Abstract
This study examines the isothermal and non-isothermal reduction behaviors of iron ore compacts in a pure hydrogen atmosphere and compares the results obtained during the reduction process by CO. The different phases accompanying the reduction reactions were identified using X-ray diffraction (XRD) and its morphology was microscopically examined. In isothermal experiments, temperature plays a significant role in the reduction process. At any given temperature, the reduction rate during the initial stages is higher than that during the final stages. The reduction rate in H2 atmosphere was faster than in CO gas. The comparison of activation energy values suggested that reduction with H2 is more efficient than with CO. At the same temperature, the time required to achieve a certain degree of reduction was lower when using H2 gas than CO atmosphere. In non-isothermal tests, the heating rate has a significant effect on the reduction rate and reduction extent. At the same heating rate, the degree of reduction was higher in H2 atmosphere than in CO gas. Based on experimental data, the parameters of reaction kinetics were deduced by application of model-free and model-fitting methods. The reduction in H2 atmosphere was controlled by nucleation model (Avrami-Erofeev model), while the CO reduction reaction was controlled by gas diffusion.
Highlights
Iron and steelmaking sector is one of the most important sectors due its great impact on the global growth, economy, and development
For any given reduction temperature, the rate of reduction is highest in the early stages and gradually decreases until the end of the reduction reaction
Understanding the kinetic analysis of non-isothermal conditions is helpful in the Direct reduction (DR) process and in hydrogen metallurgy
Summary
Iron and steelmaking sector is one of the most important sectors due its great impact on the global growth, economy, and development. El-Geassy et al [15, 16] studied the volume change of iron oxide compacts and the influence of gas composition on reduction behavior at 800 to 1100 °C They found that increased CO content in the gas mixture had a significant influence on swelling and maximum swelling (224%) was observed for samples reduced at 900 °C. Daniel et al [18] study the reduction kinetics of hematite iron ore fines by hydrogen gas using a laboratory fluidized bed reactor in a temperature range 873–1073 K. The present study aims to investigate the isothermal and non-isothermal reduction kinetics of iron ore fines in a hydrogen atmosphere, comparing the experimental results of H2 with those of CO. Correlate these predictions with the morphological structure to deduce the reduction mechanisms
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