Persistence of the thin layers of transition metal carbides in contact with liquid NiBSi alloy
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Abstract
The article presents the results of study on interaction between the liquid NiBSi alloy and solid, thin, micrometer-range layers of transition metal carbides of IVB - VIB groups of the periodic table. The reactive magnetron sputtering method was adopted to deposit of these layers on molybdenum substrates. Carbide layers are destroyed in contact with liquid alloy by dissolving, intensified by the penetration of the liquid along the coating - substrate interface. The strong interaction between liquid NiBSi and both the carbide ceramics and the refractory metal substrate was revealed. The effect intensity differs somewhat for both tested carbide groups: IVB (relatively fast) and VIB (less intense).
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How to Cite
[1]
M. Bober, J. Senkara, and B. Wendler, “Persistence of the thin layers of transition metal carbides in contact with liquid NiBSi alloy”, Weld. Tech. Rev., vol. 93, no. 1, pp. 5-12, Feb. 2021.
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This work is licensed under a Creative Commons Attribution 4.0 International License.
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Senkara J., Windyga A., Podstawy teorii procesów spajania, Wyd. Politechniki Warszawskiej, 1990.
Bober M., Jakubowski J., Radziszewski A., Senkara J., Microstructure and mechanical properties of Ni-WC thermal sprayed composite coatings, Advances in Materials Science, 2018, vol. 18, 24-34.
Bober M., Grześ J., The structure of Ni-TiC composite coatings deposited by PPTAW method, Composites Theory and Practice, 2015, vol. 2, 72-77.
Jakubowski J., Wysocki P., Senkara J., Selektywne regeneracyjne napawanie plazmowe warstw Ni-WC na tytanowe łopatki sprężarki silnika lotniczego, Welding Technology Review, 2011, vol. 83, 38-42.
Bober M., Senkara J., Badania struktury kompozytowych powłok Ni-WC napawanych plazmowo, Welding Technology Review, 2016, vol. 88, 67-70.
Bober M., Senkara J., Comparative tests of plasma-surfaced nickel layers with chromium and titanium carbides, Welding International, 2016, vol. 30, 32-37.
Dul I., Kopeć J. i in., Wpływ wybranych czynników technologicznych na proces lutowania próżniowego stopów Ni i stali wysokostopowej 18-8, Welding Technology Review, 2009, 77-80.
[10] Babul T., Jakubowski J. i in., Lutowanie próżniowe uszczelnień ulowych w aparatach kierujących wykonanych ze stopów Hastelloy i Inconel z zastosowaniem lutu NiCrSiB, Welding Technology Review, 2007, 79, 124-129.
CRC Handbook of Chemistry and Physics, 99th Edition, Taylor&Francis, 2018.
Bober M., Oddziaływania międzyfazowe w technologii napawania plazmowego warstw na osnowie Ni z węglikami metali przejściowych. PhD Thesis, Warsaw University of Technology, Warsaw, 2009.
Senkara J., Sterowanie energią adhezji pomiędzy molibdenem i wolframem a ciekłymi metalami w procesach spajania, Wydawnictwa Politechniki Warszawskiej, 1993.
Oukach S., Pateyron B., Pawłowski L., Physical and chemical phenomena occurring between solid ceramics and liquid metals and alloys at laser and plasma composite coatings formation: A review, Surface Science Reports, 2019, vol. 74, 213-241
Jansson U., Lewin E., Sputter deposition of transition-metal carbide films — a critical review from a chemical perspective. Thin Solid Films, 2013, vol. 536, 1-24.
Tokunaga T., Nishio K., Ohtani H., Hasebe M., Phase equilibria in the Ni-Si-B system. Materials Transactions, 2003, vol. 44, 1651-1654.
Peng H., Liu C., Guo H., Yuan Y., Gong S., Xu H., Fabrication of WCp/NiBSi metal matrix composite by electron beam melting, Materials Science and Engineering: A, 2016, vol. 666, 320-323.
Liu C., H Peng H., Y Zhao Y., Y Yuan Y., Guo H.B., Xu H.B., Microstructure, mechanical and corrosion properties of electron-beam-melted and plasma-transferred arc-welded WCP/NiBSi metal matrix composites, Rare Metals, 2019, vol. 38, 814–823.
Żak A., Sawras K., Dudziński W., Wpływ składu mieszanin NiCrBSiFe+ WSC i NiBSi+ WSC na ich mikrostrukturę i twardość, Welding Technology Review, 2016, vol. 88, 39-41.
Reeks W., Davies H., Marchisio S., A review: Interlayer joining of nickel base alloys, Journal of Advanced Joining Processes, 2020, vol. 2, 1000302020, https://doi.org/10.1016/j.jajp.2020.100030.
Sundaramoorthy R., Tong S.X., Parekh D., Subramanian C., Effect of matrix chemistry and WC types on the performance of Ni-WC based MMC overlays deposited by plasma transferred arc (PTA) welding, Wear, 2017, vol. 376–377, 1720-1727.