Abstract
The mechanical behavior of hard roofs often leads to significant deformation and strong mine seismicity in gob-side entry retaining (GER) of the longwall mining, affecting the mining safety and efficiency of coal mines. Field investigations indicate that the failure process of the retained entry by hard roofs can be divided into three stages. In this paper, theoretical analysis and numerical simulations are first used to evaluate the damage process of the retained entry under the hard roof. The results show that the instability of the retained entry in the conventional GER method results from the combined static-dynamic loads (in stage II and stage III) from the hard roof. Then, an innovative method, through fracturing roofs to maintain entry (FRME), based on GER with the hard roof is introduced to solve this problem. In this method, the roof of the mining area is pre-fractured, and when the coal seam is mined, the direct hard roof will collapse along the fractured surface due to its deadweight and mining pressure. The hard roof control effect on the static and dynamic loads, taking into account the innovative method, is verified with simulations and theoretical analyses. The results are compared with those of the conventional GER method. Furthermore, based on the numerical simulation study of dynamic responses, it is found that compared to the GER method, the dynamic response of the retained entry using the innovative method is more moderate and more conducive to the stability of the entry. Field application also validated the effectiveness of the innovative method to control the mechanical behavior of the “massive sudden collapse” of the hard roof.
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This study was supported by the Fundamental Research Funds for the Central Universities (2021YJSLI13;2021JCCXLJ05) and supported by Beijing Natural Science Foundation (8212033).
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Guo, P., Ma, Z. & Zhang, L. An Innovative Method of Gob-Side Entry Retaining to Control the Non-collapse Behaviors of Hard Roofs: a Case Study. Mining, Metallurgy & Exploration 40, 1805–1825 (2023). https://doi.org/10.1007/s42461-023-00829-8
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DOI: https://doi.org/10.1007/s42461-023-00829-8