Abstract
To explore the energy dissipation mechanism and damage evolution characteristics of rock specimens under compressive loading, we performed the acoustic emission (AE) testing under uniaxial compression in intact rock specimens and those with large-scale prefabricated cracks. The basic mechanical properties of both types of specimens were analyzed comprehensively, and the evolution patterns of strain energy indicators (total strain, elastic, and dissipative energies) in rock specimens before the peak on the stress-strain curve were identified. We further revealed the effect of the prefabricated crack dip angle, which controlled the surplus energy conversion of the following peak deformation and failure in the rock specimens. Using the modified equation of rock specimen damage evolution characterized by the AE energy and examining the fracture surface morphology via the scanning electron microscopy (SEM), the AE distribution law for rock specimen damage was revealed. An increase in the prefabricated crack dip angle was shown to reduce the peak stress and strain of rock specimens, which experienced a transition from the tensile and splitting failure mode to shear and slip one. Cracked rock specimens exhibited strain energy accumulation at the elastic deformation stage of the stress-strain diagram and rapid energy consumption at the plastic stage. By contrast, the intact rock specimens had a smoother energy evolution pattern. As the prefabricated crack dip angle increased, the dissipated and surplus strain energies’ shares increased. Moreover, the first peak of the AE energy occurred earlier, and the stress needed for its occurrence decreased as the dip angle increased. According to the damage evolution equation for rock specimens, their damage process can be subdivided into the initial damage, stable damage increase, and the accelerating damage increase stages. An increase in the prefabricated crack dip angle accelerated the damage accumulation in rock specimens. The locking effect of the sawtooth-like structures on the fracture surface was less conspicuous, and the fracture surface roughness increased. Thus, microcracks gradually developed, and rock specimens became more susceptible to sudden unstable failure.
Highlights
Coal mining involves roadway tunneling and stoping of working face, which usually leads to the exposure of such macroscopic geological structures as faults and joints. ese structures are sources of crack initiation and propagation, in which processes jeopardize the mining production safety and require in-depth analysis
Advances in Civil Engineering future [1, 2]. us, Yang et al [3, 4] studied the crack propagation and penetration mechanisms in rock specimens with prefabricated single and double cracks while Li et al [5] characterized the mechanical properties of precracked rock specimens under uniaxial compression
Wang et al [15] reported the rock specimens’ energy conversion features with nonpenetrating joints. e above studies provide a systematic analysis of the total strain, elastic, and dissipative energy components figuring in the stress-strain relationship of intact rock specimens, coal-rock mass combinations, and rock specimens with small-scale prefabricated cracks
Summary
Coal mining involves roadway tunneling and stoping of working face, which usually leads to the exposure of such macroscopic geological structures as faults and joints. ese structures are sources of crack initiation and propagation, in which processes jeopardize the mining production safety and require in-depth analysis. The identification of the energy evolution laws governing the damage and failure processes in rock specimens with largescale prefabricated cracks with various dip angles is very topical. E above studies provide a systematic analysis of the total strain, elastic, and dissipative energy components figuring in the stress-strain relationship of intact rock specimens, coal-rock mass combinations, and rock specimens with small-scale prefabricated cracks. The presence of macroscopic defects with increasing scales and dip angles in rock specimens increases the probability of their dynamic (impact) failure. Liu et al [21] described the damage variable by the share of dissipative energy in the total strain energy This definition was susceptible to the influence of the stiffness of the test machine and brittleness of the rock specimen. SEM was employed to analyze the damage features of the intact and precracked rock specimens. e research findings provide theoretical guidance for disaster prevention and control of mining production safety
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