Abstract
To research the dynamic response characteristics of coal mass under impact loads, based on LS-DYNA software, rigid body bars are simulated to impact coal mass under different speed conditions, and the dynamic distribution characteristics of the stress, strain and energy of coal mass are analyzed. The results demonstrate that (1) the peaks of the axial and radial stresses and strain on the central axis and the radial line obey the power function distribution; at the same position, the axial and the radial stress peaks are close, and the axial strain peak is from much larger than the radial strain peak to close to. (2) The axial and radial stresses generate tensile stresses in the axial and radial propagation directions, respectively, and the coal mass is prone to damage under tensile stress. (3) When the speed is large, the axial stress–strain curve is similar to that of the dynamic load experiment. The axial stress peak, axial strain peak, critical effective stress, critical time and secant modulus have a linear relationship with the velocity. (4) When the dynamic load is large, most of the energy is in the form of kinetic energy, and the total energy loss also increases.
Highlights
To research the dynamic response characteristics of coal mass under impact loads, based on LS-DYNA software, rigid body bars are simulated to impact coal mass under different speed conditions, and the dynamic distribution characteristics of the stress, strain and energy of coal mass are analyzed
When the speed is large, the axial stress–strain curve is similar to the stress–strain curve of the coal under the dynamic load experiment
The coal mass is prone to damage under tensile stress, and the tensile stress generated by numerical simulation is consistent with that of the theoretical analysis of the stress waves
Summary
To research the dynamic response characteristics of coal mass under impact loads, based on LS-DYNA software, rigid body bars are simulated to impact coal mass under different speed conditions, and the dynamic distribution characteristics of the stress, strain and energy of coal mass are analyzed. The damage mechanism of a coal mass under dynamic loading has been modeled with a split-Hopkinson pressure bar (SHPB)[27,28,29,30,31,32]. Yin et al.[36] obtained that the dynamic compressive strength of gas-containing coal under coupled load decreases with increasing initial gas pressure using the SHPB experiment of coal samples. Yang et al.[39] used the SHPB experiment of coal samples to obtain a linear relationship between the dynamic compressive strength and the applied strain rate. Viljoen et al.[42] analyzed the impact of the internal structure of a coal sample on coal breakage based on impact experiments with coal particles
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