Effects of Steelmaking Ladle Holding Period on Continuous Casting Yield

Godspower O. Edafeadhe; Harold C. Godwin

doi:10.4028/www.scientific.net/AMR.824.339

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 824Effects of Steelmaking Ladle Holding Period on...

Effects of Steelmaking Ladle Holding Period on Continuous Casting Yield

Abstract:

The study was undertaken to ascertain the effects of holding time during secondary steel making, casting duration, strand loss per heat, and tonnage of steel returned per heat on continuous casting yield (%). A total of 1910 heats, spanning a period of seven years (41 production months) were used for the study. Monthly tonnage of liquid steel produced and cast and the corresponding yield were computed from the casting reports. Also extracted from the casting reports are the average monthly holding time (mins) during secondary steel making, monthly average heat casting duration (minutes), average strand loss per heat and monthly average tonnage of steel returned per heat. A statistical package for social sciences (SPSS) was used to analyse the data obtained. The yield was found to be negatively correlated to steel holding time during secondary steel making (-0.257 mins), strand loss per heat (-0.753 tons), and tonnage of heat returned per heat (-0.944 tons), but positively correlated to casting duration (0.371 mins). The result showed that increase in holding time during secondary steel making, strand loss per heat and tonnage of steel returned per heat decrease the yield of continuous casting process. The model formulated was able to explain 93.4% of the total variation in the observed yield. Efforts should therefore be made to monitor and reduce these parameters that decrease the yield through proper process control, regular checks of the continuous casting machines, replacement of worn out moulds, and in-house training and retraining of casters for optimum process performance.

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Advanced Materials Research (Volume 824)

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339-346

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https://doi.org/10.4028/www.scientific.net/AMR.824.339

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September 2013

Authors:

Godspower O. Edafeadhe, Harold C. Godwin

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Casting Duration, Holding Time, Strand Loss, Tonnage of Steel, Yield

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References

[1] W. Rodney, How Europe Underdeveloped Africa, Panaf Publishing Inc., Abuja, (1972).

Google Scholar

[2] B. Obi, Nigerian Steel Plants Ikeja, Times International, 5 (1984).

Google Scholar

[3] F. Brume, Third World Experience in Setting up An Integrated Iron and Steel Complex: The Nigerian Experience, An Invitational Lecture delivered at the Training Workshop on Ore Assessment, Quality Control and Waste Management in the Iron and Steel and Allied Industries organized by the Chemical Society of Nigeria and Held at the University of Ibadan, 25th – 30th July, (1982).

Google Scholar

[4] S. Chakraborty, Y. Sahai, Effect of Holding Time and Surface Cover in Ladles on Liquid Steel Flow in Continuous Casting Tundishes, Metallurgical Transactions B, 236(1992).

DOI: 10.1007/bf02651850

Google Scholar

[5] R.A. Higgins, Engineering Metallurgy Part 1: Applied Physical Metallurgy, 6th Edition, Viva Books Private Limited, New Delhi, (2004).

Google Scholar

[6] R.H. Tupkary, V.R. Tupkary, An Introduction to Modern Steelmaking: A Textbook for Engineering Students, Khana Publishers, New Delhi, (1998).

Google Scholar

[7] Delta Steel Company Operating Manual on Concast, (1981).

Google Scholar

[8] J. Ajao-Aderemi, Return Heats from Continuous Casting Plant: Which Way Out? Paper presented at the 4th Quarter Seminar of Nigerian Metallurgical Society, Delta Chapter on 28th April, (1994).

Google Scholar

[9] L.J. Heaslip, A. McLean, I.D. Sommerville, Tundish Metallurgy: Considerations Pertaining to Tundish Performance and Metallurgical Treatment During Continuous Casting, Vol. 1, Edward Brothers Inc., Michigan, (1983).

Google Scholar

[10] B.L. Bowerman, R.T. O'Connel, M.L. Hand, Business Statistics in Practice, 2nd Ed., McGraw-Hill/Irwin, New York, (2001).

Google Scholar