Physicochemical structure features of refractory compositions with inorganic binders

Authors

  • R.V. Liutyi National Technical University of Ukraine “Igor Sikorsky Kyiv Polytechnic Institute”, Kyiv, Ukraine
  • L.I. Solonenko Dnipro University of Technology, Dnipro, Ukraine
  • I.O. Osipenko Dnipro University of Technology, Dnipro, Ukraine
  • M.M. Fedorov Donbass State Engineering Academy, Kramatorsk, Ukraine
  • B.I. Moroz Dnipro University of Technology, Dnipro, Ukraine

DOI:

https://doi.org/10.15330/pcss.23.3.612-619

Keywords:

disthene-sillimanite, binder, metaphosphate, compressive strength, orthophosphate, orthophosphoric acid, vapor-microwave treatment, pyrophyillite, liquid glass, composition structuring

Abstract

The article presents the study results of new inorganic binders and the physicochemical processes of their formation. The main purpose of the created materials is to make molds and cores for foundry production. Creating environmentally-friendly binders with a set of functional properties for foundry production is relevant worldwide. Therefore, scientists from different countries are paying special attention to the study of silicate and phosphate binders. The study analyzes the kinetics of the orthophosphoric acid interaction with several inorganic materials – pulverent pyrophyllite, disthene-sillimanite, a by-product of electrocorundum production, and sodium chloride. The phase and chemical composition of all formed binders have been established. In aluminum-containing compositions, those are represented by aluminum orthophosphates in crystalline and amorphous forms. Sodium metaphosphate is formed in the composition with sodium chloride. Peculiarities of the structuring compositions physical process with liquid glass and granular quartz filler due to steam-microwave treatment are determined. It is shown that structuring occurs due to dehydration, which is completed within 4…12 min, which allows reducing the liquid glass content in the composition to 1.5% while ensuring a high level of strength. The properties of structured compositions with the developed binding components are researched, and it is shown that all of them are competitive. Recommendations for their possible application were created.

References

[1]. S.P. Doroshenko, V.P. Avdokushyn, K. Rusyn, I. Matsashek, Molding materials and mixtures (Kyiv, Vyshcha shkola, 1980).
[2]. R.V. Liutyi, I.M. Guriya. Molding materials: Textbook (Kyiv, Igor Sikorsky Kyiv Polytechnic Institute, 2020).
[3]. L. Solonenko, I. Prokopovitch, S. Repyakh and other, Proceedings of the Odessa Polytechnic University, No. 1(57), pp. 90-98 (2019).
[4]. S.P. Doroshenko, Molding mixtures (Kyiv, IZMN, 1997).
[5]. A.N. Boldin, N.I. Davydov, S.S. Zhukovskiy and other, Foundry molding materials. Molding, core mixtures and coatings (Moscow, Mashinostroyeniye, 2006).
[6]. E.A. Belobrov, R.I. Bullstein, A.F. Poduzdikov, O.S. Kovrigin, Foundry production, No. 8, pp. 21-23 (2001).
[7]. A,V, Sokolov. Foundry production, No. 6, pp.18-19 (2016).
[8]. V.M. Golovanov, O.K.Tishshenko, O.A. Starodubtseva, International Conference on Polyphosphate cold hardening mixtures and castings from ductile iron (Lipetsk, 1989), pp. 47-50.
[9]. N.Ch. Ivanov, V.N. Klimovskij, V.A. Ulitskij, International Conference on Ferriphosphate cold hardening mixtures and technology for obtaining high-quality castings based on them (Lipetsk, 1987), pp. 43-44.
[10]. A.A. Svaryka, Molding materials and mixtures (Kyiv, Technics, 1983).
[11]. L.G. Sudacas, Phosphate binding systems (RIA «Kvintet», St. Petersburg, 2008).
[12]. O.I. Ponomarenko, N.S. Yevtushenko, T.V. Berlizeva, Foundry production, No. 4, pp. 21-23 (2011).
[13]. T.V. Berlizeva, O.I. Ponomarenko, Foundry production, No.4, pp. 21-23 (2014).
[14]. S. Puzio, J. Kamińska, K. Major-Gabryś, M. Angrecki, M. Hosadyna-Kondracka, Аrchives of foundry engineering, Vol. 19, Issue 2, pp. 91-96 (2019); doi.org/10.24425/afe.2019.127122.
[15]. V.A. Kopeykin, V.S. Klement'yeva, B.L. Krasnyy, Refractory solutions on phosphate binders (Moscow, Metallurgiya, 1986).
[16]. I.E. Illarionov, I. E. Doctor’s thesis (05.16.04, Cheboksary, 1988).
[17]. I.M. Fedorchenko, Encyclopedia of Inorganic Materials, Vol. 2 (The main edition of the Ukrainian Soviet Encyclopedia, Kyiv, 1977).
[18]. A.N. Tsibrick, New technological principles for obtaining of castings (Naukova Dumka, Kyiv, 1984).
[19]. M. Jemala, J.-J. Videaud, M. Couzie, Journal of Alloys and Compounds, Vol. 632, pp. 766-771 (2015); doi.org/10.1016/j.jallcom.2015.01.297.
[20]. M. Liu, N. Shang, X. Zhang, S. Gao, C. Wang, Z. Wang, Journal of Alloys and Compounds, Vol. 791, pp. 929-935; doi.org/10.1016/j.jallcom.2019.03.382.
[21]. R. Liutyi, M. Tyshkovets, D. Liuta, O. Sheiko, Physics and chemistry of solid state, Vol. 21, No. 4, pp. 756-763; doi.org/10.15330/pcss.21.4.756-763.
[22]. V.I. Korneev, V.V. Danilov, Soluble and liquid glass (Strojizdat, St. Petersburg, 1996).
[23]. A.V. Zabolotskaya. Candidate’s thesis (05.17.11, 02.00.01, Tomsk, 2003).
[24]. V.S. Gorshkov, V.V. Timashev, V.G. Savelyev, Methods for physical and chemical analysis of binders (High school, Moscow, 1981).
[25]. A.N. Porada, M.I. Gasik, Electrothermy of inorganic materials (Metallurgy, Moscow, 1990).
[26]. V.E. Hrychikov, I.A. Osipenko, O.L. Kiselgof, Metallurgical and mining industry, No. 3(203), pp. 29-31 (2001).
[27]. P.P. Budnikov, L.B. Horoshavin, Refractory concretes on phosphate binders (Metallurgy, Moscow, 1971).

Published

2022-09-30

How to Cite

Liutyi, R., Solonenko, L., Osipenko, I., Fedorov, M., & Moroz, B. (2022). Physicochemical structure features of refractory compositions with inorganic binders. Physics and Chemistry of Solid State, 23(3), 612–619. https://doi.org/10.15330/pcss.23.3.612-619

Issue

Section

Scientific articles (Technology)

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