Plasma Spraying of Silicide Coatings to Protect Zirconium Alloys from Oxidation

I. B. Gnesin; Гнесин И. Б.; D. V. Prokhorov; Прохоров Д. В.; N. I. Gnesina; Гнесина Н. И.; A. N. Nekrasov; Некрасов А. Н.; B. A. Gnesin; Гнесин Б. А.; V. I. Vnukov; Внуков В. И.; M. I. Karpov; Карпов М. И.; I. S. Zheltyakova; Желтякова И. С.; T. S. Stroganova; Строганова Т. С.

doi:10.31857/S1028096023100059

Plasma Spraying of Silicide Coatings to Protect Zirconium Alloys from Oxidation

Authors: Gnesin I.B.¹, Prokhorov D.V.¹, Gnesina N.I.¹, Nekrasov A.N.², Gnesin B.A.¹, Vnukov V.I.¹, Karpov M.I.¹, Zheltyakova I.S.¹, Stroganova T.S.¹
Affiliations:
1. Institute of Solid State Physics RAS
2. Institute of Experimental Mineralogy RAS
Issue: No 10 (2023)
Pages: 27-35
Section: Articles
URL: https://journal-vniispk.ru/1028-0960/article/view/141023
DOI: https://doi.org/10.31857/S1028096023100059
EDN: https://elibrary.ru/VZYMAM
ID: 141023

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Abstract

The work is devoted to an experimental study of the possibilities of applying a protective silicide coating on an alloy based on zirconium (E110) by atmospheric plasma spraying. Coatings based on the binary eutectic Mo₅Si₃ + MoSi₂ were deposited on the surface of E110 alloy sheet. The features of the structure and phase composition of the coatings after deposition and their evolution as a result of isothermal annealing at a temperature of 1300°C are studied. Upon rapid cooling of silicide particles during coating, nonequilibrium phases are formed. As a result of annealing, the phase composition changes, which corresponds to the phase diagram. The kinetics of diffusion interaction between the coating and the base material has been studied. The possibility of successfully protecting a zirconium alloy from oxidation at 1100°C in air by complex deposition of a coating of molybdenum silicides has been shown for the first time. The minimum radius of curvature of the surface of the protected samples was about 1 mm.

Keywords

protective coatings, molybdenum silicides, protection against oxidation, thermogravimetry, zirconium, vapor-zirconium reaction, tolerant fuel, phase composition, microstructure, scanning electron microscopy.

References

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