Abstract
Abstract High-steep slope stability and its optimal excavation design in Shuichang open pit iron mine were analyzed based on a large 3D physical simulation technique. An optimal excavation scheme with a relatively steeper slope angle was successfully implemented at the northwest wall between Nos. 4 and 5 exploration lines of Shuichang Iron Mine, taking into account the 3D scale effect. The physico-mechanical properties of rock materials were obtained by laboratory tests conducted on sample cores from exploration drilling directly from the iron mine. A porous rock-like composite material was formed for the model, and the mechanical parameters of the material were assessed experimentally; specifically, the effect of water on the sample was quantitatively determined. We adopted an experimental setup using stiff modular applied static loading to carry out a visual excavation of the slope at a random depth. The setup was equipped with acoustic emission (AE) sensors, and the experiments were monitored by crack optical acquirement, ground penetrating radar, and close-field photogrammetry to investigate the mechanisms of rock-mass destabilization in the high-steep slope. For the complex study area, the model results indicated a clear correlation between the model’s destabilization resulting from slope excavation and the collected monitoring information. During the model simulation, the overall angle of the slope increased by 1–6 degrees in different sections. Dramatically, the modeled excavation scheme saved over 80 million tons of rock from extraction, generating enormous economic and ecological benefits.
Highlights
Many approaches such as engineering-geological analysis, the limit equilibrium method and numerical simulation are used to analyze the high-steep slope stability of open pit mines [1,2,3,4,5]
A summary of the rock quality designation (RQD) results for the five holes is presented in Table 1, which indicates that the general RQD of open pit mine rock masses is medium
Physical modeling experiments are measureable research techniques where the physico-mechanical properties of actual rock masses are modeled by manufactured materials that are similar to the actual rocks
Summary
Many approaches such as engineering-geological analysis, the limit equilibrium method and numerical simulation are used to analyze the high-steep slope stability of open pit mines [1,2,3,4,5]. In sharp contrast with theoretical analysis, physical modeling is one of the most useful approaches in rock mechanics with unique advantages for the study of high-steep slope stability [6,7,8,9,10]; in particular, a large 3D physical modeling experiment can accurately provide deformation and fracture characteristics of rock masses in the slope being prerequisite for the prediction of dynamic destabilization and quantitative excavation design of high-steep slopes [11,12,13,14,15]. The large-scale model includes all of the geological and mechanical complexity of the high-steep slope in the actual open pit iron mine, and provides a quantitative analysis of the mechanism of high-steep slope destabilization
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