Abstract
Coal wall spalling is regarded as a key technical problem influencing safe and efficient mining of large-mining-height working faces while the distribution of abutment pressure within the limit equilibrium zone (LEZ) influences coal wall spalling within a large-mining-height working face. This research attempted to explore the distribution characteristics of abutment pressure within the LEZ in a large-mining-height working face. For this purpose, the influences of the orientation of joints on mechanical characteristics of coal with joints and on the distribution of abutment pressure within the LEZ in the large-mining-height working face were analysed by theoretical analysis and numerical simulation. Research results show that the damage variable of coal with joints first rises, then decreases, and finally increases with increasing dip angle of the joints; as the azimuth of the joints increases, the damage variable first declines, then increases; the damage variable gradually declines with increasing joint spacing; an increase in the dip angle of joints corresponds to first reduction, then growth, and a final decrease of the abutment pressure at the same position in front of the coal walls; on certain conditions, the abutment pressure at the same position within the LEZ first rises, then declines as the azimuth of joints increases; with the growth of the joint spacing, the abutment pressure at the same position within the LEZ rises. The dip angle and azimuth of joints marginally affect the abutment pressure within the LEZ.
Highlights
Coal wall spalling is considered as a key technical problem influencing the safe, efficient, green, and intelligent mining of a fully mechanised working face with a large mining height, while the abutment pressure within the limit equilibrium zone (LEZ) during mining affects the stability of a coal wall [1,2,3,4,5,6,7,8,9]. ere are many researches about the abutment pressure on the working face [10,11,12,13,14,15], which are mainly about the influences of roof structure, mining height, or the coal macroscopic mechanical parameters on the abutment pressure. e joint influence on the abutment pressure within the LEZ on the working face is almost rare
According to the limit equilibrium theory, the abutment pressure is mainly influenced by various factors within the LEZ in front of a large-mining-height working face [16]
Based on the limit equilibrium theory, the support capacity of coal walls in a large-mining-height working face is explored to reveal the distribution of abutment pressure within the LEZ in the large-mining-height working face based on joints and their displacement
Summary
Coal wall spalling is considered as a key technical problem influencing the safe, efficient, green, and intelligent mining of a fully mechanised working face with a large mining height (the mining height is bigger than 3.5 m), while the abutment pressure within the limit equilibrium zone (LEZ) during mining affects the stability of a coal wall [1,2,3,4,5,6,7,8,9]. ere are many researches about the abutment pressure on the working face [10,11,12,13,14,15], which are mainly about the influences of roof structure, mining height, or the coal macroscopic mechanical parameters on the abutment pressure. e joint influence on the abutment pressure within the LEZ on the working face is almost rare. According to the limit equilibrium theory, the abutment pressure is mainly influenced by various factors (including support capacity of coal walls and mining height) within the LEZ in front of a large-mining-height working face [16]. Based on the limit equilibrium theory, the support capacity of coal walls in a large-mining-height working face is explored to reveal the distribution of abutment pressure within the LEZ in the large-mining-height working face based on joints and their displacement. En, based on the damage effect of joints on the coal, the abutment pressure within the LEZ in a large-mining-height working face was expressed by the formula containing the parameters of joints. The numerical simulation was used to verify the rationality of the formula of abutment pressure which reveal the distribution characteristics of abutment pressure within the LEZ influenced by the joints in a large-mining-height working face
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