Ceramic materials based on silicon carbide were synthesized using reaction sintering with the introduction of a reactive component – technical carbon black – into the starting mixture at varying concentrations (5, 15, and 30 % by weight). The tribological characteristics of the resulting ceramic materials were determined in a friction pair with a VT6 structural titanium alloy under friction conditions in air and water at room temperature. It was determined that the best antifriction properties (µ = 0.17 in water) are observed during contact interaction between the titanium alloy and silicon carbide material obtained from a mechanical mixture containing the highest amount (30 % by weight) of technical carbon black.
Daria A. Dyuskina – engineer of the 2rd category, National Research Center “Kurchatov Institute” – Central Research Institute of Structural Materials “Prometey”, St. Petersburg, Russia; Saint-Petersburg State Institute of Technology, St. Petersburg, Russia
Mikhail A. Markov – Doctor of Technical Sciences, head of the Laboratory “Technical Ceramics”, National Research Center “Kurchatov Institute” – Central Research Institute of Structural Materials “Prometey”, St. Petersburg, Russia
Alexander N. Nikolaev – Candidate of Technical Sciences, leading engineer, National Research Center “Kurchatov Institute” – Central Research Institute of Structural Materials “Prometey”, St. Petersburg, Russia
Anton N. Belyakov – Candidate of Technical Sciences, senior research fellow, National Research Center “Kurchatov Institute” – Central Research Institute of Structural Materials “Prometey”, St. Petersburg, Russia
Andrey G. Chekuryaev – engineer of the 2rd category, National Research Center “Kurchatov Institute” – Central Research Institute of Structural Materials “Prometey”, St. Petersburg, Russia; Saint-Petersburg State Institute of Technology, St. Petersburg, Russia
Alina D. Bykova – Candidate of Technical Sciences, senior research fellow, National Research Center “Kurchatov Institute” – Central Research Institute of Structural Materials “Prometey”, St. Petersburg, Russia
Margarita A. Glebova – senior laboratory assistant, National Research Center "Kurchatov Institute" – Central Research Institute of Structural Materials "Prometey", St. Petersburg, Russia
Alexander D. Kashtanov – Doctor of Technical Sciences, advisor to the general director, National Research Center “Kurchatov Institute” – Central Research Institute of Structural Materials “Prometey”, St. Petersburg, Russia
1. Гаршин А. П., Гропянов В. М., Зайцев Г. П. и др. Керамика для машиностроения. М.: Научтехлитиздат, 2003. 384 с.
2. Елисеев Ю. С., Крымов В. В., Колесников С. А., Васильев Ю. Н. Неметаллические композиционные материалы в элементах конструкций и производстве авиационных газотурбинных двигателей. М.: МГТУ им. Н. Э. Баумана, 2007. 368 с.
3. Мэттьюз Ф., Ролингс Р. Композиционные материалы. Механика и технология; пер. с англ. М.: Техносфера, 2004. 408 с.
4. Syrkov A. G., Kushchenko A. N., Maslennikov A. A. Professor P. P. Weimarn, founder of the science of nanotechnology: development of works in the field of nanodispersed metals production // Non-ferrous Мetals. 2024. No. 1. P. 63 – 71.
5. Зленко М. А., Нагайев М. В., Довбыш В. М. Аддитивные технологии в машиностроении: пособие для инженеров. М.: ГНЦ РФ ФГУП «НАМИ», 2025. 220 с.
6. Хрущов М. М., Бабичев М. А., Беркович Е. С. и др. Износостойкость и структура твердых наплавок. М.: Машиностроение, 1971. 96 с.
7. Хрущов М. М., Бабичев М. А. Абразивное изнашивание. М.: Наука, 1970. 252 с.
8. Гнесин Г. Г. Карбидокремниевые материалы. М.: Металлургия, 1977. 216 с.
9. Belyakov A. N., Markov M. A., Kravchenko I. N., et al. Contemporary materials and their application in the construction of special engineering high-temperature objects // Refract. Ind. Ceram. 2024. V. 64, No. 3. P. 256 – 264.
10. Markov M. A., Krasikov A. V., Kravchenko I. N., et al. Development of novel ceramic construction materials based on silicon carbide for products of complex geometry // Journal of Machinery Manufacture and Reliability. 2021. V. 50, No. 2. P. 158 - 163.
11. Дмитриева М. О., Мельников А. А., Носова Е. А. и др. Исследование формирования микроструктуры титанового сплава ВТ6 при изготовлении крыльчатки компрессора малоразмерного газотурбинного двигателя методами аддитивных технологий // Вестник Московского авиационного института. 2023. Т. 30, № 2. С. 196 – 203.
12. Belyakov A. N., Markov M. A., Dyuskina D. A., et al. A comparative study of methods for obtaining silicon carbide ceramic materials // Refract. Ind. Ceram. 2023. V. 64, No. 3. P. 299 - 310.
13. Belyakov A. N., Markov M. A., Kravchenko I. N., et al. Structural and physicomechanical properties of silicon carbide-based reaction-sintered ceramics // Russian Metallurgy (Metally). 2024. V. 2024, No. 7. P. 1536 – 1543.
14. Nesmelov D. D., Perevislov S. N. Reaction sintered materials based on boron carbide and silicon carbide // Glass and Ceramics. 2015. V. 71, No. 9–10. P. 313 – 319.
15. Dash W. C. Silicon crystals free of dislocations // Journal of Applied Physics. 1958. V. 29. P. 736 – 739.
16. Silicon carbide, a high temperature semiconductor: proceedings / ed. J. R. O'Connor, J. Smiltens. Symposium Publications Division, Pergamon Press, 1960. 521 p.
17. Nowotny H., Parthe E., Kieffer R., et al. Das Dreistoffsystem: Molybd?n–Silizium–Kohlenstoff // Monatshefte f?r Chemie. 1954. V. 85. P. 255 – 272.
18. Брохин И. С., Функе В. Ф. Твердые сплавы. М.: Металлургия, 1969. С. 226 – 239.
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