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Fe–P Alloy Production from High-Phosphorus Oolitic Iron Ore via Efficient Pre-Reduction and Smelting Separation
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Fe–P Alloy Production from High-Phosphorus Oolitic Iron Ore via Efficient Pre-Reduction and Smelting Separation
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Fe–P Alloy Production from High-Phosphorus Oolitic Iron Ore via Efficient Pre-Reduction and Smelting Separation
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Journal Article
Fe–P Alloy Production from High-Phosphorus Oolitic Iron Ore via Efficient Pre-Reduction and Smelting Separation
2025
Overview
Diverging from conventional dephosphorization approaches, this study employs a novel pre-reduction and smelting separation (PR-SS) to efficiently co-recover iron and phosphorus from high-phosphorus oolitic iron ore, directly yielding Fe–P alloy, and the Fe–P alloy shows potential as feedstock for high-phosphorus weathering steel or wear-resistant cast iron, indicating promising application prospects. Using oolitic magnetite concentrate (52.06% Fe, 0.37% P) as feedstock, optimized conditions including pre-reduction at 1050 °C for 2 h with C/Fe mass ratio of 2, followed by smelting separation at 1550 °C for 20 min with 5% coke, produced a metallic phase containing 99.24% Fe and 0.73% P. Iron and phosphorus recoveries reached 99.73% and 99.15%, respectively. EPMA microanalysis confirmed spatial correlation between iron and phosphorus in the metallic phase, with undetectable phosphorus signals in vitreous slag. This evidence suggests preferential phosphorus enrichment through interfacial mass transfer along the pathway of the slag phase to the metal interface and finally the iron matrix, forming homogeneous Fe–P solid solutions. The phosphorus migration mechanism involves sequential stages: apatite lattice decomposition liberates reactive P2O5 under SiO2/Al2O3 influence; slag–iron interfacial co-reduction generates Fe3P intermediates; Fe3P incorporation into the iron matrix establishes stable solid solutions.
