Journals →  CIS Iron and Steel Review →  2022 →  #1 →  Back

Coatings application and Corrosion protection
ArticleName Features and regularities in formation of diffusion nickel-copper coatings on steels in the medium of low-melting liquid-metal solutions
DOI 10.17580/cisisr.2022.01.11
ArticleAuthor A. G. Sokolov, E. E. Bobylev
ArticleAuthorData

Kuban State Technological University (Krasnodar, Russia):

A. G. Sokolov, Dr. Eng., Prof.
E. E. Bobylev, Cand. Eng., Senior Lecturer, e-mail: ebobylev@mail.ru

Abstract

The paper considers the features and regularities of formation of Ni-Cu based diffusion coatings on the surface of steel products obtained as a result of diffusion metallization from the medium of low-melting liquid metal solutions. It was found out that a solid solution of Ni, Cu, Fe was formed in the main layer of coatings after applying the Ni-Cu coating on armco-iron, steel 20 and tool steel Kh12MF; it was characterized by approximately equal concentration of nickel and copper on the coating surface, it made 55 % Ni and 27 % Cu. As soon as the depth of the base layer increases, concentration of Ni and Cu in it gradually decreases, while the iron content also increases. During formation of Ni–Cu coatings on alloyed steels, selective diffusion of steel alloying elements deep into the coating is observed. It is established that the coatings have two layers – the main and the transition ones. At the same time, the maximal coating thickness constitutes 55 μm at the saturation temperature of 1150 °C and 6 hours duration. It was revealed that the main layer consists of Ni, Cu, Fe solid solution, also contains steel alloying elements and consists of columnar grains elongated in the direction of diffusion of the coating elements, as well as in its surface layer with thickness of about 5 μm. The layer of nano-scale grains with a cross-section size of 80-100 nm is forming. During formation of Ni-Cu based coatings, the phenomenon of displacement of the coating carbon and the steel alloying elements into the transition layer is confirmed; these carbon and steel elements do not interact with the coating elements. 

The innovation project was conducted under financial support of the Kuban scientific fund within the framework of the Competition of scientific-innovation projects directed on commercialization No. NIP-20.1-62/20.

keywords Chemical and thermal treatment, diffusion, coatings, coating formation mechanism, diffusion metallization
References

1. Sokolov A. G., Bobylyov E. E., Plomod'ialo R. L. Influence of carburization on the structure and properties of functional diffusion coatings based on titanium carbide on TiC-WC-Co and WCCo alloys. Materials Letters. 2020. Vol. 10. No. 4. pp. 410-415.
2. Dumitrescu L., Maury F.. Al2O3 coatings on stainless steel from Al metal-organic chemical vapor deposition and thermal treatments. Surface and Coatings Technology. 2000. Vol. 125. No. 1-3. pp. 419–423. DOI: 10.1016/s0257-8972(99)00616-7.
3. Rao Mei et al. Effect of Ni content in Cu1-Ni coating on microstructure evolution and mechanical properties of W/Mo joint via low-temperature diffusion bonding. Journal of Materials Science & Technology. 2020. Vol. 54. pp. 171-180. DOI: 10.1016/j.jmst.2020.02.005.
4. Sokolov A. G., Bobylyov E. E. The kinetics of coating formation on the base of titanium carbide, applied technology diffusion metallization from environment of the fusible liquid metal solutions, on the hard alloys. Metal working and material science. 2016. Vol. 71. No. 2. pp. 59-69.

5. Su Xingzhi et al. Formation of chromium carbide coatings on HT250 steel by thermal diffusion processes in fluoride molten salt bath. Vacuum. 2018. Vol. 155. pp. 219-223. DOI: 10.1016/j.vacuum.2018.06.015.
6. Qiaojun Wu et al. Assessment of diffusion mobility for bcc phase of Ti–Al–Ni ternary system. Computer Coupling of Phase Diagrams and Thermochemistry. 2020. Vol.71. 102203. DOI: 10.1016/j.calphad.2020.102203
7. Zhang Jin et al. Anti-wear titanium carbide coating on lowcarbon steel by thermo-reactive diffusion. Surface and Coatings Technology. 2019. Vol. 364. pp. 265-272. DOI: 10.1016/j.surfcoat.2019.02.085.
8. Medvedovski E. et al. Influence of multi-layered thermal diffusion coatings on high-temperature sulfidation resistance of steels. Surface and Coatings Technology. 2020. Vol. 403. 126430. DOI: 10.1016/j.surfcoat.2020.126430.
9. Shatinskiy V. F., Zbozhnaya O. M., Maksimovich G. G. Production of diffusion coatings in the medium of low-melting metals. Kiev : Naukova dumka. 1976. 202 p.
10. Artemyev V. P. Development of scientific and technological grounds of steel chemical and thermal treatment in liquid metal melts. Dissertation… of Doctor of Technical Sciences: 05.01.02. Krasnodar. 2001. 352 p.
11. Maksimovich G. G., Shatinskiy V. F., Goikhman M. S. Diffusion coatings by noble metals. Kiev : Naukova dumka. 1978. 168 p.
12. Sokolov A. G. Development of theoretical and technological grounds of cutting and stamping tool durability due to diffusion metallization from the media of low-melting liquid metal solutions. Dissertation… of Doctor of Technical Sciences: 05.01.02. Krasnodar. 2008. 383 p.

Full content Features and regularities in formation of diffusion nickel-copper coatings on steels in the medium of low-melting liquid-metal solutions
Back