| ArticleName |
Nitriding of hard alloys T15K6 and T14K8 |
| ArticleAuthorData |
Orenburg State University, Orenburg, Russia:
S. I. Bogodukhov, Professor at the Department of Materials Science and Technology, Doctor of Technical Sciences, Professor, e-mail: ogu@mailgate.ru
E. S. Kozik, Associate Professor at the Department of Materials Science and Technology, Candidate of Technical Sciences, e-mail: ele57670823@yandex.ru
E. V. Svidenko, Lecturer at the Department of Materials Science and Technology, Candidate of Technical Sciences, e-mail: tzvetkova.katia2016@yandex.ru |
| Abstract |
The authors of this paper performed ion implantation of hard alloys T14K8 and T15K6. According to the procedure, ions of any composition (e.g. ions of boron, nitrogen, titanium, tungsten, molybdenum and other elements) are implanted into the tool surface in a special unit at vacuum pressure of 1.33·103 Pa. This leads to a double rise in the tool durability. They are commonly tools made of high-speed steel that are subjected to implantation. At the same time, this technique failed to find a broad application due to sophisticated equipment required and because of non-uniform saturation of the surface layer. Besides, more research into that process is needed. This paper looks at the effect of nitriding on the mechanical properties and performance of TK group hard alloys (i.e. dual-carbide tungsten-cobalt alloys): T15K6 and T14K8. The following specimens were used in the experimental study: 5×5×35 mm splines made of hard alloys T14K8 and T15K6, three-edged and triangular plates made of hard alloys T5K10 and T15K6 and four-edged plates made of hard alloy T15K6. The authors noted a slight increase in microhardness after 1 hour of nitriding: by 7% for T15K6 and by 11% for T14K8. The hardness of the hard alloy T14K8 rose by 7% (from 1,300 to 1,400 HV), while the hardness of the hard alloy T15K6 – by 9% (from 1,450 to 1,600 HV). Compared with the initial specimens, the strength of the specimens subjected to nitriding increased by 25% for T14K8 and by 36% for T15K6. Compared with the initial specimens, after nitriding the diamond-abrasive wear was half as much. Nitriding of the T14K8 and T15K6 grades of hard alloys is a long process taking around 9 hours, but it helps build a surface layer (2.5 μm deep for T14K8 and 2.2 μm deep for T15K6) that enhances the performance of hard alloys. Thus, the cutting wear drops 3 times. |
| References |
1. Zhang Li, Wang Yuan-jie, Yu Xian-wang, Chen Shu et al. Crack propagation characteristic and toughness of functionally graded WC – Co cemented carbide. International Journal of Refractory Metals and Hard Materials. 2020. Vol. 26, No. 4. pp. 295–300.
2. Colovcan V. T. Some analytical consequences of experiment data on properties of WC – Co hard metals. International Journal of Refractory Metals and Hard Materials. 2021. Vol. 26, No. 4. pp. 301–305.
3. Guo Zhixing, Xiong Ji, Yang Mei, Jiang Cijin. WC – TiC – Ni cemented carbide with enhanced properties. Journal of Alloys and Compounds. 2020. Vol. 465, No. 1-2. pp. 157–162.
4. Kreymer G. S. Strength of hard alloys. Moscow : Metallurgiya, 1971. 247 p.
5. Panov V. S., Chuvilin A. M. The technology and properties of sintered hard alloys and items made of them. Moscow : MISIS, 2001. 428 p.
6. Bock H., Hoffman H., Blumenauer H. Mechanische eigenschaften von wolframkarbid-kobalt legierugen. Technik. 1976. Vol. 31, No. 1. pp. 47–51.
7. Gurland J. The fracture strength of sintered WC – Co alloys in relation to composition and particle spacing. Transactions of the Metallurgical Society of AIME. 1963. Vol. 227, No. 1. pp. 28–43.
8. Suzuki H., Hayashi K. Strenght of WC – Co cemented carbides in relation to their fracture sources. Planseeber. Pulverment. 1975. Vol. 23, No. 1. pp. 24–36.
9. Tokova L. V., Zaitsev A. A., Kurbatkina V. V., Levashov E. A. et al. Features of the influence of ZrO2 and WC nanodispersed additives on the properties of metal matrix composite. Russian Journal of Non-Ferrous Metals. 2019. Vol. 55, No. 2. pp. 186–190.
10. Bogodukhov S. I. Materials science. Moscow : Staryi Oskol, 2021. 536 p.
11. Bondarenko V. A. Ensuring the quality and enhancing the characteristics of cutting tools. Moscow : Mashinostroenie, 2000. 428 p.
12. Libenson G. A. Powder metallurgy processes. Moscow : Izdatelstvo MISiS, 2001. Vol. 1. 320 p.
13. Kim C. S., Massa T. P., Rohrer G. S. Modeling the relationship between microstructural features and the strength of WC – Co composites. International Journal of Refractory Metals and Hard Materials. 2020. Vol. 24, Iss. 1. pp. 89–100.
14. Yamamoto T., Ikuhara Y., Watanabe T. et al. High resolution microscopy study in Cr3C2 – doped WC – Co. Journal of Materials Science. 2001. Vol. 36. pp. 3885–3890.
15. Jaensson B. O. Die untersuchung von verformungsersheinungen in hochfeste WC – Co Legierungeenmit hilfeeinesneuen localisierung sverfahrens fur die abdruckelektronenmicroscopie. Practical Metallography. 1972. Vol. 9, No. 11. pp. 624–641.
16. Bogodukhov S. I. Use of strain measurement tools to determine modulus of elasticity of various materials. Vestnik of the Orenburg State University. 2014. No. 4. pp. 289–295.
17. Tretiakov A. F., Tarasenko L. V. Materials sciences and processing. Moscow : Izdatelstvo MGTU im. N. E. Baumana, 2019. 541 p.
18. Gordeev Yu. I., Yasinskiy V. B., Binchurov A. S. Sintered hard alloy production method. Patent RF, No. 2679026. Applied: 21.12.2017. Published: 05.02.2019.
19. Sokolov A. G. Method of hard-alloy tool machining. Patent RF, No. 2509173. Applied: 12.02.2013. Published: 10.03.2014.
20. Bogodukhov S. I., Kozik E. S., Svidenko E. V. Hard alloys hardening method. Patent RF, No. 2693238. Applied: 18.10.2018. Published: 01.07.2019.
21. Oskolkova T. N., Budovskikh E. A. Procedure for tungsten-cobalt hardalloyed tool surface hardening. Patent RF, No. 2398046. Applied: 27.08.2009. Published: 27.08.2010.
22. Khindrik E. Cutting tool insert for steels turning. Patent RF, No. 2536014. Applied: 29.06.2010. Published: 20.12.2014.
23. Slesarchuk V. A. Materials science and engineering. Minsk : RIPO, 2019. 391 p.
24. GOST 3882–74. Sintered hard alloys. Types. Introduced: 01.01.1976.
25. GOST 3647–80 (instead of GOST 3647–71). Abrasives. Grain sizing. Graininess and fractions. Test methods. Introduced: 01.01.1982.
26. GOST 9206–80. Diamond powders. Specifications. Introduced: 01.07.1981.
27. GOST 4728–2010. Axle billets for railway rolling stoсk. Introduced: 01.09.2011.
28. GOST 17367–71. Metalls. Method of abrasion test by friction against embedded abradant grains. Introduced: 01.01.1973. |
