Application of Intra-Particle Combustion Model for Iron Ore Sintering Bed
Pingli Hou, Sangmin Choi, Won Yang, Eungsoo Choi, Heejin Kang
DOI: 10.4236/msa.2011.25048   PDF   HTML     6,045 Downloads   10,374 Views   Citations


In order to quantitatively predict the behavior of the material in the packed bed, a single particle model is developed to describe the combustion and sintering process inside an individual particle composed of multiple solid material fines, including iron ore, coke and limestone, and is applied to the combustion modeling of an iron ore sintering. Byanalyzing three typical fuel distribution cases using the developed single particle combustion model, the effects of temperature and oxygen concentration gradient inside the particle on heat and mass transfer and the combustion behavior of the iron ore sintering process areinvestigated. Considering the various combustion rates which are highly dependent on the fuel distribution methods, correction factor for single particle model is also introduced and systematically analyzed. The aim of this research is to supplement particle technology to conventional approach and it is found that the oxygen concentration gradient inside the particle is significantly affected from the mixing method thereby changing the completion times of sintering process.

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P. Hou, S. Choi, W. Yang, E. Choi and H. Kang, "Application of Intra-Particle Combustion Model for Iron Ore Sintering Bed," Materials Sciences and Applications, Vol. 2 No. 5, 2011, pp. 370-380. doi: 10.4236/msa.2011.25048.

Conflicts of Interest

The authors declare no conflicts of interest.


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