Effect of post-spray annealing on the microstructure and corrosion resistance of nano-(Ti,V)N coatings

To improve the microstructure and properties of a nano-(Ti,V)N composite coating prepared by reactive plasma spray deposition, post-spray annealing was performed at 600 °C for durations of 1, 5, and 10 h, respectively. The microstructure and phase of the heat-treated coatings were analyzed by scanni...

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Bibliographic Details
Published in:Surface & coatings technology 2022-04, Vol.435, p.128268, Article 128268
Main Authors: Chi, YunLong, Jiang, Jie, Wang, YuXin, Mao, XingYe, Dong, Yanchun, Yang, Yong, He, JiNing
Format: Article
Language:English
Subjects:
(Ti,V)N coatings
Annealing
Corrosion behaviors
Corrosion effects
Corrosion potential
Corrosion rate
Corrosion resistance
Electrolytic cells
Electron microscopy
Grain size
Heat treatment
Microcracks
Microscopy
Microstructure
Porosity
Post-spraying treatment
Protective coatings
Reactive plasma spraying
Residual stress
Spray deposition
Substrates
Titanium
Vanadium
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Summary:To improve the microstructure and properties of a nano-(Ti,V)N composite coating prepared by reactive plasma spray deposition, post-spray annealing was performed at 600 °C for durations of 1, 5, and 10 h, respectively. The microstructure and phase of the heat-treated coatings were analyzed by scanning electron microscopy, X-ray diffraction, and transmission electron microscopy, and the change in the residual stress of the coating at different holding times was measured using the sin2ψ method. The corrosion resistances of the coatings were evaluated by electrochemical testing. The main phases of the reactive plasma sprayed nano- (Ti,V)N coating were determined to be TiVN2 and Ti3O. With an increase in the holding time, the proportion of the Ti3O phase increased and an oxide TiVO4 appearred. The TiVN2 grain size gradually increased. The coating with the lowest porosity and best corrosion resistance was obtained with an annealing time of 1 h. The maximum corrosion potential was −0.345 V, and the minimum corrosion rate was 8.24 × 10−2 mm/y. The (Ti,V)N coating did not form primary cells like metals when exposed to 3.5 wt% NaCl, but electrolyte solvents penetrated into the coating through pores and microcracks and corroded the substrate. The corrosion resistance of the annealed (Ti,V)N coatings was significantly improved, exhibiting a first immersion stage 48 times longer than that of the untreated coating. •When the nano-(Ti,V)N coatings were annealed at 600 °C TiVN2 oxidized to Ti3O, TiVO4 and V2O3 with lower densities than TiVN2.•Post-spraying annealing decreased porosity and eliminated part of residual stress of the nano-(Ti,V)N coating prepared by reactive plasma spraying.•The corrosion resistance of the nano-(Ti,V)N coating improved with increasing density.
ISSN:0257-8972
1879-3347
DOI:10.1016/j.surfcoat.2022.128268