Enhancing Oxidation and Energy Utilisation by Controlling O₂ and Gas Flow in Magnetite Pellet-Bed Induration

抄録

As Sweden transitions to hydrogen-based steel production, excess O₂ generated as a byproduct of H₂ production through water electrolysis is likely to be available. This presents an opportunity to use extra O₂ for reducing fuel consumption during production of iron ore pellets. Considerable heat is released as magnetite is oxidised to hematite during induration. Increased O₂ content in the process gas is expected to accelerate the exothermic oxidation reaction, allowing faster intrinsic heating of the bed. This study examines various energy scenarios utilising O₂-enriched gas (40 vol% O₂) relative to a base case that uses low-O₂ gas (13 vol% O₂). The focus is the effects of the flow rates and O₂ contents in the inflow gas on the temperature development and physicochemical properties (oxidation degree and cold compression strength) of pellets across a 100-kg pot furnace bed. Enriching the inflow gas with O₂ has advantages with regard to the aforementioned properties. Notably, utilising O₂-enriched gas at a reduced flow rate (in this case, 30% less gas volume compared with the base case) enables improved heat distribution relative to the base case with low-O₂ gas. In addition to the effects on the energy and pellet properties, the microstructures are analysed with respect to the underlying oxidation mechanisms.