Abstract
The induration of magnetite pellets is a complex physico-chemical process that involves oxidation, sintering, and heat transfer. The thermal- and gas-composition profile that is experienced by the pellet in an induration reactor could result in the formation of a homogenous or heterogeneous pellet structure, which could affect the pellet quality. The oxidation kinetics of magnetite pellets from sintering studies have been studied at two levels, namely, the pellet scale and at the particle scale, and the findings of the latter are presented here. The rate of oxidation of the magnetite concentrate depends primarily on temperature, oxygen content in the oxidizing gas, and particle size. These factors are investigated in this study. It was found that the oxidation of the magnetite concentrate is comprised of two distinct stages, a primary stage with high rates followed by a secondary stage where rates decrease significantly. The isothermal oxidation behavior as analyzed by the Avrami kinetic model was found to fit better than the shrinking-core model. The partially oxidized particles were examined microstructurally to supplement the experimental and model results. The Avrami kinetic model for isothermal oxidation was extended to non-isothermal profiles using the superposition principle, and the model was validated experimentally.
Highlights
THE pelletization of iron-ore fines is one of the widely practiced agglomeration techniques in iron and steel making because it enables the use of a very fine concentrate
We investigated the oxidation phenomenon of magnetite concentrate from the Luossavaara-Kiirunavara Aktiebolag (LKAB) mine in Malmberget, Sweden at the particle scale; estimated the oxidation kinetics; and determined the responsible mechanisms
The oxidation fraction increases initially at a rapid rate, and thereafter plateaus where the oxidation increases gradually at a constant oxidation rate. This implies that magnetite oxidation at the particle scale is a two-step phenomenon, which is in line with the findings reported by several researchers.[2,7,15,22,23]
Summary
THE pelletization of iron-ore fines is one of the widely practiced agglomeration techniques in iron and steel making because it enables the use of a very fine concentrate. Iron-ore pellets offer several advantages over other ferrous burdens in terms of strength, reducibility and uniformity of shape (spherical), chemistry, and porosity. Magnetite pelletization provides an added benefit in terms of energy, owing to the exothermic nature of its oxidation to hematite.[1] Magnetite ore that is excavated from mines is crushed, beneficiated, and ground into fines concentrate. The concentrate is balled into green pellets with the addition of moisture and additives, such as flux and binder. Thereafter, green pellets are fired in an induration furnace to impart
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