Decarburisation of Liquid Fe-C-S Drops Using Multiple Oxidants of O₂, CO₂ and H₂O

Abstract

The decarburisation of liquid Fe-C-S drops was studied at 1723 K employing the electromagnetic levitation technique with two different types of gas mixtures, namely, mixtures of O₂ and CO₂, and mixtures of O₂ and H₂O. For the decarburisation with O₂ and CO₂, the rate is limited by the O₂ and CO₂ transport in the gas phase with additional resistance arising from the interfacial reaction kinetics of CO₂. Sulphur significantly reduces the surface reaction rate with CO₂, and the retarding effect appears to be enhanced by existence of the simultaneous oxygen decarburisation. For the simultaneous decarburisation by O₂ and H₂O, the basic mechanism of decarburisation is similar to that of O₂ and CO₂, but there exists evidence that the homogeneous gas phase flame reaction of O₂ and CO to produce CO₂ occurs in the vicinity of the interface. This results in a much lower rate of decarburisation than the expected one, since portion of the incoming O₂ gas is converted to CO₂ and the rate of decarburisation with CO₂ is slower to a great extent than that with O₂. The conversion rate is increased as the sulphur content in the melt is increased, and this is attributed to the increase in H₂O in the vicinity of the interface with increase in sulphur. Mixed control models are developed and found to adequately explain the observed results.