The paper presents the results of a study on the durability of cutting ceramics: a replaceable polyhedral plate developed
at NSTU and cutting ceramics WOK-60 when processing hardened steel blanks made of 40X (45HRC) steel. As a result
of the tests carried out, it was found that with the use of cutting modes developed at KNAU, the durability of SMP from cutting ceramics created at NSTU is more than 1.7 times higher than the performance of plates based on the WOK-60
material. At the same time, the roughness of the treated surface of the work piece was Ra = 0.35 ? 0.05 microns when using SMP from the developed ceramics Ra = 0.55 ? 0.05 microns when using WOK-60 plates. The stages of destruction
of cutting ceramic plates are revealed, taking into account the hierarchy of structural scales.
Mylnikov V. V. – PhD (Eng.), Candidate of Technical Sciences, Associate Professor of the Department of Construction Technologies, Faculty of Civil Engineering, Nizhny Novgorod State University of Architecture and Civil Engineering (TSP ISF NNGASU), Nizhny Novgorod, Russia.E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it..
Pronin A. I. – PhD (Eng.), Candidate of Technical Sciences, Associate professor of the Department of “Mechanical Engineering”, Komsomolsk-na-Amur State University (ME KnASU), Komsomolsk-on-Amur, Russia.E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it..
Veselov S. V. – PhD (Eng.), Candidate of Technical Sciences, Associate professor of the Department of “Materials Science in Mechanical engineering”, Novosibirsk State Technical University, (MSiME NSTU) Novosibirsk, Russia. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
Valko D. A. – graduate student of the Department of “Mechanical Engineering”, Komsomolsk-na-Amur State University (ME KnASU), Komsomolsk-on-Amur, Russia. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it..
1. Schulz H., Spur G. Aspect in Cutting Mechanism in High Speed Cutting // Annals of CIPR. 1989. V. 38, No. 1. P. 51 – 54.
2. Dawson Т. Т. Hard turning, tool life, and surface quality // Manufacturing Engineering, 2001. V. 126, No. 4. P. 88, 90, 92 – 94, 97 – 98.
3. Коr D. Hard turning might not be as hard as you think // Modem Machine Shop. V. 77, No. 4. 2004. P. 72 – 76.
4. Kishawy H., Dumitrescu M., Ng E. G., Elbestawi M. A. Effect of coolant strategy on tool performance, chip morphology and surface quality during high-speed machining of A356 aluminum alloy // Int. J. of Machine Tools and Manufacture. 2005. V. 45. P. 219 – 227.
5. Волков Д. И., Проскуряков С. Л. Динамическая модель зоны резания для условий высокоскоростного точения // Вестник Рыбинской государственной авиационной технологической академии им. П. А. Соловьева. 2011. № 1(19). С. 43 – 49.
6. Faassen R. P. H., van de Wouw N., Oosterling J. A. J., Nijmeijer H. Prediction of regenerative chatter by Мodeling and analysis of high-speed milling // Int. J. of Machine Tools & Manufacture. 2003. V. 43, No. 14. P. 1437 – 1446.
7. Козочкин М. Н., Сабиров Ф. С., Попиков А. Н. Виброакустическая диагностика при твердом точении // Вестник МГТУ «Станкин». 2009. № 1(5). С. 23 – 30.
8. Васильков Д. В., Кочина Т. Б. Силы резания при высокоскоростной обработке сплавов на никелевой основе инструментами из минералокерамики // Металлообработка. 2011. № 4(64). С. 10 – 13.
9. Гениатулин А. М. Анализ состояния и перспектив развития режущей керамики // Вестник КГУ. 2011. № 1. С. 56 – 58.
10. Васин С. А., Верещака А. С., Кушнер В. С. Резание материалов. Термомеханический подход к системе взаимосвязей при резании. М.: Изд-во МГТУ им. Н.Э. Баумана, 2001. 448 с.
11. Осипова И. И., Шведков Е. Л. Режущая керамика // Порошковая металлургия. 1992. № 9. С. 31 – 45.
12. Krstic V. D., Wang K. Reaction senturing of TiN–TiB2 ceramics // Acta Mater. 2003. V. 51, No. 6. P. 1809 – 1819.
13. Zhang Guo-Jun, Yang Jian-Feng, Ando Motohide, Ohji Tatsuki. Reactive hot pressing of alumina-silicon carbide nanocomposites // J. Amer. Ceram. Soc. 2004. V. 87, No. 2. P. 299 – 301.
14. Квашнин В. И., Зыкова Е. Д., Карпович З. А., Веселов С. В. Влияние диспергирования на усадку при спекании керамического материала системы Al2O3–Ti(C, N) // Наука. Технологии. Инновации: сб. науч. тр.: в 9 ч., Новосибирск, 3 – 7 дек. 2018 г. Новосибирск: Изд-во НГТУ, 2018. Ч. 3. С. 198 – 200.
15. Пронин А. И., Мыльников В. В., Валько Д. А., Синицын И. С. Исследование температуры резания при токарной обработке закаленных сталей, применяемых для изготовления деталей морских судов // Морские интеллектуальные технологии Marine intellectual technologies. 2021. Т. 2, № 2. С. 42 – 46.
16. Пронин А. И., Мыльников В. В., Щелкунов Е. Б., Чернышов Е. А. Исследование стойкости режущей керамики при точении закаленных стальных заготовок // Стекло и керамика. 2017. № 10. С. 26 – 28.
17. Pronin A. I., Myl’nikov V. V., Shchelkunov E. B., Chernyshov E. A. Investigation of cutting ceramic stability during sharpening of hardened steel blanks // Glass Ceram. 2018. V. 74, No. 9 – 10. Р. 364 – 366.
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DOI: 10.14489/glc.2022.01.pp.015-020
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