This study aims to investigate the feasibility of forming iron aluminide coatings on a commercial 9Cr-lMo (wt.%) alloy steel by pack cementation at 650 °C in an attempt to improve its high temperature oxidation r...This study aims to investigate the feasibility of forming iron aluminide coatings on a commercial 9Cr-lMo (wt.%) alloy steel by pack cementation at 650 °C in an attempt to improve its high temperature oxidation resistance. Pack powders containing Al, A12O3 and a series of halide salts were used to carry out the coating deposition experiments, which enabled identification of the most suitable activator for the pack aluminising process at the intended temperature. The effect of pack aluminium content on the growth kinetics and microstructure of the coatings was then studied by keeping deposition conditions and pack activator content constant while increasing the pack aluminium content from 1.4 wt.% to 6 wt.%. X-ray diffraction (XRD), scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS) techniques were used to analyse the phases and microstructures of the coatings formed and to determine depth profiles of coating elements in the coating layer. Oxidation resistance of the coating was studied at 650 °C in air by intermittent weight measurement at room temperature. It was observed that the coating could substantially enhance the oxidation resistance of the steel under these testing conditions, which was attributed to the capability of the iron aluminide phases to form alumina scale on the coating surface through preferential Al oxidation.展开更多
基金The authors wish to thank the European Commission for funding this research under the SUPERCOAT programme contract ENK5-CT-2002-00608(SUPERCOAT).
文摘This study aims to investigate the feasibility of forming iron aluminide coatings on a commercial 9Cr-lMo (wt.%) alloy steel by pack cementation at 650 °C in an attempt to improve its high temperature oxidation resistance. Pack powders containing Al, A12O3 and a series of halide salts were used to carry out the coating deposition experiments, which enabled identification of the most suitable activator for the pack aluminising process at the intended temperature. The effect of pack aluminium content on the growth kinetics and microstructure of the coatings was then studied by keeping deposition conditions and pack activator content constant while increasing the pack aluminium content from 1.4 wt.% to 6 wt.%. X-ray diffraction (XRD), scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS) techniques were used to analyse the phases and microstructures of the coatings formed and to determine depth profiles of coating elements in the coating layer. Oxidation resistance of the coating was studied at 650 °C in air by intermittent weight measurement at room temperature. It was observed that the coating could substantially enhance the oxidation resistance of the steel under these testing conditions, which was attributed to the capability of the iron aluminide phases to form alumina scale on the coating surface through preferential Al oxidation.
