Abstract
Flotation is a complex process that exhibits high dimensionality which makes modeling and optimization very challenging. One technique to alleviate the dimensionality problem is to combine variables together into more informative ones. Bubble surface area flux and air recovery are examples of dimensionality reduction. Gas holdup also captures the effect of a plurality of variables including gas rate, bubble size, surfactant type, and concentration. This work makes use of a dual flotation–conductivity cell to explore the relationship between gas dispersion properties, including frother concentration and flotation performance. Results demonstrate that gas holdup effectively captured the effect of gas rate and frother concentration and better correlates to flotation performance.
Funder
Chilean Council of Science and Technology
Subject
Geology,Geotechnical Engineering and Engineering Geology
Reference37 articles.
1. Selection of flotation reagents for mineral flotation;Mular;Design and Installation of Concentration and Dewatering Circuit,1986
2. Lynch, A.J., and Elber, L. Modelling and control of mineral processing plants. Proceedings of the IFAC Mining, Mineral, and Metal Processing.
3. Prediction of grade and recovery in flotation from physicochemical and operational aspects using machine learning models;Gomez-Flores;Miner. Eng.,2022
4. The relationship between the peak in air recovery and flotation bank performance;Hadler;Miner. Eng.,2009
5. The effect of froth depth on air recovery and flotation performance;Hadler;Miner. Eng.,2012