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Purpose: The aim of this paper concerns the manufacturing of nanocomposite Ni/diamond surface layers deposited on S235JR carbon steel using electrocrystallization method and examinations of their structures and properties. Design/methodology/approach: The performed research covers Ni/diamond nanocomposite layers and for comparison purposes also nickel layers produced by the electrocrystallization method. The disperse phase structure and whole produced layers were characterized by: X-ray diffraction (XRD), scanning electron microscope (SEM), optical microscopy. The realized research was performed to select the features of the produced layers such as microhardness, tribological properties and corrosion resistance. Findings: The results of completed studies indicate on a compact structure and a good adhesion of produced layers with the steel substrate. The Ni/diamond nanocomposite layer shave a higher hardness and wear resistance, as well as greater corrosion resistance tested in a corrosive environment as compared to Ni nanocrystalline layers. Research limitations/implications: It is reasonable to continue further research on influences of different amount of nanodiament in nickel matrix and its impact on the tribological, corrosion, and thermal properties so produced nanocomposite layers.
Wydawca
Rocznik
Tom
Strony
34--40
Opis fizyczny
Bibliogr. 11 poz., rys., tab.
Twórcy
autor
- Institute of Precision Mechanics, ul. Duchnicka 3, 01-796 Warszawa, Poland
autor
- Institute of Precision Mechanics, ul. Duchnicka 3, 01-796 Warszawa, Poland
Bibliografia
- [1] X.G. Cao, H.Y. Zhang, Investigation into conductivity of silver-coated cenosphere composites prepared by a modified electroless process, Applied Surface Science 264 (2013) 756-760.
- [2] S. Wang, X. Huang, M. Gong, W. Huang, Microstructure and mechanical properties of Ni-P-Si3N4 nanowire electroless composite coatings; Applied Surface Science 357 (2015) 328-332.
- [3] S. Faraji, A.H. Faraji, S.R. Noori, An investigation on electroless Cu–P composite coatings with micro and nano-SiC particles, Materials and Design 54 (2014) 570-575.
- [4] V. Goel, P. Anderson, J. Hall, F. Robinson, S. Bohm, Electroless Co–P-Carbon Nanotube composite coating to enhance magnetic properties of grain-oriented electrical steel, Journal of Magnetism and Magnetic Materials 407 (2016) 42-45.
- [5] B. Szeptycka, A. Gajewska-Midziałek, Nanocomposite nickel-graphene coatings produced by electrochemical reduction method, Materials Engineering 3/205 (2015) 112-115 (in Polish).
- [6] K.-H. Houa, H.-T.Wang, H.-H. Sheu, M.-D. Gerc, Preparation and wear resistance of electrodeposited Ni–W/diamond composite coatings, Applied Surface Science 308 (2014) 372-379.
- [7] M.S. Sataev, S.T. Koshkarbaeva, S. Perni, S.Z. Nauryzova, P. Prokopovich, A galvanic-chemical method for preparing diamond containing coatings, Colloids and Surfaces A: Physicochemical and Engineering Aspects 480 (2015) 384-389.
- [8] I. Petrov, P. Detkov, A. Drovosekov, M.V. Ivanov, T. Tyler, O. Shenderova, N.P. Voznecova, Y.P. Toporov, D. Schulz, Nickel galvanic coatings co-deposited with fractions of detonation nanodiamond, Diamond & Related Materials 15 (2006) 2035-2038.
- [9] G. Cielak, A. Mazurek, M. Trzaska, Ni/grapheme composite layers produced by means of the electrochemical reduction method, Surface Engineering 3 (2015) 44-47 (in Polish).
- [10] M. Betiuk, K. Burdyski, S. Joczyk, A. Szczepaski, K. Niedwiedzki, „Wirotest” and „Kulotester” – control and measurement devices for measuring material characteristics, Surface Engineering 2 (2008) 50-56 (in Polish).
- [11] M. Betiuk, K. Burdyski, J. Michalski, P. Wach, Reveal of thin layers and coatings structures in metallographical investigations by using Kulotester, Surface Engineering 3 (2007) 70-74 (in Polish).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-c677dead-dd74-4056-86e7-98f5b1333254