Study on control of dynamic disaster induced by high-level ETHR fracture by ground fracturing

Fracture of high-level extra thick and hard roof (ETHR) above the coal seam is the main reason for the frequent occurrence of mine dynamic disasters such as mine earthquake and rock burst. In order to address this problem, the ground fracturing technology was proposed in this paper to presplit the high-level roof. The FLAC numerical model was established to study the dynamic response of the ETHR before and after fracturing. The simulation results show that: The existence of hydraulic fracture can effectively reduce the first breaking span of ETHR, and slow down the stress and elastic deformation energy concentration of coal and rock mass on both sides of goaf. In order to ensure the economical and effective opening of prefabricated cracks, the comprehensive influence of tensile stress zone and induced stress between cracks should be fully considered in the design of crack spacing. Finally, the field test of hydraulic fracturing was carried out in 63(up)06 working face in Dongtan coal mine in China. The results of microseismic monitoring showed that there were only 4 strong mine earthquake events of magnitude 2.0 that happened in the first 400 m of excavation, compared with the adjacent working face, the number of large energy mining earthquake events decreased significantly. It showed that the ground fracturing effectively controlled the high and thick strata and verified the feasibility of the ground fracturing technology. The research results can provide some guidance for the treatment of mine earthquake and rock burst in similar working face.

Automated summary

This paper proposes the ground fracturing technology to pre-split the high-level roof, aiming to address the frequent occurrence of mine dynamic disasters such as mine earthquake and rock burst. The FLAC numerical model is used to study the dynamic response of the roof before and after fracturing. The simulation results show that the presence of hydraulic fracture can effectively reduce the first breaking span of the roof and slow down the stress and deformation energy concentration of coal and rock mass on both sides of the goaf.