Geomechanical Model Experiment Study on Deformation and Failure Mechanism of the Mountain Tunnel in Layered Jointed Rock Mass

Guo, Zhibiao; Fan, Jinyan; Wang, Fengnian; Zhou, Hu; Li, Wei

doi:10.1155/2021/6645124

Cited by 9 publications

(5 citation statements)

References 34 publications

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“…After substituting the partial derivative of Equation (1) into Equation (10), the plastic shear strain in each principal direction can be obtained: 4 Geofluids…”

Section: Geofluidsmentioning

confidence: 99%

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Development of Transversely Isotropic Elastoplastic Constitutive Model in FLAC3D and Its Application in Tunnel Engineering

Zhang

Yin

et al. 2022

Geofluids

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The obvious anisotropy of layered rock mass prevents the built-in constitutive model of commercial simulation software from accurately describing the elastoplastic behavior of the rock mass. In this paper, a transversely isotropic elastoplastic constitutive model (called the AN-MC model) that characterizes the elastoplastic failure behavior of the layered rock mass is developed by introducing the Mohr-Coulomb yield criterion with the tension cutoff in the model based on the transversely isotropic constitutive model and deriving its finite difference scheme. The development and programming of the transversely isotropic elastoplastic constitutive model are achieved on the basis of the secondary development platform of FLAC3D and the VC++ environment. The accuracy and rationality of the proposed constitutive model are verified in terms of consistency of the calculation results of the developed transversely isotropic elastoplastic constitutive model and the built-in constitutive models. In the numerical analysis of the Queerxi tunnel project, the calculation results of the AN-MC model are in good agreement with the field monitoring data. Thus, the deformation characteristics of the tunnel surrounding rock are well characterized. Comparative analysis of the deformation and failure laws of the layered surrounding rock and isotropic surrounding rock indicates that the plastic failure range of the layered surrounding rock tunnel is larger, and the arch foot and waist are prone to plastic penetration failure with butterfly-shaped characteristics. The research results are important for the scientific prediction and precise support of layered rock mass deformation.

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“…After substituting the partial derivative of Equation (1) into Equation (10), the plastic shear strain in each principal direction can be obtained: 4 Geofluids…”

Section: Geofluidsmentioning

confidence: 99%

“…In recent years, extensive research has been conducted on the deformation and failure characteristics of layered rock mass [1][2][3][4][5][6][7]. Xia et al [1] studied the bearing deformation and failure process of layered rock mass through a model test and revealed the eccentric pressure failure phenomenon of surrounding rock.…”

Section: Introductionmentioning

confidence: 99%

Development of Transversely Isotropic Elastoplastic Constitutive Model in FLAC3D and Its Application in Tunnel Engineering

Zhang

Yin

et al. 2022

Geofluids

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“…Under the assumption that any tunnel section is parallel to the isotropic plane, the analytical solution for stress and displacement around any tunnel has been derived [28][29] . There is also comprehensive research on the stress distribution, deformation, and failure characteristics of surrounding rock in layered rock masses [30][31][32][33][34][35] .…”

Section: Introductionmentioning

confidence: 99%

Analytical expression of displacement of circular double tunnels in transversely isotropic rock mass in unstable rock zone of southwest mountainous area

Wei,

Zhang

2023

Preprint

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Due to the instability of the underground rock structure in the southwest mountain area, the influence of different pore shapes on the rock mechanics performance and fracture characteristics under uniaxial compression changes. The analysis and research on the displacement of double circular tunnels in layered rock mass lay an essential foundation for back-analyzing the displacement of anisotropic double caverns. Researchers can derive the displacement analytical solution for two circular tunnels in a transverse isotropy rock mass using the complex function and Schwarz alternating methods. This analytic solution can simplify the analytical solution of displacement within an isotropic rock mass and the displacement analytical solution for a single circular tunnel in a transversely isotropy rock mass. The solution demonstrates that even when the tunnel cross-section is presumed to be parallel to the isotropic plane during derivation, the displacement of the surrounding rock is influenced by the elastic modulus and the Poisson ratio in both the isotropic plane and the plane perpendicular to it. Hence, in the displacement back-analysis of two tunnels in transversely isotropic rock mass viewed in cross-section, it is necessary to determine six parameters that meet discernible conditions and use the corresponding sensitivity coefficients to invert the uniqueness of the parameters. By comparing the analytic solution with the numerical solution, it was found that the trends of both solutions were mainly consistent. Moreover, the error between the analytic and numerical solutions was relatively small within the 90 to 105 degrees data, which indicates that the analytical solution can effectively reflect the actual deformation pattern of circular tunnels. This finding is pivotal for back analysis of tunnel excavation displacement in layered rock masses.

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“…Wang et al [15] comprehensively examined the effects of roadway shape and fault dip angle on roadway damage, studying the initiation position and propagation path of cracks under the respective influences. Guo et al [16] analyzed the deformation evolution process of layered jointed roadway surrounding rock models and found that the distribution of stress concentration zones in the surrounding rock is highly uneven due to the unique characteristics of layered joint structures.…”

Section: Introductionmentioning

confidence: 99%

Numerical Analysis on the Influence of Joint Density on the Stability of Complex Jointed Roadway Surrounding Rock

Wang,

Wu,

Yang

et al. 2023

Sustainability

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The random distribution of a complex joint network within a coal–rock mass has a significant weakening effect on its bearing capacity, making the surrounding rock of the roadway highly susceptible to instability and failure under the influence of in situ stress and mining-induced stress. This poses challenges in controlling the surrounding rock and seriously affects the normal production of mines. Consequently, it is imperative to conduct stability analysis on complex jointed roadway surrounding rock. Therefore, taking the transport roadway of Panel 11030 in the Zhaogu No. 2 Coal Mine as a case study, the microscopic contact parameters of particles and joint surfaces in each rock layer were calibrated through uniaxial compression and shear simulation tests using the particle flow simulation software PFC2D 5.0. Based on the calibrated microscopic contact parameters, a multilayered roadway surrounding rock model containing complex joints was established, and the joint density was quantified to analyze its effects on the displacement field, stress field, force chain field, and energy field of the roadway surrounding rock. The research findings indicate that as the distance to the sidewall decreases, the impact of joint density on the deformation of the surrounding rock of the roadway increases. The displacement of the roadway roof, floor, and sidewalls is affected differently by the joint density, predominantly contingent upon the properties of the rock mass. During the process of stress redistribution in the surrounding rock, the vertical stress of the roof and floor is released more intensively compared to the horizontal stress, while the horizontal stress of the sidewalls is released more intensively compared to the vertical stress. The increase in joint density leads to an increasing release rate of the surrounding rock stress, causing the load-bearing rock mass to transfer towards the deeper part. As the joint density increases, the force chain network gradually transitions from dense to sparse, resulting in a decrease in strong force chains and a decline in the bearing capacity of the surrounding rock, accompanied by an expansion in the range of force chain failure and deformation. With the continuous increase in joint density, the values of maximum released kinetic energy and residual released kinetic energy become larger. Once the joint density reaches a certain threshold, the kinetic energy stability zone consistently maintains a high energy level, indicating extreme instability in the roadway and sustained deformation. The results provide a valuable insight for analyzing the failure mechanism of complex jointed roadway surrounding rock and implementing corresponding support measures.

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Geomechanical Model Experiment Study on Deformation and Failure Mechanism of the Mountain Tunnel in Layered Jointed Rock Mass

Cited by 9 publications

References 34 publications

Development of Transversely Isotropic Elastoplastic Constitutive Model in FLAC3D and Its Application in Tunnel Engineering

Development of Transversely Isotropic Elastoplastic Constitutive Model in FLAC3D and Its Application in Tunnel Engineering

Analytical expression of displacement of circular double tunnels in transversely isotropic rock mass in unstable rock zone of southwest mountainous area

Numerical Analysis on the Influence of Joint Density on the Stability of Complex Jointed Roadway Surrounding Rock

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