Abstract
Stress-dominated coal and gas outburst disaster has become one of the main safety problems in deep coal mines. Acoustic emission (AE) or microseismic technology has been viewed as a promising method that can effectively reflect the stress and stability status of rock mass. The AE activity precursor of coal failure is the theoretical basis of this technology. In this study, AE experiments in failure process of coal specimens with different properties and under different stress conditions were performed in laboratory to explore influence factors and their effect of AE activity, and AE activity pattern classification was proposed based on the failure type of coal. The results indicate that the AE activity of different coals under loading are associated with the failure phase, and the evolution pattern of AE activity depends on the failure type of stressed coal. Both the mechanical property and the external stress condition have an important influential effect on the failure type and AE activity pattern in coal failure process. The internal mechanical property decides the inherent tendency of stressed coals to perform brittle or ductile behavior, and the responded AE activity pattern. The contrast of fissure distribution of specimens suggested that fissure structure in coal significantly affects the fracturing mode of coal in uniaxial compression and the AE activity pattern. The external stress condition has a transition effect on AE event energy distribution and AE activity pattern. Under the effect of external stress condition, the energy distribution of AE events was transforming between relative disperse and relative concentration, the failure type and AE activity evolution pattern of coal could appear the brittle-ductile transition. Based on the view of failure type, the pattern of AE activity of coal failure can be classified into three types, i.e., ductile, brittle, and semi-brittle pattern. It is suggested that the high-level AE activity can be viewed as the precursor of brittle instability of coal, and relative quiet phenomenon of AE activity as the precursor of ductile or semi-brittle instability. The research achievement can provide a theoretical base for the prewarning criteria establishment of coal and rock dynamic disasters at depth and improve the insight of AE activity in the coal failure process.
Highlights
With the increasing of mining depth, coal and rock dynamic disasters, such as coal and gas outbursts and coal bumps are becoming more and more serious in deep coal mines, and have graduallyEnergies 2018, 11, 1414; doi:10.3390/en11061414 www.mdpi.com/journal/energiesEnergies 2018, 11, 1414 become one of the major problems restricting safety and efficiency of production in mines
The Acoustic emission (AE) activity pattern in the failure process of stressed coals is the theoretical basis of this technology
AE experiments in the failure process of coal specimens with different properties and under different stress conditions were performed in laboratory to explore influence factors and their effect of AE activity, and AE activity pattern classification was discussed based on the failure type in this paper
Summary
With the increasing of mining depth, coal and rock dynamic disasters, such as coal and gas outbursts and coal bumps are becoming more and more serious in deep coal mines, and have graduallyEnergies 2018, 11, 1414; doi:10.3390/en11061414 www.mdpi.com/journal/energiesEnergies 2018, 11, 1414 become one of the major problems restricting safety and efficiency of production in mines. With the increasing of mining depth, coal and rock dynamic disasters, such as coal and gas outbursts and coal bumps are becoming more and more serious in deep coal mines, and have gradually. The mechanism of coal and gas outbursts disaster at depth is more complicated than that in the shallow. The traditional outburst prediction approach, which mainly focuses on quantitative detection of methane in coal seams and provides a successful solution of outburst hazard prediction in shallow seams, has not been able to meet the demand of disaster prevention in deep mines because of its weakness in reflection on stress factors. Acoustic emission (AE) technology is a prewarning method which can reflect the changes of rock mass stress and stability status [2,3,4]. Some AE researches and applications on coal bumps [8,9,10,11,12] and gas outburst [13,14,15] prewarning have been conducted in fields or laboratories
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