The application of these coatings is optimized for the formation of Optimization and performance evaluation of high-performance anticorrosive sealing coatings. The coating’s composition, temperature resistance, crack resistance, hardness, adhesive strength, and binding energy are analyzed to ensure its effectiveness against corrosion. The coatings are evaluated using zinc reduction measurements of the galvanized coating, which is a common method to assess the anti-corrosion properties of coatings.
The study discusses the implementation of Ce-based noble sealing coatings on insulator pins, but it also suggests that this approach could be adapted for other metal parts prone to corrosion in power industries. The reliability evaluation of these coatings is essential, with a desirable lifespan of at least 30–50 years, similar to that of high-voltage outdoor insulators. These coatings are also tested for resistance to temperature variations and harsh outdoor environments, which are critical for their application in industrial and marine sites where corrosion rates increase dramatically due to contaminated environments.
In summary, the high-performance anticorrosive sealing coating is likely a metal part coated with a cerium-based sealing coating for enhanced corrosion resistance, especially in harsh environments. This approach offers a sustainable solution for corrosion prevention in power industries, leveraging the properties of cerium to protect against corrosion while minimizing environmental impact.