A comprehensive methodological approach is proposed for resolving metallurgical problems within the scope of a multistage problem formula “composition – structure – properties” – “technology” – “thermal shock-corrosion-erosion-resistant material” followed by development of material technology and objects conforming to refractory conditions and operating regimes in heating units. Practical scientific approaches are considered for forming heat and corrosion resistant refractory materials. A general structural model is proposed for ceramic refractory technology making it possible by computer modelling to perform systematic analysis, prediction and calculation of specific technological parameters in the main production stages.
Similar content being viewed by others
References
K. K. Strelov, Theoretical Bases of Refractory Material Technology [in Russian], Metallurgiya, Moscow (1985).
O. V. Roman, V. T. Shmuradko, et al., “Development of special software for heat treatment of ceramic material objects: use of phase composition diagrams in mathematical modelling and numerical calculations of sintering in a PC, “ Research report (intermediate), GNPO PM OKhP NII IP with OP, No. GR 20088893, Minsk (2009).
A. F. Il’yushchenko, V. T. Shmuradko, et al., “Development of a functional scheme for developing functional objects (material – technology – object) from refractory compounds: study of structure and properties ZrO2, Al2O3 materials in the main production stages,” Research report (intermediate), GNPO PM OKhP NII IP with OP, No. GR 20082696, Minsk (2009).
O. V. Roman, V. T. Shmuradko, et al., “Development of materials and technology for molding ceramic and refractory heat and erosion-resistant objects for metallurgy using pulsed loading methods,” Research report (concluding), OKhP NII IP with OP, No. GR 20062894, Minsk (2009).
A. F. Il’yushchenko, V. T. Shmuradko, et al., “Design of heat-resistant ceramic objects based on systematic analysis of technology using a PC and special software. Development of recommendations for practical use and introduction of research results,” Research report (intermediate), OKhP NII IP with OP, No. GR 20093645, Minsk (2009).
S. M. Logvinkov, G. D. Semchenko, and D. A. Kozyreva, “Thermodynamic aspects of synthesizing refractories from talc-kaolin-alumina compositions,” Ogneupor. Tekhn. Keram., No. 4, 22 – 26 (1998).
A. S. Vlasov and L. M. Krainova, Trudy MKhTI, No. 53, 110 – 115 (1988).
I. M. Low and R. McPherson, J. Mater. Sci., 24, 926 – 936 (1989).
A. V. Galakhov, and V. Ya. Shevchenko, Ogneupory, No. 1, 8 – 11 (1991).
V. T. Shmuradko, O. V. Roman, A. F. Il’yushchenko, and I. V. Fomikhina, “Directed synthesis of multilayered structures in ceramic and refractory technology,” Refractories and Industrial ceramics, 48, No. 3, 189 – 196 (2007).
L. B. Khoroshavin and V. A. Perepelitsyn, Ogneupor. Tekhn. Keram., No. 12, 30 – 35 (1999).
Author information
Authors and Affiliations
Additional information
Translated from Novye Ogneupory, No. 9, pp. 17 – 27, September 2010.
Rights and permissions
About this article
Cite this article
Roman, O.V., Panteleenko, F.I., Reut, O.P. et al. Scientific and practical approaches to creating ceramic refractory materials and technology. Refract Ind Ceram 51, 334–342 (2011). https://doi.org/10.1007/s11148-011-9321-1
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11148-011-9321-1