering
Abstract

The strength decay that occurs in the post-peak stage, under low confinement stress, represents a key factor of the stress-strain behaviour of rocks. However, for soft rocks this issue is generally underestimated or even neglected in the solution of boundary value problems, as for example those concerning the stability of underground cavities or rocky cliffs. In these cases, the constitutive models frequently used in limit equilibrium analyses or more sophisticated numerical calculations are, respectively, rigid-plastic or elastic-perfectly plastic. In particular, most of commercial continuum-based numerical codes propose a variety of constitutive models, including elasticity, elasto-plasticity, strain-softening and elasto-viscoplasticity, which are not exhaustive in simulating the progressive failure mechanisms affecting brittle rock materials, these being characterized by material detachment and crack opening and propagation. As a consequence, a numerical coupling with mechanical joint propagation is needed to cope with fracture mechanics. Therefore, continuum-based applications that treat the simulation of the failure processes of intact rock masses at low stress levels may need the adoption of numerical techniques capable of implementing fracture mechanics and rock brittleness concepts, as it is shown in this paper. This work is aimed at highlighting, for some applications of rock mechanics, the essential role of post-peak brittleness of soft rocks by means of the application of a hybrid finite-discrete element method. This method allows for a proper simulation of the brittle rock behaviour and the related mechanism of fracture propagation. In particular, the paper presents two ideal problems, represented by a shallow underground cave and a vertical cliff, for which the evolution of the stability conditions is investigated by comparing the solutions obtained implementing different brittle material responses with those resulting from the assumption of perfectly plastic behaviour. To this purpose, a series of petrophysical and mechanical tests were conducted on samples of soft calcarenite belonging to the Calcarenite di Gravina Fm. (Apulia, Southern Italy), focusing specific attention on the post-peak behaviour of the material under three types of loading (compression, indirect tension and shear). Typical geometrical features representative of real rock engineering problems observed in Southern Italy were assumed in the problems examined. The numerical results indicate the impact of soft rock brittleness in the assessment of stability and highlight the need for the adoption of innovative numerical techniques to analyse these types of problems properly. [ABSTRACT FROM AUTHOR]

Published
2017
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3. Дефинисање механичких својстава алтерисаног стенског материјала лабораторијским методама

Author

Владимир Чебашек and Небојша Гојковић, Радоје Пантовић

Subjects
једноосна чврстоћа на притисак, механика стена, rock stability, композитни узорци, дацит, triaxial compressive strength, 622.83(043.3) [624.12], алтерисани дацит, троосна чврстоћа на притисак, стабилност косина, composite samples, dacite, uniaxial compressive strength, altered dacite, rock mechanics
Abstract

M70 M70 Основни циљ овог рада је да представи методологију одређивања механичких својстава хетерогеног стенског масива који изграђују дацит (Д) и алтерисани дацит (АД), где је уочена је зона постепеног преласка од алтерисаног дацита до дацита. Механичка својства стенског масива у тој зони утврђена су на основу лабораторијских испитивања једноосне и троосне чврстоће на притисак стенског материјала композитних узорака. Композитни узорци су се састојали од дискова стенског материјала, при чему је висина дискова h дефинисала различити процентуални удео појединог стенског материјала, дацита (Д), који представља чвршћу компоненту, и алтерисаног дацита (АД), који представља слабију компоненту у пробним телима. Функционална зависност промене параметара чврстоће стенског материјала (једноосне чврстоће на притисак, троосне чврстоће на притисак непоремећеног стенског материјала и материјалне константе) са повећањем учешћа "слабијег" стенског материјала утврђена је на основу резултата испитивања једноосне и троосне чврстоће на притисак. Учешће алтерисаног дацита директно утиче на начин и механизам лома током испитивања. Једноосна чврстоћа на притисак (σciUCS) и троосна чврстоћа на притисак непоремећеног стенског материјала (σciТX ) опадају експоненцијално са повећањем процентуалног учешћа АД. Утврђене зависности σciТX и константе mi дефинишу поузданије вредности параметара чврстоће стенске масе, које се, заједно са одговарајућим системима класификације стенског масива, могу користити као основа за процену параметара стенског масива. У оквиру овог рада је коришћена GSI класификација којом се врши редуковање чврстоће стенског масива на основу заступљених геолошких услова у стенском масиву. Стога, на основу свих израчунатих параметара чврстоће за различите процентуалне садржаје АД (0-100%), могуће је прогнозирати параметре чврстоће хетерогеног стенског масива на прелазу чврсте компоненте (Д) и слабе компоненте (АД). Вредности параметара чврстоће стенског масива утврђене на претходно описани начин су биле основа за израду геомеханичких модела помоћу којих је извршена анализа стабилности косина. Анализа стабилности косина је извршена на карактеристичном профилу у правцу напредовања површинског копа, са променљивим углом нагиба завршне косине који се кретао у распону 20-70°, где је анализом обухваћено два случаја: са и без коришћења транзиционе зоне. Транзициона зона је разматрана на растојању границе Д и АД од горње равни косине у распону од 0-140 m са кораком од 20 m. На тај начин је за вредност фактора сигурности Fs=1,3 за сваки случај посебно, утврђен максимални угао нагиба завршне косине. The aim of this paper presents a methodology for determining mechanical properties of heterogeneous rock mass composed of dacite (D and altered dacite (AD), where zone of gradual transition from altered dacite to dacite was observed in the rock mass. The mechanical properties of the rock mass in that zone was determined based on laboratory tests of uniaxial and triaxial compressive strength of the rock material on composite samples. The composite samples consisted of rock material discs, with the height (h) of the discs defining different volumetric percentages of rock material dacite (D), which represent hard component, and altered dacite (AD), which represent weaker component in specimens. However, the functional dependence on the strength parameter alteration of the rock material (uniaxial compressive strength, intact uniaxial compressive strength, and material constant) with an increase in the participation of "weaker " rock material was determined based on the test results of uniaxial and triaxial compressive strength. The participation of altered dacite directly affects the mode and mechanism of failure during testing. Uniaxial compressive strength (σciUCS) and intact uniaxial compressive strength (σciTX) decrease exponentially with increased AD volumetric participation. The dependences of the σciTX and constants mi define more reliable values of rock mass strength parameters, which can be used, together with rock mass classification systems, as a basis for estimating rock mass parameters. Within this paper, the GSI classification was used, which reduces the strength of the rock mass based on the represented geological conditions in the rock mass. Therefore, it is possible to predict the strength parameters of the heterogeneous rock mass at the transition of hard component (D) and weak component rock (АD) based on all calculated strength parameters for different participation of AD (0-100%). The values rock mass strength parameters was determined were the basis for the development of geomechanical models by which the analysis of slope stability was performed. Slope stability analysis was performed on a characteristic profile in the direction of open pit advancement, with a variable final slope angle of the ranging from 20- 70°, where the analysis included two cases: with and without the use of the transition zone. The transition zone was considered for the distances of the boundary D and AD from the upper plane in the range of 0-140 m with a step of 20 m were considered. That way for the value of the safety factor Fs = 1.3, for each case separately, the maximum allowed final slope angle of the was determined.

Published
2022

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