The failure mechanisms of thermal barrier coating (TBC) systems applied on
gas turbine blades and vanes are investigated using thermomechanical fatigu
e (TMF) tests and finite element (FE) modeling. TMF tests were performed at
two levels of applied mechanical strain, namely five times and three times
the critical in-service mechanical strain of an industrial gas turbine. TM
F testing under the higher mechanical strain of air plasma-sprayed (APS) an
d electron beam-physical vapor deposition (EB-PVD) coated samples showed th
at both systems failed after a similar number of cycles by cracks that init
iated at the bond coat/thermally grown oxide (TGO) interface and propagated
through the bond coat to the substrate. When the applied mechanical strain
was decreased, cracking of the bond coat in EB-PVD coated systems was supp
ressed, the life of the coated system increased significantly and delaminat
ion of the top-coat was observed. A subsequent FE analysis showed that, by
subjecting the system to the higher mechanical strain, significant tensile
stresses develop in the TGO and the bond coat that are thought to be respon
sible for the observed crack initiation and propagation. The FE model also
predicts that cracking initiates at specific geometric features of the roug
h interface of a PS coated system, which was confirmed by metallographic ex
amination of failed samples. The decrease of the applied mechanical strain
and hence of the developed stresses led to the suppression of failure by bo
nd coat cracking and activate delamination. These results outline the impor
tance of designing TMF tests and selecting the appropriate mechanical loadi
ng in order to accelerate testing and still trigger the same failure mechan
isms as observed in-service. (C) 2000 Acta Metallurgica Inc. Published by E
lsevier Science Ltd. AII rights reserved.