A Simulation Methodology for the Design of Eco-efficient Comminution Circuits
The traditional comminution circuit is a major consumer of energy-both as electrical energy and through consumption of media and wear resistant liners. Up to 40% of electrical energy consumed at a mine site is attributed to comminution however only a few percent of this energy is used in the generation of new surfaces from size reduction.This paper describes the evaluation of modifications using simulation models based on two operating comminution circuits. The aim of these modifications is to decrease both the amount of electrical energy consumed in the size reduction process, known as direct energy, as well as to decrease the consumption of grinding consumables such as steel grinding media and mill liners, designated as indirect energy.The approach is two-fold: · Employ, where possible, autogenous grinding techniques to eliminate the need for grinding media and reduce mill liner wear. · Optimise the use of the grinding energy distribution in the comminution circuit by using more energy efficient grinding devices to target typically problematic features of a comminution circuit such as critical size material from the primary mill and overgrinding in the secondary mill.The investigations show that significant total energy savings, as high as 50% in some cases, can be achieved by employing the techniques described while maintaining circuit throughput and product size. Investigations also show potential benefits in downstream flotation processes as the product size distribution generated from the eco-efficient circuit is generally narrower in shape for improved flotation performance and containing less material in the coarse fraction for overall better liberation.
Z. Pokrajcic R. Morrison
Julius Kruttschnitt Mineral Research Centre, Australia
国际会议
XXIV International Mineral Processing Congress(第24届国际矿物加工大会)
北京
英文
481-495
2008-09-24(万方平台首次上网日期,不代表论文的发表时间)