High Mining Face Flexible Reinforcement to Prevent Coal Wall Spalling by Cuttable Aluminum–Plastic Pipe Pre-Grouting

Jiao, Huazhe; Yang, Wenbo; Chen, Xinming; Yang, Liuhua; Li, Zhen

doi:10.3390/en15093233

Energies

2022

DOI: 10.3390/en15093233

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High Mining Face Flexible Reinforcement to Prevent Coal Wall Spalling by Cuttable Aluminum–Plastic Pipe Pre-Grouting

Huazhe Jiao

Wenbo Yang

Xinming Chen

et al.

Abstract: A larger mining height leads to easy caving of the coal wall in the working face. The flexible reinforcement method during the mining period of the working face affects the normal mining of the working face, and the high strength of the traditional bolt/cable material affects the operation of the shearer drum, so it is necessary to seek a reinforcement material which does not affect the production and the drum coal cutting. This paper proposed a technical scheme of coal wall reinforcement by pre-grouting with … Show more

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Cited by 3 publications

References 28 publications

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Failure mechanism of the coal wall at the working face based on an eccentric compression mechanical model

Tian,

Wang,

Wang

et al. 2024

Deep Underground Science and Engineering

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The deformation and failure of coal walls in front of a working face cause significant difficulties during mining operations. This study reveals the nonuniform distribution of bearing pressure in front of coal walls based on in situ monitoring data and numerical simulation. Therefore, an eccentric compression mechanical model was established to study the deformation and failure characteristics of a coal wall. The slenderness ratio of the compression bar is introduced to define coal walls. The results showed that instability failure occurs when λ > λc and material failure occurs when λ ≤ λc. The instability failure‐type coal wall spalling was related to the mining height, eccentricity of roof pressure, the horizontal force, and the reaction moment of the floor. The material failure‐type coal wall spalling was related to the cohesion, the internal friction angle of the coal, the upper pressure, and the horizontal force of coal walls. Unstable and destructive coal wall peeling usually occurs at a height of 0.5–0.6 times the mining height, while material damage to coal wall peeling is determined to occur within the range of 0.4–0.6 times the mining depth. The findings contribute to the understanding of the deformation and failure of coal walls.

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Failure mechanism of the coal wall at the working face based on an eccentric compression mechanical model

Tian,

Wang,

Wang

et al. 2024

Deep Underground Science and Engineering

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Finite–Discrete Element Method Prediction of Advanced Fractures in Extra-Thick Coal Seams Based on a Constitutive Model of Rock Deformation–Fragmentation Failure Process

Guo-qiang

2023

Processes

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Roof fall is a frequent and destructive disaster in the working face of extra-thick coal seams. The important technology for disaster elimination is roof grouting, and the key to its success is to accurately predict the distance of the advanced fractures based on a reasonable rock constitutive relationship. In this paper, the constitutive relationship reflecting the progressive failure process of rock was established, including the elastic–plastic constitutive relation of intact rock, the fracture constitutive relation of non-penetrating fracture, and the shear friction constitutive relation of penetrating fracture. On this basis, the finite–discrete element method (FDEM) numerical calculation method was developed. Taking Yushupo Coal mine with a 16-m-thick coal seam as an example, the numerical results showed that the fractures in the roof appear 15~35 m ahead of the working face, and the maximum value of advance bearing pressure is between 16 and 30 MPa. Meanwhile the laboratory test results showed that the compressive strength of the grouted coal is 14.91 MPa after solidification for 7d. The above data mean that the grouting slurry can solidify the broken roof into a whole without roof fall disaster. At the same time, the rock pressure of the extra-thick coal seam can effectively crush the top coal, which is conducive to the top-coal caving operation. The in situ test shows that when the pre-grouting is carried out in the range of 20~30 m in front of the working face, the roof fall disaster can be effectively avoided, which is consistent with the numerical simulation results. It shows the rationality of the FDEM numerical method and the constitutive model of rock deformation–fragmentation failure process.

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Research on the Mechanism of Coal-Wall Spalling and Flexible Reinforcement in Soft-Coal Seams Based on the Mogi–Coulomb Criterion

Zhao,

Gao

et al. 2024

Sustainability

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The problem of soft coal-seam wall spalling is more prominent in the deep mining process, which seriously restricts the safety and sustainability of mining. The horizontal ground stress is usually ignored in the analysis of the coal-wall spalling mechanism. In this paper, based on the Mogi–Coulomb criterion and limit-equilibrium analysis, it is found that the traces of coal siding can be approximated as linear. The safety-stability coefficient of a soft-coal wall under the limit-equilibrium condition is obtained by applying the Mogi–Coulomb criterion. The coal stability of different positions is quite different. The coal with greater cohesion is more stable. In this regard, the cohesion of the coal can be improved through flexible reinforcement so as to improve the stability of the coal body. The control mechanism of the grouting and flexible rope reinforcing technology for the coal-wall spalling in the soft-coal seam is revealed. The safety-stability coefficient of the reinforced coal wall and the limit-stability coefficient are deduced. The reinforcement effect is related to the aperture ratio, the ultimate tensile force of the flexible rope, and the layout spacing. Reasonable aperture ratio, layout spacing, and flexible rope selection are key to reinforcement. This study has important guiding significance for the sustainability and safety of mining by revealing the mechanism of coal-wall spalling and reinforcement.

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High Mining Face Flexible Reinforcement to Prevent Coal Wall Spalling by Cuttable Aluminum–Plastic Pipe Pre-Grouting

Cited by 3 publications

References 28 publications

Failure mechanism of the coal wall at the working face based on an eccentric compression mechanical model

Failure mechanism of the coal wall at the working face based on an eccentric compression mechanical model

Finite–Discrete Element Method Prediction of Advanced Fractures in Extra-Thick Coal Seams Based on a Constitutive Model of Rock Deformation–Fragmentation Failure Process

Research on the Mechanism of Coal-Wall Spalling and Flexible Reinforcement in Soft-Coal Seams Based on the Mogi–Coulomb Criterion

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