In-situ surface hardening of cast iron by surface layer metallurgy

Abstract

Abrasive wear is a serious problem in many cast iron castings used in industry. To minimize failure and repair of these components, different strategies exist to improve their surface microhardness thus enhancing their wear resistance. However, most of these methods lead to very brittle and/or expensive castings. In the current work a new method for surface hardening is presented which utilizes surface layer metallurgy to generate in-situ a boron-enriched white cast iron surface layer with a high microhardness on a gray cast iron casting. To do this, sand molds are coated with a ferroboron suspension and cast with a cast iron melt. After solidification, a 100–900µm thick layer of boron-enriched ledeburite is formed on the surface of the casting which produces an increase in the average microhardness from 284 HV0.1±52 HV0.1 to 505 HV0.1±87 HV0.1. Analyses of the samples׳ core reveal a typical cast iron microstructure which leads to the conclusion that the coating mainly affects the castings׳ surface. By varying the grain size of the ferroboron powder in the coatings, it is shown that a powder size ≤100µm is most suitable to create a boron-enriched ledeburite surface layer possessing high hardness values.