Abstract
SYNOPSIS Cave mining is an underground mass mining technique. The largest projects, which are known as 'super caves', produce hundreds of thousands of tons of ore per day, which involves large footprints with considerable column height, and have a life of mine of over 20-40 years. These operations are typically located deep, under high stresses and in competent rock masses, making initiation and propagation of the caving process harder to manage. These challenges must be confronted by optimizing the fragmentation of the orebody to achieve smaller size blocks that will result in consistent caving and improved flow of the ore from the drawpoints. To achieve better performance from the drawpoints, preconditioning is applied to fragment and damage the material required to cave. We present a proposed design for preconditioning in underground mines, considering the challenges that these large-scale mines are already facing, based on a comprehensive analysis of current design parameters, case studies, and sensitivity analyses using numerical models. Keywords: fragmentation, preconditioning, caving, blasting, structures, stresses, explosives.
Highlights
Caving operations undermine a massive orebody to initiate the collapse, comminution, and flow of the ore to multiple drawpoints
The work presented in this paper describes the modelling process for alternative forms of preconditioning to optimize fragmentation of the rock mass
This translates into a low powder factor of around 0.045 kg/m3, and it is surprising that the results showed a significant change in the fragmentation of the rock mass: the in-situ block size of 2 × 1 m being reduced to a P80 of 1.4 to 0.7 m at the drawpoints
Summary
Caving operations undermine a massive orebody to initiate the collapse, comminution, and flow of the ore to multiple drawpoints. Cave mining operations are facing greater challenges due to greater depths. Besides the depth of the mines, the rock mass presents challenging characteristics, with fewer open structures, or joints filled with cohesive material; both conditions causing difficulties for the mining process, the caving of the ore, fragmentation, and seismicity. To mitigate the difficulties, preconditioning (PC) has been implemented in Chile to weaken the rock mass by hydraulic fracturing (HF), and this has shown favourable results in terms of the seismic response of the cave. The work presented in this paper describes the modelling process for alternative forms of preconditioning to optimize fragmentation of the rock mass
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