TRANSACTION PAPER

 

Development of a gravity flow numerical model for the evaluation of drawpoint spacing for block/panel caving

 

 

R.L. Castro^I; F. Gonzalez^II; E. Arancibia^III

^IMining Engineering Department, Mining Technology Center, University of Chile, Santiago, Chile
^IIMining Engineering Department, University of Chile, Santiago, Chile
^IIICodelco, Chile

 

 

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SYNOPSIS

Block caving methods, when operated under favourable rock mass conditions, can achieve higher production rates and lower operating costs than other various existing underground mining applications. For this reason, it has been considered the preferred method for the mining of deep and large orebodies in current and future operations around the world. One of the key aspects in the design of block caves is the selection of the production level layout, which, among other parameters, is based on the gravity flow characteristics of the caved rock. This is because gravity flow has a large impact on total ore recovery and the amount of dilution in a caving operation. Today, there are a number of computer based methods which aim to emulate the gravity flow pattern of the caved rock.
In this paper, the authors present the development of FlowSim an improved model of gravity flow based on the cellular automaton approach, to estimate dilution entry, mixing and ore recovery. As part of the model development, flow simulations were conducted and subsequently compared to full-scale data collected at two mine sectors operated by Codelco Chile. The results indicate that by using proper calibrated parameters, good correlations between simulated and measured grades as well as dilution entry are obtained. The potential use of the numerical tool to evaluate drawpoint spacing in terms of recovery and dilution for block/panel caving operations is also presented.

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