Experimental study on the crack propagation characteristics of drilled-slit and grouted rock samples based on CT three-dimensional scanning

Gas leakage in cross-layer drainage boreholes compromises methane extraction efficiency through reduced concentration and recovery rates, while increasing residual gas content and coal outburst risks. This phenomenon further exacerbates operational hazards, including excessive gas emissions during mining activities and potential coal-gas outburst incidents. To address sealing challenges in deep coal seams, this study conducts an inquiry into the effectiveness of slit-grouting technology through triaxial compression tests and industrial CT scanning. The experimental protocol examines strength variations and fracture propagation patterns in rock specimens under different slit configurations. Key findings indicate that increased slit quantity enhances fracture network complexity while improving grout distribution uniformity. However, it simultaneously reduces specimen strength (by 3.3–12.1 %) and permeability (by 0.66–18.94 % compared to the unslitted grouted sample, G0). Post-failure analysis demonstrates linear correlations between slit quantity and three-dimensional fracture parameters: fracture volume (by 2.52–40.12 %) and fractal dimension (+0.0849 units per slit) increase proportionally, while Euler number decreases correspondingly (R²=0.84). Pore network analysis indicates enhanced topological connectivity with additional slits. Optimization studies identify single-slit configuration as optimal, balancing structural integrity with effective sealing performance. These findings establish a scientific foundation for advanced sealing technologies, offering dual benefits in outburst prevention and methane emission control - indispensable for sustainable mining operations and greenhouse gas mitigation.