High temperature molten salt corrosion behavior of aluminide and nickel-aluminide coatings for heat storage in concentrated solar power plants

Sprayed slurry aluminide and nickel-aluminide coatings deposited by means of electrodeposition and slurry application to 9wt% Cr P91 alloy were studied to mitigate molten salt corrosion in concentrated solar power plants. Both coatings were tested isothermally at 580°C in contact with the Solar Salt...

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Bibliographic Details
Published in:Surface & coatings technology 2018-09, Vol.349, p.1148-1157
Main Authors: Audigié, P., Encinas-Sánchez, V., Juez-Lorenzo, M., Rodríguez, S., Gutiérrez, M., Pérez, F.J., Agüero, A.
Format: Article
Language:English
Subjects:
Aluminide coatings
Aluminides
Chemical etching
Coated electrodes
Coatings
Corrosion
Corrosion products
Corrosion rate
Heat storage
Heat treating
Heat treatment
High temperature
Interdiffusion
Intermetallic compounds
Iron oxides
Molten nitrates
Molten salts
Morphology
Nickel
Nickel alloys
Nickel-aluminide coatings
Organic chemistry
Oxidation
Power plants
Protective coatings
Scale (corrosion)
Slurries
Spallation
Steels
Substrates
Thermosolar plants
Ultrasonic testing
Weight
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Summary:Sprayed slurry aluminide and nickel-aluminide coatings deposited by means of electrodeposition and slurry application to 9wt% Cr P91 alloy were studied to mitigate molten salt corrosion in concentrated solar power plants. Both coatings were tested isothermally at 580°C in contact with the Solar Salt (60%wt% NaNO3, 40wt% KNO3) under static and dynamic conditions. Uncoated P91 showed considerable mass gains in both conditions and there was evidence of extensive spallation on both cases. Mass loss was therefore also measured after removing the corrosion products by chemical etching so that the corrosion rate could be better estimated. P91 developed a complex, fast growing multilayered oxide scale which included Fe2O3, Fe3O4 and NaFeO2 in molten nitrates whatever the test conditions. All the coated systems and in particular the nickel-aluminide coating in contact with the Solar Salt up to 1000h performed much better than the uncoated material as they exhibited lower weight variations and no evidence of significant spallation. The aluminide coating developed a thin Na ferrite scale as shown by SEM-EDS and XRD after testing under static conditions. On the tested nickel-aluminide coating NiAl2O4 was detected only by XRD, so it is not possible to establish if it resulted from the oxidation of the residual undiffused material left after heat treatment, or to a thin layer formed on top of the coating after exposure to molten salt. Interdiffusion between the coating and the substrate also occurred in the nickel-aluminide coating whereas the aluminide coating formed at high temperature remained quite stable both in composition and morphology. •The uncoated P91 developed a non-protective and fast growing multilayered oxide scale which included Fe2O3, Fe3O4 and NaFeO2.•All the coated systems performed much better than the uncoated P91 up to at least 1000 h at 580°C.•The nickel-aluminide had the better corrosion behavior amongst the studied systems.•The aluminide coating developed a thin Na ferrite scale whereas the nickel-aluminide coating developed a NiAl2O4 oxide.
ISSN:0257-8972
1879-3347
DOI:10.1016/j.surfcoat.2018.05.081