Abstract
With unceasing increase of mining depth and development intensity, mining disasters such as rock burst have been increasing frequently, which often result in catastrophic accidents. Therefore, it is imperative to accurately forecast underground disasters. Previous research has suggested that the combination of drill-hole pressure relief and acoustic emission (AE) monitoring serves as an effective measure method towards the forecasting and prevention of disastrous accidents. However, the AE evolution mechanism of underground rock damages remains a challenge; more specifically, the relationships among the drilling hole positions, depths and diameters, and the stress–strain and AE characteristics of the rocks are discussed little in the literature. In order to bridge this research gap, the particle flow code (PFC2D) is employed to systemically investigate the hidden patterns among the mechanical properties, AE and damage evolution of the rock mass with different positions, depths and diameters of the drilling holes. Analysis results demonstrate that the drilling position influences the rock stress–strain and AE characteristics in the plastic deformation stage and the residual stage while the hole depth affects the drilling process. More specifically, the initial AE strength, AE impact at the peak moment, AE fluctuations and induction time are significantly influenced by the drilling position and depth. Furthermore, the drilling position and depth change the evolution law in the damage acceleration and stable development stages, while the hole diameter has little effect on the AE signal during the rock drilling process.
Highlights
On account of the intensity associated with the continuous development of the improvement of mineral resources, rock burst and other mining disasters and accidents have increased
With unceasing increase of mining depth and development intensity, mining disasters such as rock burst have been increasing frequently, which often result in catastrophic accidents
Previous research has suggested that the combination of drill-hole pressure relief and acoustic emission (AE) monitoring serves as an effective measure method towards the forecasting and prevention of disastrous accidents
Summary
On account of the intensity associated with the continuous development of the improvement of mineral resources, rock burst and other mining disasters and accidents have increased. In a previous work Jia et al [15] found that the diameter, spacing and depth of the drilling hole may significantly change the rock stress–strain characteristics, but they did not use AE sensors in their investigation. It is worth analyzing the effects of the drilling hole parameters on the AE signal and the rock mechanic characteristics. In order to address the aforementioned challenge, PFC2D is employed to systemically investigate the hidden patterns among the mechanical properties, acoustic emission (AE) and damage evolution in the rock pressure relief process with different positions, depths and diameters of the drilling hole. (2) A hidden pattern among the mechanical properties, AE and damage evolution characteristics is discovered for the granite under different drilling hole positions, depths and diameters
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Published Version
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