FATIGUE STRENGTH AND FRACTURE MECHANISMS OF CERAMIC‐ SPRAYED STEEL IN AIR AND A CORROSIVE ENVIRONMENT

Abstract

Abstract— In order to investigate the fatigue strength and fracture mechanism of ceramic‐sprayed steel, rotary bending fatigue tests were conducted at room temperature in air and 3% NaCl solution using specimens of a medium carbon steel (S45C) with sprayed coating layers of Ni‐5% A1 (under‐coating) and chromia (top‐coating). The results obtained are discussed based on observations of fatigue cracks and experimental data on specimens subjected to individual treatments during the ceramic spraying process. It was found that at a very early stage of fatigue life, cracks were initiated at the interface between under‐ and top‐coating layers, and grew rapidly into the ceramic‐sprayed layer. However, these cracks did not propagate continuously into the substrate, and the final failure was led by the growth of a crack newly initiated at the surface of the substrate steel. Thus, the fatigue strength of the ceramic‐sprayed steel in air could be evaluated due to the property of the substrate. The corrosion fatigue strength of ceramic‐ sprayed steel was improved when compared to that of the substrate steel. However, the coating layer contained many pores, through which NaCl solution was supplied from the specimen surface to the substrate. Corrosion pits were formed at the interface between the under‐coating and the substrate. Subsequently, cracks initiated from the pits and grew into the substrate. Tests were also conducted on specimens whose pores were closed by a shielding treatment. In this case, NaCl solution was supplied to the substrate by cracks initiated in the top‐coating layer. The shielding treatment was effective at low stress levels where fatigue life was more than 107 cycles, while it had little effect on improving corrosion fatigue strength at higher stress levels because of the many cracks initiated in the top‐coating layer.