The concept of creating electrical insulating ceramic materials and objects from powder systems represented by oxide and nonoxide chemical compounds is formulated; a program document for materials science and technological logistics of physical and chemical transformation of technogenic mineral raw materials into electrical materials and products for various scientific, practical, and specific engineering purposes is created and implemented. The main theoretical approach and its applied practical aspects are development, research, and creation of heat and chemically resistant structural electrical insulation materials that are products for various scientific and practical purposes: automatic contact welding of tubular bimetals (for example, copper-aluminum), vacuum electron beam welding of thick-walled large-sized structures made of high-strength aluminum alloys, high-temperature (1050°C) hardening of drilling tools in vacuum furnaces in a dissociated acetylene atmosphere, and in electric transmissions of BelAZ quarry dump truck brake installations.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
G. G. Gnesin and V. V. Skorokhod, Inorganic Material Science. Encyclopaedic edition, in 2 Vol. Vol. 1 [in Russian], Naukova Dumka Kiev (2008).
G. G. Gnesin, V / . A. Dubov, G. N. Braterskaya, et al., Sintered Materials for Electrical Engineering and Electronics: Ref. Ed. [in Russian]. Metallurgiya, Moscow (1981).
V. T. Shmuradko, O. V. Roman, and I. V. Fomichina “Directed synthesis of multilayer structures in ceramic and refractory technology,” Refract. Ind. Ceram., 48(3), 189 – 196 (2007).
O. V. Roman, F. I. Panteleenko, O. P. Reut, et al., “Scientific and practical approaches to creating ceramic refractory materials and technology,” Refract. Ind. Ceram., 51(5), 334 – 342 (2011).
V. T. Shmuradko, O. V. Roman, F. I. Danteleenko, and A. V. Drozdov, “calculation of temperature fields for two-layer objects,” Proc. Internat. Conf. of Refractory Workers and Metallurgists (21 March – 1 April, 2011, Moscow), Novye Ogneupory, No. 3, 41 (2011).
O. P. Royt, V. T. Shmuradko, et al., “Development of physicochemical bases of technology for preparing heat- and chemically-resistant materials objects based on modified aluminum oxide using isostatic compaction: research review,” IPK and PK BNTU, Minsk (2015).
N. A. Rudenskaya, V. T. Shmuradko, et al, “development of high-strength materials based on corundum modified with rare-earth element oxides and production bases for creating effective materials and objects at the level of mobile competitive production; research review,” IPK and PK BNTU, Minsk (2015).
V. T. Shmuradko, F. I. Panteleenko, O. P. Reut, et al., “materials science principles and production solutions for development, creation, and use of wear-resistant corundum material objects for underground driving in soils and metal cord production,” Coll. MTNK “New technology and materials, automated production,”, 2 – 3 November, Brest (2016).
F. I. Panteleenko, V. T. Shmuradko, et al., “development of heat-resistant electrical insulating materials, preparation technology for functional objects operating in machine assemblies and mechanisms in a static-dynamic regime and severe temperature gradients: research review,” IPK and PK BNTU, Minsk (2015).
V. T. Shmuradko, F. I. Panteleenko, O. P. Reut, and M. O. Stepkin, “Principles of creating heat-resistant electrical insulating objects for BelAZ quarry dumper trucks,” Proc. Internat. Conf. of Refractory Workers and Metallurgists (1 – 2 March, 2016, Moscow), Novye Ogneupory, No. 3, 19 – 20 (2016).
V. T. Shmuradko, F. I. Panteleenko, O. P. Reut, et al., “Physicochemical processes and mechanism for preparing Belaz quarry dumper truck heat-resistant electrical insulators,” Refract. Ind. Ceram., 57(6), 614 – 617. (2016).
V. T. Shmuradko, F. I. Panteleenko, O. P. Reut, et al., “Electrical insulating materials for automatic welding of tubular pipe metals,” Proc. Internat. Conf. of Refractory Workers and Metallurgists (10 – 20 March, 2017, Moscow), Novye Ogneupory, No. 3, 64 (2017).
V. T. Shmuradko, F. I. Panteleenko, O. P. Reut,, et al., “Electrical insulating materials products for welding equipment,” Refract. Ind. Ceram., 58(6), 693 – 696 (2018).
V. T. Shmuradko, F. I. Panteleenko, O. P. Reut, et al., “Features of preparation of thermal shock resistant electrical insulating materials and objects for welding equipment,” Coll. Internat. Symp. “prospective materials and technology,” Vitebsk, Belarus, 22 – 26 May, 2017.
K. K. Strelov, Theoretical Bases of Refractory Material Technology [in Russian] Metallurgiya, Moscow (1985).
V. N. Strekalovskii, Yu. M. Polezhaev, and S. F. Pol’guev, Oxides with Impurity Disordering: Composition, Structure, Phase Transformations [in Russian], Nauka, Moscow (1987).
Yu. E. Pivinskii, Chemical Binders and Ceramic Concretes [in Russian], Metallurgiya, Moscow (1990).
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Novye Ogneupory, No. 9, pp. 16 – 24, September, 2020.
Rights and permissions
About this article
Cite this article
Roman, O.V., Shmuradko, V.T., Panteleenko, F.I. et al. Engineering Ceramics: Material Science and Technology Principles and Mechanisms for Development and Implementation of Ceramic Electrical Insulators for Various Scientific and Practical Purposes. Refract Ind Ceram 61, 499–506 (2021). https://doi.org/10.1007/s11148-021-00511-w
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11148-021-00511-w