Effect of pre-confining pressure on unloading-induced coalburst: Insights from distinct element modelling

Coalburst is a violent dynamic failure of coal during underground mining. It is of significance to study failure pattern as well as energy evolution and transition during coalbursts and how they are influenced by pre-confinement. This paper presents unloading-induced coalburst simulations using the distinct element method via a combined static-dynamic loading-unloading strategy. The numerical model is calibrated and validated by comparison with the failure process observed in laboratory tests. The influence of pre-confining pressure on unloading-induced coalburst was numerically investigated from the perspective of crack propagation, fracturing process, failure pattern, and energy evolution. In addition, failure mechanism and energy conversion during coalbursts under different pre-confining pressures are discussed. The results show that the stress change caused by sudden unloading of the pre-confining results in the initiation and development of cracks. Crack density and crack propagation velocity increase with increasing pre-confining pressure. As the pre-confining pressure increases, the coalburst becomes more intense and takes less time to be completed, and the main failure pattern in coalburst transforms from a tensile type to a shear type. In addition, the conversion ratio of kinetic energy and frictional energy during coalbursts increase non-linearly with increasing pre-confining pressure.

Automated summary

This study conducts simulations of unloading-induced coalbursts using the distinct element method. The numerical model is calibrated and validated by comparison with laboratory tests. The influence of pre-confining pressure on coalbursts is investigated, with a focus on crack propagation, fracturing process, failure pattern, and energy evolution. The results show that increasing pre-confining pressure leads to more intense coalbursts with faster completion time, and the main failure pattern transforms from tensile to shear type. Additionally, the conversion ratio of kinetic energy and frictional energy during coalbursts increases non-linearly with increasing pre-confining pressure.