High-temperature thermal fatigue causes the failure of thermal barrier coating (TBC) systems. This paper addresses the development of thick TBCs, focusing on the microstructure and the porosity of the yttria partially stabilized zirconia (YPSZ) coating, regarding its resistance to thermal fatigue. Thick TBCs, with different porosity levels, were produced by means of a CoNiCr A1Y bond coat and YPSZ top coat, both had been sprayed by air plasma spray. The thermal fatigue resistance of new TBC systems and the evolution of the coatings before and after thermal cycling was then evaluated. The limit of thermal fatigue resistance increases depending on the amount of porosity in the top coat. Raman analysis shows that the compressive in-plane stress increases in the TBC systems after thermal cycling, nevertheless the increasing rate has a trend which is contrary to the porosity level of top coat.
Thermal Fatigue Behaviour of Thick and Porous Thermal Barrier Coatings Systems / A. Scrivani; G. Rizzi; U. Bardi; C. Giolli; M. Muniz-Miranda; S. Ciattini; A. Fossati; F. Borgioli. - ELETTRONICO. - (2007), pp. 440-445. (Intervento presentato al convegno ITSC 2007 tenutosi a Beijing nel 14-16 Maggio 2007).
Thermal Fatigue Behaviour of Thick and Porous Thermal Barrier Coatings Systems
BARDI, UGO;MUNIZ-MIRANDA, MAURIZIO;CIATTINI, SAMUELE;BORGIOLI, FRANCESCA
2007
Abstract
High-temperature thermal fatigue causes the failure of thermal barrier coating (TBC) systems. This paper addresses the development of thick TBCs, focusing on the microstructure and the porosity of the yttria partially stabilized zirconia (YPSZ) coating, regarding its resistance to thermal fatigue. Thick TBCs, with different porosity levels, were produced by means of a CoNiCr A1Y bond coat and YPSZ top coat, both had been sprayed by air plasma spray. The thermal fatigue resistance of new TBC systems and the evolution of the coatings before and after thermal cycling was then evaluated. The limit of thermal fatigue resistance increases depending on the amount of porosity in the top coat. Raman analysis shows that the compressive in-plane stress increases in the TBC systems after thermal cycling, nevertheless the increasing rate has a trend which is contrary to the porosity level of top coat.
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