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Hauptverfasser: Shi, Kaiwen, Shi, Wenhao, Zhao, Shankun, Duan, Hongfei, Li, Yuwei, Xue, Haojie, Shang, Xueyi, Dang, Wengang, Li, Peng, Zhang, Yunfei, Guan, Binghuo, Ma, Xiang, Gao, Hongke
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2504.20353
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author Shi, Kaiwen
Shi, Wenhao
Zhao, Shankun
Duan, Hongfei
Li, Yuwei
Xue, Haojie
Shang, Xueyi
Dang, Wengang
Li, Peng
Zhang, Yunfei
Guan, Binghuo
Ma, Xiang
Gao, Hongke
author_facet Shi, Kaiwen
Shi, Wenhao
Zhao, Shankun
Duan, Hongfei
Li, Yuwei
Xue, Haojie
Shang, Xueyi
Dang, Wengang
Li, Peng
Zhang, Yunfei
Guan, Binghuo
Ma, Xiang
Gao, Hongke
contents With heightened mining intensity, the incidence of coal bursts is escalating, necessitating advanced understanding and prediction techniques. This research delves into the intricacies of coal burst mechanisms, proposing a novel theoretical model for the release of coal mass energy founded on the tenets of stress superposition. A significant revelation is that the energy culminating in a coal burst is an amalgamation of intrinsic coal strain energy and perturbations from mining activities. Field investigations scrutinize the microseismic parameters across a spectrum of mining velocities, discerning potential failure regions and precursor hallmarks in high-intensity mining environments. Notably, microseismic energy, in such contexts, experiences an augmentation of approximately 2000 J. Numerical simulations executed via 3DEC elucidate stress distribution patterns and failure modalities of adjacent rock structures in relation to mining velocities. The simulations underscore that an uptick in mining speed diminishes the buffer to high-pressure abutments, intensifying inherent pressures. For mitigation, it's advocated that high-intensity mining advances be capped at 11 m/d. Merging theoretical analysis, experimental data, field assessments, and computational simulations, this study proffers a holistic insight into coal burst dynamics, underscoring its value in refining monitoring and early warning protocols in the domain.
format Preprint
id arxiv_https___arxiv_org_abs_2504_20353
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Study on impact mechanism and precursor information induced by high intensity mining
Shi, Kaiwen
Shi, Wenhao
Zhao, Shankun
Duan, Hongfei
Li, Yuwei
Xue, Haojie
Shang, Xueyi
Dang, Wengang
Li, Peng
Zhang, Yunfei
Guan, Binghuo
Ma, Xiang
Gao, Hongke
Geophysics
With heightened mining intensity, the incidence of coal bursts is escalating, necessitating advanced understanding and prediction techniques. This research delves into the intricacies of coal burst mechanisms, proposing a novel theoretical model for the release of coal mass energy founded on the tenets of stress superposition. A significant revelation is that the energy culminating in a coal burst is an amalgamation of intrinsic coal strain energy and perturbations from mining activities. Field investigations scrutinize the microseismic parameters across a spectrum of mining velocities, discerning potential failure regions and precursor hallmarks in high-intensity mining environments. Notably, microseismic energy, in such contexts, experiences an augmentation of approximately 2000 J. Numerical simulations executed via 3DEC elucidate stress distribution patterns and failure modalities of adjacent rock structures in relation to mining velocities. The simulations underscore that an uptick in mining speed diminishes the buffer to high-pressure abutments, intensifying inherent pressures. For mitigation, it's advocated that high-intensity mining advances be capped at 11 m/d. Merging theoretical analysis, experimental data, field assessments, and computational simulations, this study proffers a holistic insight into coal burst dynamics, underscoring its value in refining monitoring and early warning protocols in the domain.
title Study on impact mechanism and precursor information induced by high intensity mining
topic Geophysics
url https://arxiv.org/abs/2504.20353