CUI Feng,LI Yifei,JIA Chong,et al. Rock burst hazard evaluation of coal mining face based on a Gaussian mixture model[J]. Coal Geology & Exploration,2024,52(10):85−96. DOI: 10.12363/issn.1001-1986.24.01.0072
Citation: CUI Feng,LI Yifei,JIA Chong,et al. Rock burst hazard evaluation of coal mining face based on a Gaussian mixture model[J]. Coal Geology & Exploration,2024,52(10):85−96. DOI: 10.12363/issn.1001-1986.24.01.0072

Rock burst hazard evaluation of coal mining face based on a Gaussian mixture model

  • Objective Deep insights into the probabilistic information contained in the energy distribution of acoustic emission (AE) or microseismic events are significant for the rock burst hazard evaluation of coal mining face.
    Methods  This study investigated No.40111 mining face of the No.4 coal seam at the Dafosi Coal Mine in Shaanxi Province. Using physical simulation experiments with similar materials, theoretical analysis, and on-site monitoring, this study investigated the evolutionary patterns of AE monitoring data during coal mining and illustrated the physical meaning of fluctuations in the probability distribution of AE energy. Accordingly, this study proposed an index model for the rock burst hazard evaluation based on a Gaussian mixture model (GMM) and confidence intervals and validated the proposed model based on field microseismic data.
    Results and Conclusions The results indicate that the overlying strata collapsed periodically during mining, with the collapse being accompanied by intensive release of AE energy. The probability density function (PDF) of the total energy exhibited a multi-degree-of-freedom asymmetric distribution. The comparison of multiple indices of fitting effects, such as the residual sum of squares, reveals that the GMM is the optimal fitting model. As indicated by the GMM clustering analysis based on the expectation-maximization (EM) algorithm, the total energy distribution of AE events can be categorized into two types, namely the high-frequency/low-energy and low-frequency/high-energy AE signals, with the latter type consistent with the sudden occurrence and high-energy destruction of rock burst events. This study conducted a rock burst hazard evaluation of the mining face based on the probability-energy gradient variations, providing a novel probabilistic approach for the rock burst hazard evaluation of coal mining face. The new assessment method based on probabilistic information has the potential to be applied in the monitoring, early warning, and subsequent prevention of rock bursts.
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