Resistance of slurry erosion with HVOF coating: A review
Abstract
Erosion - corrosion in various industrial applications causes considerable financial losses. Industry adopts many surface treatment methods to resolve these issues. Recent research suggests erosion-resistant coatings are economical than other surface modification methods. Surface modification techniques include thermal spraying, chemical vapor deposition, physical vapor deposition, chemical vapor deposition, laser surface modification, plasma nitriding and ion implantation. In order to prolong the life of industrial components exposed to wear and corrosion, thermal spray methods have been widely employed to apply coatings of different composition. Among the different coating’s techniques, high velocity oxy-fuel spraying process is a novel and widely utilized thermal coating technology that produces a thick covering with a with porosity less than 1%. It is likely to achieve a coating thickness more than 1.5 mm by carefully controlling cooling to eliminate residual stresses. Increased durability, decreased porosity, and protection against erosion and corrosion are all results of using these spray procedures. The extensive utilization of HVOF coatings across various industries can be attributed to its notable characteristics. This review study analyzes how process deposition factors affect coatings physical, mechanical, wear, erosion, and corrosion properties.
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