Abstract
Based on the superposition principle of fracture dynamics, the disturbance caused by dynamic blasting loads on the expansion of primary cracks in a typical slope was examined in this study. The stress intensity factor of the collinear double crack tip under the condition of mixed-mode dynamic and static loading was calculated. A dynamic response evaluation index was established, and the influence rules of blasting load amplitude, crack inclination angle, crack length, and crack spacing were analyzed theoretically. A collinear double-crack combination model was established and operated using ABAQUS software. The dynamic blasting load is shown to markedly increase crack propagation. Cracks with a 45° inclination angle are most intensely affected by the dynamic load. The crack length increases continuously as new cracks emerge under static load conditions; the dynamic load accelerates the penetration of the crack system. When the crack spacing is small, the penetration between them occurs more quickly. When the crack spacing increases to 10 mm, the unit shows multiple single crack failure modes. Response surface methodology was applied to obtain the multiple regression fitting function, which validates the theoretical analysis results. This work may provide a valuable reference for similar projects.
Highlights
Blasting is one of the most common rock slope excavation operations in open-pit mines
Zuo et al.6,7 derived the relationship between the initial crack angle and the load based on linear elastic fracture mechanics
Crack propagation through a rock mass is affected by dynamic loading during the blasting process
Summary
Blasting is one of the most common rock slope excavation operations in open-pit mines. Bohloli and De Pater, for example, studied the crack initiation and propagation mechanisms in rock masses under different surrounding rock stress conditions. Zhou et al. carried out indoor dynamic tests on artificial rock specimens with three-dimensional (3D) embedded cracks produced by 3D printing and studied their volume fracturing and mechanical properties under high strain rate impact conditions. Crack propagation through a rock mass is affected by dynamic loading during the blasting process. Most studies have been qualitative, where numerical software or specimen tests are used to simulate the crack propagation path—there is no fully accurate or effective quantitative analysis method for the mixed-mode stress intensity factor (mSIF) of dynamic and static load compound crack tips in rock masses with multiple cracks. The fracture characteristics of collinear cracks in rock mass under dynamic and static mixed-mode loading conditions were investigated in this study based on the superposition principle. The simulation results were compared against theoretical results to validate the derivation
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