Interaction Between Mineral Phases in a Hematite Iron Ore and Fluxing Materials During Sintering
journal contribution
posted on 2024-11-17, 13:12authored byHuibin Li, David J Pinson, Paul Zulli, Liming Lu, Raymond J Longbottom, Sheng J Chew, Brian J Monaghan, Guangqing Zhang
The interaction between mineral phases in two commercial iron ores and flux materials (CaO, MgO, SiO , and Al O ) was studied under 0.5 kPa O partial pressure while heating to different temperatures. CaO was the most effective flux for liquid phase generation during sintering. For a hematite ore with few gangue components (Ore A), the formation of an initial liquid phase commenced at ~ 1275 °C, with the liquid volume increasing dramatically as temperature increased to 1300 °C. For a goethite containing hematite ore (Ore B), the formation of an initial liquid phase through interaction between goethite and CaO was observed when heating to 1225 °C, with the majority of goethite transformed to liquid at 1250 °C. The porous morphology of sintered goethite and finely distributed quartz results in a high reactivity with CaO. The initial liquid phase penetrated into the pores within the hematite matrix, promoting assimilation and by 1300 °C, all hematite in Ore B was dissolved. The hematite/martite phase in Ore B was much easier to assimilate than that in Ore A due to the presence of goethite. MgO diffused into hematite ore grains by solid-state diffusion and formed a solid solution (Fe, Mg)O∙Fe O without the formation of a liquid phase. The reaction layer formed by MgO diffusion was limited to approx. 60 μm at 1300 °C. The porous morphology in goethite facilitated MgO diffusion. However, the cavities and cracks caused by goethite dehydration significantly restricted solid phase diffusion of Mg . There was no observed interaction between Al O and SiO with Ores A and B when heated to 1300 °C. 2 2 3 2 2 3 2 3 2 2+
Funding
BlueScope Steel (IH130100017)
History
Journal title
Metallurgical and Materials Transactions B: Process Metallurgy and Materials Processing Science