Smelting of Iron Ore in Fe-Cr-C-Si Melts

Direct smelting of the South African Sishen hematite ore in Fe-Cr-C-Si melts was studied, where the aim was to increase the Fe/Cr ratio of high carbon ferrochrome melts in order to approach stainless steel compositions. Experiments in the temperature range of 1600°C to 1750°C were conducted in an in...

Full description

Saved in:
Bibliographic Details
Published in:Materials and manufacturing processes 2008-10, Vol.23 (8), p.764-768
Main Authors: Vardar, E., Eric, R. Hurman
Format: Article
Language:English
Subjects:
Activation energy
Carbon
Chromium
Dissolution
Equilibrium
Ferrochrome
Iron
Iron ore
Kinetics
Reduction
Silicon
Slag
Smelting
Stainless steel
Transport phenomena
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Direct smelting of the South African Sishen hematite ore in Fe-Cr-C-Si melts was studied, where the aim was to increase the Fe/Cr ratio of high carbon ferrochrome melts in order to approach stainless steel compositions. Experiments in the temperature range of 1600°C to 1750°C were conducted in an inductively heated rotating cylinder technique furnace; however, due to the very fast nature of the reactions, the sintered iron ore cylinders were not rotated. The molten alloy contained 50% Cr, 0.25 to 8% C, and 1.5 to 7% Si, balance being Fe. Relevant slag metal equilibrium in the system was determined from literature and Scanning Electron Microscope (SEM) examinations. In Fe-Cr-C melts, the rate increased with increasing temperature and was independent of the carbon concentration while it decreased with decreasing Cr content of the metal. At 1600°C, the formation of a carbide layer surrounding the iron oxide was observed to be a kinetic barrier for reduction. At 1650°C and higher temperatures, a mixed rate control was suggested. When the melt contained Si, the rate again increased with temperature and was independent of Si concentration. The rate limiting factor in Fe-Cr-Si melts was suggested as the diffusion of Si in the formed slag phase. In the presence of both carbon and silicon in the alloy phase the reduction rate was similar to the rates in Fe-Cr-Si melts.
ISSN:1042-6914
1532-2475
DOI:10.1080/10426910802382007