Graded coatings for thermal, wear and corrosion barriers
U. Schulz, M. Peters, Fr.-W. Bach, G. Tegeder
Materials Science
Abstract
The present paper summarizes the main results generated in a German National Science Foundation (DFG) program on projects concerned with functionally graded materials applied to optimize the thermal, wear and corrosion properties of metallic and ceramic materials. Thermal barrier coatings deposited onto Cu substrates by pulsed laser deposition showed improved spallation behavior by a graded lamella microstructure with improved interface fracture toughness. A particle-hardened graded surface structure improved the wear resistance of plasma sprayed thermal barriers. By means of evaporation techniques a graded bonding area was manufactured with a high potential of lifetime improvement.
For non-oxide ceramics graded coatings based on Si3N4 and mullite led to improved oxidation resistance of the substrate material. Graded TiC–TiN thin films allowed to improve the wear resistance of cutting tool alloys with good adhesion to the substrate material. On light metal alloys, the limits of grading with respect to corrosion protection as well as wear were determined. Graded layers of arc-sprayed titanium with in situ produced particles or welded alloy gradients led to improved wear characteristics. Stress profiles in graded layers were analyzed with the help of a modified X-ray diffraction analysis.
keywords:Functionally graded materials; Corrosion; Wear; Coatings; Zirconia; Mullite; Hard particles; BondingS
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