Tribological Properties of Nanostructured Diffusion Layers of Metal Coatings

Margarita Aleksandrovna Skotnikova; Galina V. Tsvetkova; Nikolay Alexandrovich Krylov

doi:10.4028/www.scientific.net/KEM.721.446

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 721Tribological Properties of Nanostructured...

Tribological Properties of Nanostructured Diffusion Layers of Metal Coatings

Abstract:

Copper nickel (Cu-Ni) coatings on products from instrumental steel H12M were drawn and they were subjected to subsequent intensive plastic deformation under stresses 3.0; 3.5; 4.0 and 4.5 GPa. The nanostructured surface, formation grains size of 13...173 nm with high-angle (at 3.0; 4.0; 4.5 GPa) and low-angle (dislocation) borders of grains (at 3.5 GPa), influencing redistribution of alloying elements and tribological properties was shown by means of methods of light and electronic microscopy, X-ray diffraction and micro-ray spectral analysis, and also tribological tests.

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Periodical:

Key Engineering Materials (Volume 721)

Pages:

446-450

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.721.446

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Online since:

December 2016

Authors:

Margarita Aleksandrovna Skotnikova*, Galina V. Tsvetkova, Nikolay Alexandrovich Krylov

Keywords:

Coverage, Intensive Plastic Deformation, Nanostructure, Wear

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References

[1] A.G. Sokolov, Development of theoretical and technology bases of increase of cutting and shtampovy tool firmness due to diffusion metallization from the environment of fusible zhidkometallichesky solutions, The abstract of thesis for Dr. of science degree, Krasnodar, (2008).

Google Scholar

[2] M.A. Skotnikova, S.A. Shasherina, N.A. Krylov, Research tribology properties nanostructure diffusion layers of metal coverages, Proceedings of XII International Conference on Nanostructured Materials (NANO 2014), Moscow (2014) 332.

Google Scholar

[3] Margarita A. Skotnikova, Galina V. Tsvetkova, Nikolay A. Krylov, Features of wear of abrasive grains depending on microcuttings speed of steels, Proceedings of the 24th International Conference Engineering materials & tribology- BALTMATTRIB 2015 Tallinn (2015).

DOI: 10.4028/www.scientific.net/kem.674.189

Google Scholar

[4] M.A. Skotnikova, N.A. Krylov, E.K. Ivanov, Study of tribological properties of nano-structured layers diffusion of metal coatings, Proceedings of V International Symposium on Transportation tribotechnology Transtribo 2013, St. Petersburg (2013).

Google Scholar

[5] M.A. Skotnikova, N.A. Krylov, G.V. Tsvetkova, Features of plastic deformation and wear of the abrasive grains during high-speed machining, J. Black metals. 4 (2014) 84-92.

Google Scholar

[6] Margarita A. Skotnikova, Galina V. Tsvetkova, Nikolay A. Krylov, Features of wear of abrasive grains depending on microcuttings speed of steels, J. Key Engineering Materials. 674 (2016) 358-364.

DOI: 10.4028/www.scientific.net/kem.674.189

Google Scholar