Experiment on separated layer rock failure technology for stress reduction of entry under coal pillar in mining conditions

Liu, Juntao; Shen, Wenlong; Bai, Jianbiao; Shan, Chengfang; Liu, Xudong

doi:10.3389/fevo.2023.1265883

Front. Ecol. Evol.

2023

DOI: 10.3389/fevo.2023.1265883

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Experiment on separated layer rock failure technology for stress reduction of entry under coal pillar in mining conditions

Juntao Liu,

Wenlong Shen,

Jianbiao Bai

et al.

Abstract: Longwall entrance is especially vulnerable to the combined mining of nearby coal seams because of the substantial deformation disaster loaded by the abutment stress caused by the mining disturbance. Changes to the fracture characteristics, movement behavior, and structural morphology of the bearing structure above the coal pillar are recommended using the separated layer rock failure technology (SLRFT) to safeguard the entry beneath the coal pillar from high abutment stress. To simulate the impacts of the SLRF… Show more

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2024

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Cited by 3 publications

References 36 publications

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Study on the Cyclic Impact Mechanical Characteristics of Coal under Confining Pressure

Yongliang,

Liying,

Xuegang

2024

ACS Omega

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Coal damage accumulation and strength deterioration caused by mining-induced disturbances in deep mines are among the factors influencing the occurrence of dynamic disasters such as rock bursts. To study the mechanical deformation and failure characteristics of coal masses under both cyclic impact and confining pressure, SHPB experiments were performed to systematically analyze the behavior of coal samples under 1, 2, and 3 cycles at impact pressures of 0.25, 0.30, 0.35, 0.40, and 0.45 MPa. To study the influence of pressure and impact frequency on the dynamic mechanical failure of coal samples, a weakening effect model of coal samples under confining pressure was established, revealing the dynamic mechanical characteristics and failure mechanism of coal samples under different impact pressures and impact frequencies. The confining pressure SHPB results reveal that the number of cycles and impact pressure are inversely proportional to the peak stress and are proportional to the degree of weakening. The peak stress weakening coefficient of the coal samples under the different impact pressures ranged from 28.5 to 73.2%, and a linear weakening relationship with the number of cycles was obtained. The coal exhibited an end effect-controlled Y-shaped failure mode under both confining pressure and dynamic loading. This study provides an experimental reference for preventing the energy absorption and erosion of weak structures around rock bursts and improving the stability of supporting structures.

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Study on the Cyclic Impact Mechanical Characteristics of Coal under Confining Pressure

Yongliang,

Liying,

Xuegang

2024

ACS Omega

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Large-Scale Failure Mechanism of a Footwall with Steeply Inclined Discontinuities in a Sublevel Caving Mine

Yang,

Li,

Xia

et al. 2024

Int. J. Geomech.

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Study on the Dynamic Evolution of Mining-Induced Stress and Displacement in the Floor Coal-Rock Induced by Protective Layer Mining

Liu,

Man,

2024

Minerals

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Protective layer mining is the most effective means to prevent and control coal and gas outbursts. In order to deeply understand the dynamic evolution law of mining stress and displacement of the bottom plate coal rock body in the process of protective layer mining, the effects of upper protective layer mining on stress variation and displacement deformation in the underlying coal seam were studied using the similar experiment and FLAC3D simulations. The results reveal that mining in the 82# coal seam notably alleviates pressure in the 9# coal seam below, with an average relief rate of 86.2%, demonstrated by the maximal strike expansion deformation rate of 11.3‰ in the 9# coal seam post-mining. Stress monitoring data indicates a stress concentration zone within 32 m ahead of the working face, and a pressure relief zone within 51 m behind it. The research provides a scientific foundation for pressure-relief gas extraction techniques, affirming the substantial impact of upper protective layer mining on alleviating pressure in underlying coal seams, enhancing safety, and optimizing mining efficiency.

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Experiment on separated layer rock failure technology for stress reduction of entry under coal pillar in mining conditions

Cited by 3 publications

References 36 publications

Study on the Cyclic Impact Mechanical Characteristics of Coal under Confining Pressure

Study on the Cyclic Impact Mechanical Characteristics of Coal under Confining Pressure

Large-Scale Failure Mechanism of a Footwall with Steeply Inclined Discontinuities in a Sublevel Caving Mine

Study on the Dynamic Evolution of Mining-Induced Stress and Displacement in the Floor Coal-Rock Induced by Protective Layer Mining

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