Balance of Raw Input and Energy of Titanium Slag Smelting in Closed High Power Direct Current Electric Arc Furnace

Feng Xia Han; Xiu Li Sang; Jian Xin Xu

doi:10.4028/www.scientific.net/AMR.734-737.1516

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 734-737Balance of Raw Input and Energy of Titanium Slag...

Balance of Raw Input and Energy of Titanium Slag Smelting in Closed High Power Direct Current Electric Arc Furnace

Abstract:

There were two controlling factors, which should be kept balance of raw input and energy during titanium slag smelting in closed high power direct current electric arc furnace, DC furnace for short. The first factor contains compositions and ratio of input raw materials. Compositions of the raw could influence the progress and technical indicators of DC furnace smelting, and on the meanwhile, it could determine the compositions of impurity and contents of TiO₂ in titanium slag. On the other hand, the ratio of input infected the compositions of the slag, while too much anthracite would disadvantage to produce high quality slag because of impurity being reduced continually. Meanwhile much more low-state titanium would be generated. The second factor was an important one that energy equilibrium, which influence the production safety of DC furnace. It could keep balance of input and output energy, while the heatloss was 4.971 MVA. While the ratio of anthracite remained the same, the energy would effect slag viscosity and equilibrium of freeze lining directly. The energy input higher than smelting need would result in burnthrough of furnace wall and hearth, on the contrary, lower than smelting need would bring about slagging difficulties. Consequently, raw input and energy must be kept dynamic balance in order to achieve high quality titanium slag and protect freeze lining.

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Periodical:

Advanced Materials Research (Volumes 734-737)

Pages:

1516-1521

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.734-737.1516

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Online since:

August 2013

Authors:

Feng Xia Han, Xiu Li Sang, Jian Xin Xu

Keywords:

Closed Direct Current Electric Arc Furnace, Energy Balance, High Power, Titanium Dioxide (TiO₂), Titanium Slag

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References

[1] S.L. Yang, J.F. Sheng: Titanium Slag and Pig Iron Smelting Technology (Metallurgy Industry Press, China 2006), In Chinese.

Google Scholar

[2] W. Mo: Titanium (Metallurgy Industry Press, China 2008), In Chinese.

Google Scholar

[3] J. Pesl, R.H. Eric. Minerals Engineering. Vol.15 (2006), p.971.

Google Scholar

[4] C. Murty, R. Upadhyay, S. Asokan. INFACON XI. (2007), p.823

Google Scholar

[5] R.K. Galgali, H.S. Ray, A.K. Chakrabarti. Metallurgical and Materials Transactions B. Vol.29 (1998), p.1175.

Google Scholar

[6] H. Kotzé, D. Bessinger, J. Beukes. The South African Institute of Mining and Metallurgy. (2006), p.165.

Google Scholar

[7] J.H. Zietsman, P.C. Pistorius. Minerals Engineering. Vol.19 (2006), p.262.

Google Scholar

[8] Y.M. Wang, Z.F. Yuan, Z.C. Guo, etc. Transactions of Nonferrous Metals Society of China. (2008), p.962.

Google Scholar

[9] J.H. Zietsman, P.C. Pistorius. The South African Institute of Mining and Metallurgy. Vol. 12 (2004), p.653.

Google Scholar

[10] P.C. Pistorius. The Southern African Institute of Mining and Metallurgy. Vol. 108 (2008), p.35.

Google Scholar

[11] D.C. Li, H. Liu, D.L. Zhou: Process of Titanium Smelting (Chemical Industry Press, China 2009), In Chinese.

Google Scholar

[12] S. Samal, P.S. Mukherjee, A.K. Ray. Plasma Chemistry and Plasma Processing. Vol. 30 (2010), p.413.

Google Scholar

[13] P.C. Pistorius. Scandinavian Journal of Metallurgy. Vol.31 (2002), p.120.

Google Scholar

[14] P.C. Pistorius. The South African Institute of Mining and Metallurgy. Vol.8 (2004), p.417.

Google Scholar

[15] F.X. Han, T. Lei, L. Zhou, ect. J. Light Metals. Vol.12 (2012), p.51.

Google Scholar

[16] P. Zhao, Y.D. Meng, X.Y. Yu, etc. Plasma Science and Technology. Vol.11 (2009), p.206.

Google Scholar