Combined Steel Treatment with Calcium-Silicon

R.A. Gizatulin; A.B. Efremenkov; Denis V. Valuev; S.N. Fedoseev; A.V. Valueva

doi:10.4028/www.scientific.net/AMM.770.114

Paper Titles

Functionalized Composite Coatings Based on Filled Powder Paint Processed in Planetary Ball Mill
p.93

Use of Nanopowders of Metals in Different Branches of Industry
p.99

Smelting Steel Resistant to Corrosion from Metal Mixing Air in Late Oxygen Blowing
p.104

Industrial Surfacing of Hammer Grinder Components Utilized in Coke-Making Process and Outlines of Surfacing Quality Improvement
p.108

Combined Steel Treatment with Calcium-Silicon
p.114

New Technologies of Anodizing Components of Oil and Gas Industry Equipment Made of Aluminum Alloys
p.121

Impact of Welded Joint on Cyclic Strength of Low-Alloyed Steels
p.126

Development of the Technique to Simulate Residual Heading Corium Prototype
p.130

Elastic Properties of Solid Solutions with Intermediate Valence Sm_1-xY_xS
p.137

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 770Combined Steel Treatment with Calcium-Silicon

Combined Steel Treatment with Calcium-Silicon

Abstract:

The method of adding calcium silicon in aluminum containers to a metal when it pours into a ladle from the steelmaking unit has been developed. Industry data were obtained to confirm the possibility of providing a sufficiently high and stable recovery of calcium in the context of production at a particular plant and its effective impact on the composition, physical and chemical condition of a melt and properties of a final product.

You might also be interested in these eBooks

Urgent Problems of Up-to-Date Mechanical Engineering

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volume 770)

Pages:

114-120

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.770.114

Citation:

Cite this paper

Online since:

June 2015

Authors:

R.A. Gizatulin, A.B. Efremenkov, Denis V. Valuev*, S.N. Fedoseev, A.V. Valueva

Keywords:

Calcium-Silicon Lumps, Combined Steel Treatment, Metallurgical Enterprise, Purging Steel

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] R.A. Gizatulin, V.I. Dmitrienko, Secondary metallurgy and ladle treatment processes, Novokuznetzk, (2006), p.181.

Google Scholar

[2] R.A. Gizatulin, Yu. N Nosov, S.K. Otroshchenko, N.N. Zharikova, T.V. Gudimova, Improvement in quality of electrical steel during complex treatment with calcium, aluminum and titanium in a ladle, J. Modern problems of steel making and quality management in training specialists: Materials of Sc. -Method. Conference. (2002).

Google Scholar

[3] D.A. Dyudkin, S. Yu. Bat, S.E. Grinberg, S.N. Marinztev, Ladle furnace steelmaking, Donetzk, (2003) 306.

Google Scholar

[4] A.P. Rodzevich, E.G. Gazenaur, G.M. Belokurov, The Technology of production and treatment of materials in the electric field, J. Applied Mechanics and Materials. 682 (2014) 206-209.

DOI: 10.4028/www.scientific.net/amm.682.206

Google Scholar

[5] S.V. Kazakov, A.G. Sviazhin, A.I. Pozhivanov, Averaging time for a chemical composition and temperature when a liquid steel is blown in the ladle, J. Iss. ASUSSR. Metals. 2 (1988) 5-12.

Google Scholar

[6] N.A. Saprykina, A.A. Saprykin, Improvement of surface layer formation technology for articles produced by layer-by-layer laser sintering, J. Applied Mechanics and Materials. 379 (2013) 56-59.

DOI: 10.4028/www.scientific.net/amm.379.56

Google Scholar

[7] E.A. Ibragimov, A.A. Saprykin, E.V. Babakova, Influence of laser beam machining strategy at SLS synthesis, J. Advanced Materials Research. 1040 (2014) 764-767.

DOI: 10.4028/www.scientific.net/amr.1040.764

Google Scholar

[8] Yu.N. Nosov, R.A. Gizatulin, Combined steel treatment with aluminum and calcium in an arc furnace at tapping, J. Elekrometallurgiya. 4 (1999). 33-34.

Google Scholar

[9] S.N. Fedoseev, D.V. Lychagin, A.S. Sharafutdinova, Improving characteristics of austenitic steels by modification, J. Advanced Materials Research. 1040 (2014) 236-240.

DOI: 10.4028/www.scientific.net/amr.1040.236

Google Scholar