Enhancing Fine Iron Ore Flotation Using the Direct Flotation Reactor (DFR®): Pilot Results and Full Scale Evaluation

The flotation of Brazilian fine iron ore particles presents well-documented challenges, particularly the high entrainment of iron into the quartz (tailings) stream, resulting in significant iron losses and reduced circuit efficiency. This paper evaluates the application of Woodgrove’s Direct Flotation Reactor (DFR®) technology, which has been piloted by Vale as a potential solution to these challenges. The DFR is assessed from a pilot scale and process design perspective, with emphasis on its staged flotation mechanism, energy dissipation characteristics, and concentrate handling mechanism that together collectively enhance the selective recovery of fine iron particles. The DFR’s operation is contrasted with conventional tank cells, highlighting its improved control over bubble-particle interactions, reduced entrainment, and potential for higher selectivity. The DFR pilot plant was used to perform reverse cationic flotation of a quartz-rich froth phase to upgrade the iron ore. Pilot plant results are presented, comparing DFR performance with pilot-scale conventional flotation tests on the same feed material and relevant industrial benchmarks. This paper compares a conventional mechanical cell circuit performance and design with a proposed DFR configuration for two -45μm deslimed size fraction samples, analysing parameters such as footprint, energy efficiency, reagent consumption, and overall metallurgical performance. The findings show that DFR technology has the potential to significantly improve the fine hematite selectivity in quartz flotation for iron ore applications, offering a pathway to increased resource efficiency and reduced losses to tailings.