Abstract
To research the failure mechanism of the layer-crack structure of surrounding rock in deep mine roadway, the combination (Layer-Intact structure) of shallow layer-crack coal and deep complete coal was taken as the research object, and the mechanical behavior and energy evolution law of the Layer-Intact structure under uniaxial and biaxial compression were studied by numerical simulation with particle flow code (PFC2D). The results show that: (1) In the Layer-Intact structure, layer-crack specimen is destroyed prior to intact specimen; The degree of fragmentation increases with the increase of confining stress, and decreases with the increase of fissure number; (2) The confining stress and the fissure number have a significant impact on the basic mechanical parameters of the Layer-Intact structure. The peak stress of the structure increases first and then decreases with the increase in the confining stress, and decreases with the increase in the fissure number; (3) When fissure number is constant, the energy ratio of layer-crack specimen (strain energy stored in the layer-crack specimen to the the whole specimen) increases first and then decreases with the increase in confining stress, while the energy ratio of intact specimen (strain energy stored in the intact specimen to the whole specimen) decreases first and then increases. When the confining stress is constant, with the increase in the fissure number, energy storage capacity of the Layer-Intact structure is reduced, the energy ratio of layer-crack specimen decreases, while the energy ratio of intact specimen increases. The research can provide some reference for revealing the energy release for dynamic instability of layer-crack structure.
Highlights
Under the influence of excavation disturbance, the joints and fracture in the surrounding rock develop continuously, which form the layer-crack structure in the roadside
AbstractTo research the failure mechanism of the layer-crack structure of surrounding rock in deep mine roadway, the combination (Layer-Intact structure) of shallow layer-crack coal and deep complete coal was taken as the research object, and the mechanical behavior and energy evolution law of the Layer-Intact structure under uniaxial and biaxial compression were studied by numerical simulation with particle flow code (PFC2D)
The peak stress of the structure increases first and decreases with the increase in the confining stress, and decreases with the increase in the fissure number; (3) When fissure number is constant, the energy ratio of layer-crack specimen increases first and decreases with the increase in confining stress, while the energy ratio of intact specimen decreases first and increases
Summary
It is necessary to study the failure mechanism of the layer-crack structure. Many scholars have carried out a lot of researches on the instability of the layer-crack structure using many methods such as numerical simulationǃlaboratory test [4,5,6]. The dynamic instability mechanism of the layer-crack structure was analyzed from several aspects. The research object mainly focused on shallow layer-crack coal mass, but the deep intact coal mass played an important role on the layer-crack structure failure. We investigated the instability mechanism of the Layer-Intact structure system composed of deep intact coal mass and shallow layer-crack coal mass with PFC2D, and further reveal the failure and energy release law of the Layer-Intact structure
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