Resource-saving direct alloying of steel
- Authors: Rybenko I.A.1, Nokhrina O.I.1, Rozhikhina I.D.1, Golodova M.A.1, Tsymbal V.P.1
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Affiliations:
- Siberian State Industrial University
- Issue: Vol 47, No 2 (2017)
- Pages: 85-90
- Section: Article
- URL: https://journals.rcsi.science/0967-0912/article/view/179335
- DOI: https://doi.org/10.3103/S0967091217020097
- ID: 179335
Cite item
Abstract
The development of the alloying and modification of steel by oxides, including natural materials, is very promising. Potential materials include barium–strontium carbonate ores, nickel concentrates, and vanadium converter slag, which may be used to produce steel with improved properties, without the expensive process of producing ferroalloys and intermediate alloys. Considerable research is required to improve steel-making processes. Thermodynamic modeling may be used for that purpose. In the present work, thermodynamic modeling is used for elementary systems involved in the extraction of barium, strontium, vanadium, and nickel from their oxides by means of different reducing agents. The results indicate that microalloying and modification of steel by inexpensive materials is possible; and permit the determination of the type of reducing agent and the optimal quantities employed. The Terra software used in thermodynamic modeling permits the determination of the equilibrium composition of the multicomponent heterogeneous system for high-temperature conditions, on the basis of the maximum-entropy principle. The reducing agents considered are carbon, silicon, and aluminum. The influence of the temperature and reducing-agent consumption on the reduction processes is investigated. The results regarding the reduction of barium and strontium show that silicon or aluminum is the best reducing agent when barium-bearing oxide materials are employed. The optimal reducing-agent consumption corresponding to maximum reduction of the barium and strontium is determined. The possibility of reducing nickel by carbon is confirmed. It is found that vanadium may be reduced by silicon or carbon or a complex process in which carbon is the predominant reducing agent. The results permit the development of a resource-saving technology based on oxides for the alloying, microalloying, and modification of Fe–C systems.
About the authors
I. A. Rybenko
Siberian State Industrial University
Author for correspondence.
Email: rybenkoi@rambler.ru
Russian Federation, Novokuznetsk
O. I. Nokhrina
Siberian State Industrial University
Email: rybenkoi@rambler.ru
Russian Federation, Novokuznetsk
I. D. Rozhikhina
Siberian State Industrial University
Email: rybenkoi@rambler.ru
Russian Federation, Novokuznetsk
M. A. Golodova
Siberian State Industrial University
Email: rybenkoi@rambler.ru
Russian Federation, Novokuznetsk
V. P. Tsymbal
Siberian State Industrial University
Email: rybenkoi@rambler.ru
Russian Federation, Novokuznetsk