Issue 8

R. Ghelichi et alii, Frattura ed Integrità Strutturale, 8 (2009) 30-44; DOI: 10.3221/IGF-ESIS.08.03 41 T HE EFFECT OF CGDS ON SUBSTRATE PROPERTIES he effect cold spray coating process on many substrate properties specially the fatigue behavior was studied by many authors. T.S. Price et al. [56] studied the Effect of Cold Spray Deposition of a Titanium Coating on Fatigue Behavior. Thus, Coatings were deposited onto samples with two different surface preparation methods (as- received and grit-blasted). The fatigue life of the as-received and grit-blasted materials, both before and after coating was measured. A 15% reduction in fatigue endurance limit was observed after application of the coating to the as-received substrate, but no significant reduction was observed on its application to the grit-blasted substrate. It has been shown that CGDS titanium coatings have a detrimental effect on the fatigue endurance limit of Ti6Al4V. Compressive stresses found within a coating are usually associated with increased fatigue endurance limits; however, those found within CGDS titanium coatings are too low to prevent fatigue crack formation, and these lead to premature fracture. Surface Finish Surface Roughness, Ra, µm Fatigue endurance limit, MPa Modulus, GPa As-received 2.7 633 107 As-received and sprayed 8.6 537 20 Grit-Blasted 3.5 507 107 Grit-blasted and sprayed 8.5 512 19 Table 2 : Effect of surface finish on fatigue endurance limit [56]. E. Sansoucy et al. [57] work on in particular the bending fatigue and the bond strength, of the Al-Co-Ce coatings. The results show that the Al-Co-Ce coatings improved the fatigue behavior of AA 2024-T3 specimens when compared to uncoated and Alclad specimens It is suggested that the increase in the fatigue properties of the specimens can be attributed to the residual compressive stresses induced in the coatings and to the high adhesion strength of the coatings to the substrates. The fatigue results can be rationalized on the basis of two important factors: the existence of residual compressive stresses, and the high adhesion of the coatings to the substrate. The high velocity impacts of particles cause plastic deformation of the underlying layers and generate compressive residual stresses. Qiang Zhang et al. [58] nanostructured NiCrAlY bond coating was deposited after that a shot-peening treatment was applied to the as-sprayed coating to modify the coating surface morphology. It was found that a uniform oxide layer was formed on the surface of the shot-peened nanostructured NiCrAlY coating during oxidation at temperatures of 900 °C and 1000 °C. The surface geometry of the cold-sprayed MCrAlY coating must be modified to promote formation of a protective oxide film during oxidation, through application of a post-treatment process such as shot-peening. The surface of as-sprayed coating was very rough, and some protrudings presented on the surface of bond coating, as shown in Fig. 12. However, after shot-peening treatment, the surface of bond coating was uniform and smooth, and compacted, as shown in Fig. 5b. The surface roughness was significantly reduced from Ra=5.6±1.2 μm(Rz=26.2 ±3.5 μm) at the as- sprayed state to Ra=3.1±0.6 μm (Rz=14.1±1.3 μm) at the shot-peened state. Figure 12: Surface morphology of as-sprayed NiCrAlY bond coating (a) and after shot-peened NiCrAlY bond coating (b)[58]. T