Numerical simulation of optimum mining design for high stress hard-rock deposit based on inducing fracturing mechanism
(1. School of Resources and Safety Engineering, Central South University, Changsha 410083, China;
2. Guizhou Kaiyang Phosphate Mine Group Co., Guiyang 550302, China)
2. Guizhou Kaiyang Phosphate Mine Group Co., Guiyang 550302, China)
Abstract: The 3D numerical simulation model of deep hard-rock deposit in Kaiyang Phosphate Mine of Guiyang was established based on the practical engineering using 3DEC numerical simulation software. The distribution characteristics of displacement fields and plastic zones of the orebody were simulated in three different excavation cases, including the case of excavation artificial inducted roadway in the orebody, the case of horizontal or vertical excavation direction and the case of the upward or downward excavation order. The simulation results indicate that the plastic zone and displacement field of surrounding rock around the inducted roadway are continuously increasing with the increase of the exposure time after digging an artificial inducted roadway in the orebody. Thus the raw rock ore becomes easier to be fragmented, which provides advantageous conditions for roadheader to cut high stress hard-rock. It is worthy noting that there is a large difference in effective utilization of deep ground pressure between horizontal and vertical excavation directions. The later can produce larger deformation and fracture zone than the former on the rock mass around the deduced roadway, which means that the later may utilize the high ground pressure more effectively to break hard-rock. And the obtained results also show that upward excavation order is more helpful for ground pressure to break rock than downward excavation order.
Key words: inducted fracturing; high stress hard-rock deposit; excavation case; roadheader excavation; numerical simulation