This study presents a non-equimolar diffusion model to enhance the predictive accuracy of coke degradation kinetics in hydrogen-rich blast furnaces, where elevated water vapor (HO) levels are present. The model integrates the unreacted core shrink model with the Maxwell-Stefan equation to delineate the 3D curved surface distribution of HO concentration and the effective diffusion coefficient within the coke ash layer. Validated against experimental data, the model demonstrated a significant improvement in accuracy, with a deviation range of 0.77%-3.5%, compared to the 15.61%-18.92% deviation for the traditional unreacted core shrink model. This advancement is crucial for optimizing blast furnace design and operation, supporting the industry's transition toward low-carbon ironmaking. The findings highlight the importance of considering non-equimolar diffusion in the reaction kinetics between coke and HO, contributing substantially to the scientific understanding and technological advancement in ironmaking.
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| http://dx.doi.org/10.1016/j.isci.2024.111181 | DOI Listing |
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