C. J. Li, H. T. Wang, G. J. Yang, School of Materials Science and Engineering, Xi'an Jiaotong University, Xi'an, China; W. Y. Li, Northwestern Polytechnical University,, Xi'an, China; H. Liao, LERMPS-UTBM, Belfort, France
The critical velocity is an important parameter in cold spraying. It determines the deposition efficiency under a given spray condition. The critical velocity depends not only on materials types, but also particle temperature and oxidation conditions. In present paper, three types of materials including copper, 316L stainless steel, Monel alloy were used to deposit coatings by cold spray process. The critical velocities of spray materials were determined using a novel measurement method. Oxygen content in three powders was changed by isothermal oxidation at ambient atmosphere. The effect of oxygen content on the critical velocity was examined. It was found that the critical velocity in cold spray was significantly influenced by particle oxidation condition besides materials properties. The critical velocity of Cu particles changed from about 300m/s to over 610m/s with change of oxygen content in powder. It is evident that the materials properties influence the critical velocity more remarkable at low oxygen content than high oxygen content. The results suggest that with a severely oxidized powder the critical velocity tends to be dominated by oxide on the powder surface.
Summary: In present paper, three types of materials including copper, 316L stainless steel, Monel alloy were used to deposit coatings by cold spray process. The critical velocities of spray materials were determined using a novel measurement method. Oxygen content in three powders was changed by isothermal oxidation at ambient atmosphere. The effect of oxygen content on the critical velocity was examined. It was found that the critical velocity in cold spray was significantly influenced by particle oxidation condition besides materials properties. The critical velocity of Cu particles changed from about 300m/s to over 610m/s with change of oxygen content in powder. It is evident that the materials properties influence the critical velocity more remarkable at low oxygen content than high oxygen content. The results suggest that with a severely oxidized powder the critical velocity tends to be dominated by oxide on the powder surface.
