Abstract
This study aimed to explore the stress distribution and variation of reverse fault-affected mined coal body. A mechanical analysis model of the coal body in the reverse fault area was first established, then the coal body stress characterization equation was derived, and the stress distribution pattern on the coal body was calculated. Subsequently, applying the Mohr–Coulomb strength criterion revealed the following relationship: the closer is the distance to the reverse fault, the worse is the stability of the coal body, and that the coal body strength influences the stress concentration of the coal body in front of the working face. Moreover, simulation with FLAC3D was carried out to verify the coal body stress calculated by the mechanical model as well as the fluctuation of the coal body stress concentration. It could be concluded that while mining the hanging wall of the reverse fault, the stress concentration of mined coal body decreases with the increase of reverse fault dip angle, but increases with the increase of reverse fault throw; the stress concentration magnitude generated during footwall mining is lesser than that during hanging-wall mining. In other words, the magnitude of coal body stress concentration can be affected by the hanging wall and footwall mining, as well as parameters of the reverse fault. Finally, intrinsically safe GZY25 borehole stress sensors were used to monitor the coal body stresses in the reverse fault area under the influence of mining in Xinchun Coal Mine and ZuoQiuka Coal Mine. It was found that the coal body stress concentration in front of the working face either increased gradually or increased first before decreasing. It can be concluded that with the decrease of the distance between the working face and reverse fault, the vertical stress of the coal body increases, and the vertical stress of the coal body begins to increase obviously at a certain position. At this point, the vertical stress of the coal body can be generalized to 1.02–1.39 times of the initial vertical stress. Furthermore, the stress concentration coefficient of coal body is related to the distance from the reverse fault, and two changes occur: ① if the coal-bearing capacity does not exceed its strength, the coal stress in front of the working face increases gradually, and the stress concentration factor increases gradually; ② the stress concentration coefficient of mining coal body increases first, such that when the coal body bearing capacity exceeds its strength, the coal body fails and loses all its effective bearing capacity, followed by the decrease in coal body stress concentration coefficient.
Highlights
Reverse faults are common geological structures widely distributed in China’s coal-producing areas [1,2,3], especially those in the southwest of the country, such as Guizhou, Yunnan, and Sichuan
Reverse faults have sealing properties, so mining stress will have an impact on gas bearing and its migration. erefore, the mining activities in the reverse
Due to high susceptibility to rockbursts caused by the mining conditions-incurred reverse fault instability, plenty of research efforts have been focused on fields related to the prevention of rockbursts, such as stress variation, the stability of reverse fault zone, and the slip of reverse fault zone
Summary
Reverse faults are common geological structures widely distributed in China’s coal-producing areas [1,2,3], especially those in the southwest of the country, such as Guizhou, Yunnan, and Sichuan. Underground coal mine projects in these areas often take place across or close to these reverse faults [4,5,6]. The coal bodies often lose their stability when the mining face gets too close to the reverse fault [7,8,9,10,11]. Significant achievements have been made in the analysis of mined coal body stress in reverse fault regions. To clarify the stress variation characteristics of reverse fault-affected mined coal bodies and explore the stress distribution characteristics of the mined coal bodies under various working faces, reverse fault distances, reverse fault dip angles, and fault throws, the actual working conditions of a typical working face in Guizhou mining area, were taken as the reference for the research
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