Research of the boron interfacial distribution between boron-bearing oxide and metal / Sychev A.V., Salina V.A., Babenko A.A., Zhuchkov V.I. // Izvestiya Vysshikh Uchebnykh Zavedenij. Chernaya Metallurgiya. - 2017. - V. 60, l. 2. - P. 140-144.

ISSN:

03680797

Type:

Article

Abstract:

The thermodynamic calculations have been performed to study the influence of silicon (0.1 – 0.8 %), aluminum (0.005 %) and carbon (0.1 %) contained in the metal on recovery process of boron from slag with the basicity equal to 5, at temperatures of 1400 – 1700 °C with the help of software package HSC 6.1 Chemistry (Outokumpu). The experiments of interfacial distribution of boron between slag system of CaO – SiO2 – MgO – Al2O3 – B2O3 and metal have been carried out in a high temperature electrical resistance furnace of Tamman. The low-carbon steels with different contents of silicon were the base metal. The results of thermodynamic modeling and experimental data have shown that direct microalloying of steel with boron are crucially possible due to boron reduce with the help of silicon in metal. The reduction of boron with slag is possible with the help of silicon in metal and the process was theoretically based and experimentally studied. The results of thermodynamic modeling indicate the possibility of thermodynamic recovery of boron from the system of CaO – SiO2 – MgO – Al2O3 – B2O3 with the help of silicon, despite its low (0.1 – 0.8 %) concentration in the metal. The increase of the initial silicon content in the steel increases the concentration of boron in the reduced metal. The results have shown the effect of silicon content and temperature of metal on the content of boron in steel. It has been shown that an extract of the metal by slag, containing 4.3 % B2O3, is accompanied by boron reduction. The primary reductant of boron is silicon, whose content in the metal after the experiment is reduced by 15 – 22 %. Thus, the steel sample with high concentration of silicon contains greater amount of boron. Recovery rate of boron ranges from 5.8 to 6.9 %, it is essentially correlated with the results of thermodynamic modeling. The concentration of boron in the metal can be controlled by changing temperature of process and content of silicon in the steel. The research results can be used in the development of the process technology of direct steel microalloying with boron. © 2017, National University of Science and Technology MISIS. All rights reserved.

Author keywords:

Boron; Direct alloying; Experimental study; Interfacial distribution of boron; Slag; Steel; Thermodynamic modeling

Index keywords:

нет данных

DOI:

10.17073/0368-0797-2017-2-140-

Смотреть в Scopus:

https://www.scopus.com/inward/record.uri?eid=2-s2.0-85026344942&doi=10.17073%2f0368-0797-2017-2-140-144&partnerID=40&md5=e95f256d6fa813549dadac9e8bc5efdb

Соавторы в МНС:

—

Другие поля

Поле	Значение
Link	https://www.scopus.com/inward/record.uri?eid=2-s2.0-85026344942&doi=10.17073%2f0368-0797-2017-2-140-144&partnerID=40&md5=e95f256d6fa813549dadac9e8bc5efdb
Affiliations	Institute of Metallurgy, UB RAS, Ekaterinburg, Russian Federation
Author Keywords	Boron; Direct alloying; Experimental study; Interfacial distribution of boron; Slag; Steel; Thermodynamic modeling
Funding Details	RSF, Russian Science Foundation
Funding Text	The research was supported by the grant from the Russian Science Foundation (Project no. 16-19-10435).
References	Lyakishev, N.P., Pliner, Y.L., Lappo, S.I., (1986) Borsoderzhashchie Stali I Splavy [Boron-Containing Steels and Alloys], p. 192. , Moscow: Metallurgiya; Ershov, G.S., Bychkov, Y.B., (1982) Fiziko-Khimicheskie Osnovy ratsional’-nogo Legirovaniya Stali I Splavov [Physical and Chemical Frameworks of Rational Alloying of Steel and Alloys], p. 360. , Moscow: Metallurgiya; Heckmann, C.J., Ormston, D., Grimpe, F.E., Development of low carbon Nb-Ti-B microalloyed steels for high strength large diameter linepipe (2005) Iron and Steelmaking, (4), pp. 57-60; Asakhi, K., Khaara, T., Tzuru, E., (2006) Development of Ultra-High-Strength X120 UEO Pipes. In: Sb. Dokladov Mezhdunarodnogo Sem-Inara “Sovremennye Stali Dlya Gazonefteprovodnykh Trub, Problemy I perspektivy” [Collected Papers of the International Seminar “Mo-dern Steels for Gas Oil Pipes, Problems and perspectives”], pp. 123-130. , Moscow: Metallurgizdat; Kobyakov, K.V., Nevar, N.F., Research of the influence of alloying with boron on the properties of iron-carbon alloys (2014) Lit’e I Metallurgiya, 1 (74), pp. 105-107; Gol’Dshtein, Y.E., Mizin, V.G., (1986) Modifitsirovanie I Mikrolegirovanie Chuguna I Stali [Modification and Microalloying of Cast-Iron and Steel], p. 272. , Moscow: Metallurgiya; Kolbasnikov, N.G., Matveev, M.A., (2016) Research of Boron Influence on High-Temperature Plasticity of Microalloyed Steel. Nauch.-Tekhn. Vedomosti Spbgpu. Metallurgiya I Materialovedenie, 1 (238), pp. 129-135; Potapov, A.I., (2013) Issledovanie Protsessov Mikrolegirovaniya Stali Borom S tsel’yu Sovershenstvovaniya Tekhnologii Proizvodstva Borsoder-Zhashchei Stali: Avtoref. Dis. Kand. Tekhn. Nauk [Research of Processes of Steel Microalloying with Boron to Improve the Technology of Production of Boron-Containing Steel: Extended Abstract of Cand. Sci. Diss.], p. 27. , Moscow; Upadhyaya, N., Pujara, M.G., Sakthivelb, T., Mallikaa, C., Lahab, K., Kamachi Mudalia, U., Effect of addition of boron and nitrogen on the corrosion resistance of modified 9Cr-1Mo ferritic steel (2014) Pro-Cedia Engineering, 86, pp. 606-614; Ya-Long, Z., Ying-Yi, Z., Fei-Hua, Y., Zuo-Tai, Z., Effect of alloying elements (Sb, B) on recrystallization and oxidation of Mn-containing IF steel (2013) Journal of Iron and Steel Research, International, 20 (3), pp. 39-44; Wang, H., Zhang, T., Zhu, H., Guirong, L., Yongqi, Y., Wang, J., Effect of В2О3 on melting temperature, viscosity and desulfurization capacity of CaO-based refining flux (2011) ISIJ International, 51 (5), pp. 702-706; Choa, K.C., Munb, D.J., Koob, Y.M., Leeb, J.S., Effect of niobium and titanium addition on the hot ductility of boron containing steel Materials Science and Engineering A, 528 (2011), pp. 3556-3561; Loґpez-Chipresa, E., Mejıґa, I., Maldonado, C., Bedolla-Jacuinde, A., El-Wahabi, M., Cabrera, J.M., Hot flow behavior of boron microalloyed steels (2008) Materials Science and Engineering A, 480, pp. 49-55; Stumpf, W., Banks, K., The hot working characteristics of boron bearing and conventional low carbon steel (2006) Materials Science and Engineering A, 418, pp. 86-94; Stepanov, A.I., Babenko, A.A., Sychev, A.V., Zhuchkov, V.I., Mur-Zin, A.V., Dresvyankina, L.E., Ushakov, M.V., Development of technology for microalloying steel with boron using ferro-silicon-boron (2014) Metallurgist, 58 (78), pp. 588-590; Bedolla-Jacuinde, A., Guerra, F.V., Rainforth, M., Mejia, I., Maldonado, C., Sliding wear behavior of austempered ductile iron microalloyed with boron (2015) Wear, 330-331, pp. 23-31; Konovalov, R.P., (1986) Slitok Kipyashchei Stali [Open Steel Ingot], p. 176. , Moscow: Metallurgiya; Zhong-Dong, Y.A.N.G., Su-Lan, L.I.U., Ze-Fu, L.I., Xiang-Xin, X.U.E., Oxidation of Silicon and Boron in Boron Containing Molten Iron (2007) Jornal of Iron and Steel Research, International, 14 (6), pp. 32-36; Zhuchkov, V.I., Akberdin, A.A., Vatolin, N.A., Leont’Ev, L.I., Zaya-Kin, O.V., Kim, A.S., Usage of boron-containing materials in metallurgy (2011) Elektrometallurgiya, (3), pp. 25-29; Babenko, A.A., Zhuchkov, V.I., Smirnov, L.A., Sychev, A.V., Akberdin, A.A., Kim, A.S., Vitushchenko, M.F., Dobromilov, A.A., Production technology for low-carbon, low-sulfur boron steel (2015) Steel in Translation, 45 (11), pp. 883-886; Roine, A., Outokumpu, H.S.C., (2002) Chemistry for Windows. Chemical Reactions and Equilibrium Software with Extensive Thermochemical Database, , Pori: Outokumpu research OY
Publisher	National University of Science and Technology MISIS
CODEN	IVUMA
Language of Original Document	Russian
Abbreviated Source Title	Izv Vyssh Uchebn Zaved Chern Metall
Source	Scopus