DOI: 10.52150/2522-9117-2018-32-361-370

Snigura Iryna Romanivna, Junior Researcher, Iron and Steel Institute named after Z.I. Nekrasov of the NAS of Ukraine, Academic square Starodubova, 1, Dnipro, Ukraine, 49107

Togobitskaya Daria Nikolaevna, Dr. Sci. (Engin.), Professor, Head of the Department, Iron and Steel Institute named after Z.I. Nekrasov of the NAS of Ukraine, Academican Starodubova square, 1, Dnipro, Ukraine, 49107; email: dntog@ukr.net, isi-ofhp@mail.ru ORCID 0000-0001-6413-4823

THE ROLE OF TAKING INTO ACCOUNT THE INTERATOMIC INTERACTION IN PREDICTING THE COMPLEX OF STRUCTURALLY-SENSITIVE PROPERTIES OF STEELS AND ALLOYS FOR SPECIAL PURPOSE

Abstract. The aim of the work is to identify the influence of the chemical composition of steels and special-purpose alloys on the formation of their physicochemical and structural-sensitive properties. This problem is solved by mathematical modeling of the inseparable chain «composition – structure – property» taking into account the parameters of interatomic interaction in the melt based on the concept of a directed chemical bond. A steel melt is considered as a chemically homogeneous system, and the state of the melts is expressed through a set of integral parameters, the main of which are: Zy – system charge state parameter (e); r – statistically average internuclear distance (10-1nm); tgα is a constant for each element, which characterizes the change in the radius of the ion as its charge changes. On the basis of experimental information on properties and using the parameters of interatomic interaction, computational models are proposed for predicting the properties of steels and alloys. The forecast models took into account the  parameters of microinhomogeneity of steel, which ensured a high accuracy of the operational forecast. A comparative analysis of the results of steel melting with the corresponding calculations based on the JMatPro software package confirmed the effectiveness of using the interatomic interaction parameters as models. The proposed models for determining the melting of chromium-nickel steels are recommended for use with the content of basic elements Cr, Ni from 0 to 30%. The research results are recommended for use in industrial environments through the integration of the developed models in the process control system
of steelmaking, which will contribute to the directed formation of the composition and properties of smelting products, as well as reducing energy costs.
Keywords: special steels, interatomic interaction parameters, physicochemical properties, micro-inhomogeneity, predictive models.

Reference
1. Naydek V. L., Melnik S. G., Verkhovlyuk A. M. Clusters – structural components of metal melts. Metal and Casting of Ukraine .- 2015. – № 7.- P. 21-24.
2. Skrebtsov A.M. Liquid metals. Their properties and structure. Textbook for universities. Mariupol, Perm State Technical University, 2010. – 252.
3. Proceedings of the XIII Russian Conference “The structure and properties of metallic and slag melts”. T.1. Ekaterinburg: Ural Branch of RAS, 2011. – 218 p.
4. Hansen J.P., MacDonald I.R., Theory of Simple Liquids, Academic Press, London, 1986.
5. The structure of metallic liquids: Tutorial. L.A. Zhukov. Ekaterinburg: USTU-UPI, 2002. 46 p.
6. Vikhlevshchuk V.A., Kharakhulakh V.S., Brodsky S.S. Ladle steel finishing: – Dnepropetrovsk: System technologies, 2000 – 190 p.
7. Ladyanov V. I., Novokhatsky I. A., S. V. Logunov. Estimation of the lifetime of clusters in liquid metals. Izv. Academy of Sciences of the USSR. Metals. 1995. № 2. From 13-22.
8. Prikhodko E. V. Efficiency of complex alloying of steels and alloys. – K .: Naukova Dumka, 1995. – 292s.
9. Snihura I.R., Togobitskaya D.N. Prediction of melting and crystallization temperatures of nickel-chrome steels. – Modern problems and metals. Naukovi visti. No. 21, Vol. 1, 2018 – p. 67 – 72.
10. Togobitskaya D.N., Snihura I.R. Prediction of liquidus temperatures and solidus of metal melts based on the concept of targeted chemical bonding. International scientific and technical journal “Automated technologies and production” Magnitogorsk. – № 3, 2016. – p. 64 – 69.
11. Togobitskaya D.N., Golovko L.A., Snihura I.R. Investigation of the microinhomogeneity of one-component metal melts in the region of the above-likvidusnyh temperatures based on the interatomic interaction parameters. – VII International Scientific and Practical Conference “Science in the modern world.” – Kiev, March 19, 2016 – p. 37 – 44
12. Togobitskaya D.N., Snihura I.R., Stepanenko D.A. Prediction of liquidus temperatures in aluminum and magnesium alloys based on the concept of a directed chemical bond. – Materials of the XVth All-Ukrainian Competitive Scientific Practical Conference of the Special Metalurgy: Vchora, CGN, Tomorrow. – 2017, p. 1139 – 1148.37 – 44
13. Computer simulation of the melting and crystallization temperatures of special-purpose alloys. [D.N.Togobitskaya, M.Shaper, O.Gridin, I.R.Snihura]. – Steel. № 6. 2018 – p. 11 – 15.
14. Gaiduk S.V., Kononov V.V., Kurenkova V.V. Obtaining predictive mathematical models for calculating the thermodynamic parameters of casting high-temperature nickel alloys. SEM-2015. – № 5. – p. 31-37.
15. Petrushin N.V., Svetlov I.L. Physico-chemical and structural characteristics of high-temperature nickel alloys. Metals. 2001. No. 2. C 63 – 73.
16. Kablov, E.N., Golubovsky, E.R. Heat resistance of nickel alloys. M .: Mashinostroenie, 1998. 464 p.
17. Kablov E.N., Petrushin N.V., Svetlov I.L., Demonis I.M. Heat-resistant nickel alloys for advanced aviation GTE // Light alloy technology. 2007. № 2. P. 6 – 16.
18. K. D. Carlson & C. Beckermann (2012) Determination of solid fraction– temperature relation and latent heat using full scale casting experiments: application to corrosion resistant steels and nickel based alloys.
International Journal of Cast Metals Research, 25:2, 75-92, DOI: 10.1179/1743133611Y.0000000023