Tribological behavior of cold sprayed Inconel 718 coatings at room and elevated temperatures
Tribological behavior of cold sprayed Inconel 718 coatings at room and elevated temperatures
In this study, Inconel 718 coatings were fabricated by high pressure cold spray deposition and the microstructure and tribological properties of the coatings were systematically investigated at both room and elevated temperatures. At the first place, the investigation on the effect of thermal exposure on the surface oxidation of the coatings was conducted in the absence of sliding. It was found that oxides started to form on the coating surface when the ambient temperature was above 500 °C. At 600 °C, a NiFe2O4 spinel oxide layer spread over the coating surface. Under sliding against an Al2O3 counter ball, oxides started to form on the coating surfaces in contact with the ball when the ambient temperature was above 200 °C due to the fact that the frictional and external heat had facilitated the formation of the oxides. Thus, the friction coefficients of the Inconel 718 coatings decreased with the increase of ambient temperatures. However, the wear rates of the coatings increased at 100 °C and 200 °C compared to those of the coatings tested at room temperature, which was due to the decrease of hardness and severe abrasive wear. When the ambient temperature was further increased to 300 °C, a transition in wear mechanism occurred and the wear rates decreased due to the formation and breakage of the surface oxides that could act as lubricants between the counter ball and coating. With further increase of ambient temperature, a ‘glaze’ layer was formed and grew on the wear tracks, which could act as a protective layer and showed a load-bearing effect that prevented further removal of the coating materials, resulting in an improved wear resistance of the Inconel 718 coatings at elevated temperatures. Therefore, cold sprayed Inconel 718 coatings could be potentially used under wear conditions at elevated temperatures.
High pressure cold spray, High temperature, Inconel 718 coating, Oxidation, Wear
Sun, Wen
38403bb0-2b99-4958-b9ee-39b4016d0968
Tan, Adrian Wei Yee
3d644676-a520-4f41-b7f1-410d1c46689d
King, Donavan Jia Ying
e3088b13-1a9a-4804-8c9b-17521298b04c
Khun, Nay Win
5218a552-1378-4f19-8aa9-eee5b38d939f
Bhowmik, Ayan
d5756d8b-4fd7-4272-987f-35901f169cf6
Marinescu, Iulian
eb6fb154-1605-451d-a446-f3148bb0da0b
Liu, Erjia
f0eb8f01-7079-4d8a-9687-f00250b31ffd
15 March 2020
Sun, Wen
38403bb0-2b99-4958-b9ee-39b4016d0968
Tan, Adrian Wei Yee
3d644676-a520-4f41-b7f1-410d1c46689d
King, Donavan Jia Ying
e3088b13-1a9a-4804-8c9b-17521298b04c
Khun, Nay Win
5218a552-1378-4f19-8aa9-eee5b38d939f
Bhowmik, Ayan
d5756d8b-4fd7-4272-987f-35901f169cf6
Marinescu, Iulian
eb6fb154-1605-451d-a446-f3148bb0da0b
Liu, Erjia
f0eb8f01-7079-4d8a-9687-f00250b31ffd
Sun, Wen, Tan, Adrian Wei Yee, King, Donavan Jia Ying and Liu, Erjia
,
et al.
(2020)
Tribological behavior of cold sprayed Inconel 718 coatings at room and elevated temperatures.
Surface and Coatings Technology, 385 (3), [125386].
(doi:10.1016/j.surfcoat.2020.125386).
Abstract
In this study, Inconel 718 coatings were fabricated by high pressure cold spray deposition and the microstructure and tribological properties of the coatings were systematically investigated at both room and elevated temperatures. At the first place, the investigation on the effect of thermal exposure on the surface oxidation of the coatings was conducted in the absence of sliding. It was found that oxides started to form on the coating surface when the ambient temperature was above 500 °C. At 600 °C, a NiFe2O4 spinel oxide layer spread over the coating surface. Under sliding against an Al2O3 counter ball, oxides started to form on the coating surfaces in contact with the ball when the ambient temperature was above 200 °C due to the fact that the frictional and external heat had facilitated the formation of the oxides. Thus, the friction coefficients of the Inconel 718 coatings decreased with the increase of ambient temperatures. However, the wear rates of the coatings increased at 100 °C and 200 °C compared to those of the coatings tested at room temperature, which was due to the decrease of hardness and severe abrasive wear. When the ambient temperature was further increased to 300 °C, a transition in wear mechanism occurred and the wear rates decreased due to the formation and breakage of the surface oxides that could act as lubricants between the counter ball and coating. With further increase of ambient temperature, a ‘glaze’ layer was formed and grew on the wear tracks, which could act as a protective layer and showed a load-bearing effect that prevented further removal of the coating materials, resulting in an improved wear resistance of the Inconel 718 coatings at elevated temperatures. Therefore, cold sprayed Inconel 718 coatings could be potentially used under wear conditions at elevated temperatures.
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Published date: 15 March 2020
Additional Information:
Funding Information:
This work was financially supported by the Industry Alignment Fund (IAF) of Singapore A*STAR , Rolls-Royce (RR) and Nanyang Technological University , Singapore (NTU) under the research grant: ARMS 1.1 Advanced Metallized Coatings using Cold Spray.
Funding Information:
This work was financially supported by the Industry Alignment Fund (IAF) of Singapore A*STAR, Rolls-Royce (RR) and Nanyang Technological University, Singapore (NTU) under the research grant: ARMS 1.1 Advanced Metallized Coatings using Cold Spray.
Publisher Copyright:
© 2020 Elsevier B.V.
Keywords:
High pressure cold spray, High temperature, Inconel 718 coating, Oxidation, Wear
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Local EPrints ID: 475740
URI: http://eprints.soton.ac.uk/id/eprint/475740
ISSN: 0257-8972
PURE UUID: 814b0830-e960-485c-9dd0-bb7b9b49b8dc
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Date deposited: 27 Mar 2023 16:45
Last modified: 17 Mar 2024 13:14
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Contributors
Author:
Wen Sun
Author:
Adrian Wei Yee Tan
Author:
Donavan Jia Ying King
Author:
Nay Win Khun
Author:
Ayan Bhowmik
Author:
Iulian Marinescu
Author:
Erjia Liu
Corporate Author: et al.
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