Studies on the reduction behavior of Iion oxide pellet fines with hydrogen gas : mechanism and kinetic analysis
Hammam, Abourehab; Nasr, M. I.; Elsadek, M. H.; Khan, Inam Ullah; Omran, Mamdouh; Wei, Han; Qiu, Dejin; Yu, Yaowei (2023-08-11)
Hammam, A., Nasr, M.I., Elsadek, M.H. et al. Studies on the Reduction Behavior of Iron Oxide Pellet Fines with Hydrogen Gas: Mechanism and Kinetic Analysis. J. Sustain. Metall. 9, 1289–1302 (2023). https://doi.org/10.1007/s40831-023-00721-1
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https://urn.fi/URN:NBN:fi-fe20230918131146
Tiivistelmä
Abstract
The present study contributes to the current worldwide activities aiming to replace fossil carbon in steel making processes with hydrogen causing considerable reduction of greenhouse gas emissions. Compacts prepared from iron oxide pellets fines were isothermally reduced in pure hydrogen gas and a mixture of hydrogen and argon in the temperatures range from 700 to 1100 °C. The total weight loss produced during the reduction process was continuously recorded using thermogravimetric analysis (TG) technique. The findings demonstrated that the temperature has a considerable impact on the conversion and reduction rates. At a given temperature, the reduction rate was accelerated as the amount of H₂ increased in the reducing gas. The results indicated that H₂ content does not have an effect on reduction behavior, when it is higher than 80%. The reduction reaction of samples was shown to takes place in a step wise manner from hematite to metallic iron. The reduction kinetic and mechanism were deduced from the application of mathematical models and the morphological structure of the reduced samples and correlated with the apparent activation energy (Ea) values. The Ea values at the early, intermediate and final stages were 16.36, 29.24 and 49.35 kJ/mole, respectively. The early stage of the reduction process was controlled by chemical reaction, whereas the gaseous diffusion was controlled the latter stage. At the intermediate stage, the reduction process was controlled by mixed mechanism of gaseous diffusion and chemical reaction.
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