A. Choudhiri, P. S. Mohanty, University of Michigan, Dearborn, MI; J. Karthikeyan, ASB Industries, Inc, Barberton, OH
Bioceramics such as hydroxyapatite (HAP) have been conventionally deposited by plasma spray technique. However, due to the inherent high temperature in the plasma, deleterious effects such as evaporation, phase alteration, residual stress, debonding, and gas release etc., commonly occur in these coatings. This paper presents a novel approach to deposit bioceramic coatings at temperatures well below their melting point by cold spray. Composite powders of titanium and HAP were deposited using CGT Kinetic 4000 system. The influence of the process parameters, powder quality as well as HAP to titanium ratio has been investigated. It was observed that dense composite coatings, containing up to 30% HAP can be deposited by this technique. Due to differential densities between the powders, as well as the adhesion mechanism, the HAP content in the deposit was a few percent lower than the powder mixture. XRD analysis indicated that the phase composition of the HAP in the deposit was identical to that of the powder. Further, the bond strength of the deposit was comparable/better to that of the plasma sprayed HAP. Coatings deposited using this process hold tremendous potential for improving bone integration of a wide range of dental and orthopedic implants.
Summary: This paper presents a novel approach to deposit bioceramic coatings at temperatures well below their melting point by cold spray. The influence of the process parameters, powder quality as well as HAP to titanium ratio has been investigated. It was observed that dense composite (Ti/HAP) coatings, containing up to 30% HAP can be deposited by this technique. XRD analysis indicated that the phase composition of the HAP in the deposit was identical to that of the powder. Coatings deposited using this process hold tremendous potential for improving bone integration of a wide range of dental and orthopedic implants