Comprehensive Mathematical Model of Full Oxygen Blast Furnace with Top Recycle Gas Heated by Gasifier

Jia Le Meng; Hui Qing Tang; Zhan Cheng Guo

doi:10.4028/www.scientific.net/AMM.268-270.356

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 268-270Comprehensive Mathematical Model of Full Oxygen...

Comprehensive Mathematical Model of Full Oxygen Blast Furnace with Top Recycle Gas Heated by Gasifier

Abstract:

A comprehensive mathematical model of full oxygen blast furnace with top recycle gas heated by gasifier was established. The model consists of the calculation equations for gas composition of four zones (hearth, belly, lower shaft, top) in the blast furnace, the thermo-chemical balance model of blast furnace, the energy balance model of hot stand-by zone of blast furnace, the shaft efficiency model of blast furnace, the calculation equations for gas composition of gasifier and the thermo-chemical balance model of gasifier. By using this model, the new process was calculated. The results show that coke rate and coal rate of the new process are 200 kg/thm and 190 kg/thm respectively, fuel rate is decreased by 24.7% compared with that of conventional blast furnace. In addition, theoretical combustion temperature decreases with increasing hearth-recycle gas quantity. Increasing of hearth-recycle gas quantity by 10 m3/thm decreases theoretical combustion temperature by 11.6 K. Furthermore, the model could be applied to calculate the operating parameters when the raw materials and fuel conditions are different, and the changing laws of operating parameters under the same raw materials and fuel conditions could also be studied with this model.

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Periodical:

Applied Mechanics and Materials (Volumes 268-270)

Pages:

356-364

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.268-270.356

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Online since:

December 2012

Authors:

Jia Le Meng, Hui Qing Tang, Zhan Cheng Guo

Keywords:

CO₂, Full Oxygen Blast Furnace, Gasifier, Mathematical Models, Top Gas Recycling

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References

[1] Ministry of International Trade and Industry, in: Year book of Iron and Steel Statistics 2002, (MITI, Japan: 2003).

Google Scholar

[2] G. Danloy, A. Berthelemot and M. Grant, Rev Met Paris, Vol. 106 (2009), p.1

Google Scholar

[3] G. Q. Zuo and A. Hirsch, in: The trial of the top gas recycling blast furnace at LKAB's EBF and scale-up, Proceedings of the 4th Ulcos Seminar, p.1, Essen (2008).

DOI: 10.1051/metal/2009067

Google Scholar

[4] M. S. Qin, Z. K. Gao and G. L. Wang: Iron and Steel, Vol. 22 (1987), p.1

Google Scholar

[5] M. S. Qin, T. Y. Zhang and H. S. Lu: Iron and Steel, Vol. 25 (1990), p.9

Google Scholar

[6] M. S. Qin and J. L. Zhang: Iron and Steel, Vol. 28 (1993), p.9

Google Scholar

[7] P. M. Guo, J. J. Gao and P. Zhao: Journal of University of Science and Technology Beijing, Vol. 33 (2011), p.334

Google Scholar

[8] L. G. Zheng and E. Furinsky, Energy conversion and management, Vol. 46 (2005), p.1767

Google Scholar

[9] X. L. Wang, in: Ferrous Metallurgy (Iron-making) (Metallurgical Industry Press, China 2006).

Google Scholar

[10] S. R. Na, in: Iron-making Calculation (Metallurgical Industry Press, China 2007).

Google Scholar

[11] W. X. Wang, in: Technological progress of key iron-making companies in China in 2010, 2011 China low CO2 iron-making technology conference, p.15, Hunan (2011).

Google Scholar