Abstract
The aim of this study is to evaluate the effect that the size of grinding media exerts on ferronickel slag milling efficiency and energy savings. A series of tests were performed in a laboratory ball mill using (i) three loads of single size media, i.e., 40, 25.4, and 12.7 mm and (ii) a mixed load of balls with varying sizes. In order to simulate the industrial ball milling operation, the feed to the mill consisted of slag with natural size distribution less than 850 μm. Grinding kinetic modeling and the attainable region (AR) approach were used as tools to evaluate the data obtained during the ball milling of slag. Particular importance was given to the determination of the specific surface area of the grinding products, the identification of the grinding limit, and the maximum specific surface area which could be achieved when different grinding media sizes were used. The results showed that, in general, the breakage rates of particles obey non-first-order kinetics and coarse particles are ground more efficiently than fines. The AR approach proved that there is an optimal grinding time (or specific energy input) dependent on the ball size used for which the volume fraction of the desired size class is maximized. The use of either 25.4 mm balls or a mixed load of balls with varying sizes results in 31 and 24% decrease in energy requirements, compared to the use of balls with small size (12.7 mm).
Highlights
Slags generated from the non-ferrous, ferrous and steel industries, as well as residues produced from various hydrometallurgical operations, are becoming a subject of great environmental and ecological debate [1]
The grinding behavior of the slag was investigated by identifying the relationship between the remaining (% volume) fraction for six representative particle sizes vs. grinding time, when three loads of grinding media with the same ball size, namely 40 mm, 25.4 mm, 12.7 mm, and an additional load consisting of equal mass of balls from each size were used (Figure 1a–d)
In this study grinding of ferronickel slag was investigated in a laboratory ball mill, to determine the effect of grinding media size on milling efficiency using kinetics and attainable region approaches
Summary
Slags generated from the non-ferrous, ferrous and steel industries, as well as residues produced from various hydrometallurgical operations, are becoming a subject of great environmental and ecological debate [1]. Slags have found a wide range of applications in the construction, cement, and fertilizers industries, and can be considered as secondary sources for base metals, especially iron and copper [3]. The alkali activation of various slags for the production of materials or binders that can be used in construction applications is extensively investigated [8,9]. The increase of the utilization rate of slags and the development of sustainable management schemes for environmental protection are of great importance for both the industry and the society [10,11,12]
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