The use of high performance ceramic thermal barrier coatings in stationary gas turbines requires fundamental knowledge of their fatigue behavior under high temperature gradients and thermal cycling. An experimental method based on rapid laser heating complemented with finite-element calculations was developed in order to identify the major damage mechanisms and to obtain a data set for reliability assessment of thermal barrier coatings for temperature and stress fields similar to gas turbine conditions. The observed failures are strongly related to the pretreatment procedures such as annealing under high temperature gradients and isothermal long-term oxidation. The vertical crack patterns observed closed to the top surface of the Zirconia coating are generated at the moment of rapid cooling. These cracks are induced by high biaxial tensile stresses caused by the temperature gradient and the stress reversion after relaxation of compressive stresses at high temperatures. The long-term fatigue behavior is decisively determined by two processes: (1) the porous Zirconia loses its damage tolerant properties by densification, and (2) the growth of an oxide layer at the bond coat degrades adhesion and produces localized stress fields at the interface. Cyclic loads increase the length of existing in-plane cracks and delaminations rather than enlarging their number. Misfit of the crack flanks and wedge effects are the driving forces for continued crack propagation. These experimental results are discussed in terms of fracture mechanics.

Issue Section:
Gas Turbines: Ceramics
Topics:
Fatigue, Lasers, Thermal barrier coatings, Fracture (Materials), Stress, High temperature, Damage, Gas turbines, Adhesion, Annealing, Ceramics, Coatings, Compressive stress, Cooling, Crack propagation, Delamination, Failure, Finite element analysis, Fracture mechanics, Heating, Oxidation, Relaxation (Physics), Reliability, Temperature, Temperature gradient, Tension, Wedges
1.
Chang
G. C.
,
Phucharoen
W.
,
Miller
R. A.
,
1987
, “
Behavior of Thermal Barrier Coating for Advanced Gas Turbine Blades
,”
Surface and Coatings Technologies
, Vol.
30
, pp.
13
28
.
2.
Kokini
K.
,
Takeuchi
Y.
,
1994
, “
Initiation of Surface Cracks in Multilayer Ceramic Thermal Barrier Coatings Under Thermal Loads
,”
Material Science and Engineering A
, Vol.
189
, pp.
301
309
.
3.
Evans, A. G., Wang, J. S., Mum, D., 1997, “Mechanism-Based Life Prediction Issues for Thermal Barrier Coating,” paper presented at the TBC-Workshop, Cincinnati, OH, May 19-21, 1997.
4.
Loh
R. L.
,
Rossington
C.
,
Evans
A. G.
,
1986
, “
Laser Technique for Evaluating Spall Resistance of Brittle Coatings
,”
J. Am. Ceram. Soc.
, Vol.
69
, pp.
139
142
.
5.
Hashida, T., Takahashi, H., 1990, “Laser Irradiation Thermal Shock and Thermal Fatigue Test Procedure,” Proceedings, Int. Symposium, FGM, Sendai, pp. 365–373.
6.
Kirchhoff, G., Holzherr, M., Bast, U., Rettig, U., 1993, “Thermal Shock and Thermal Cycling Behavior of Silicon Nitride Ceramics,” Proceedings, Int. Conf. On Silicon Nitride-Based Ceramics, Trans Tech Public. Ltd., Switzerland, pp. 605–609.
7.
Pompe, W., Bahr, H.-A., Pflugbeil, I., Kirchhoff, G., Langmeier, P., Weiss, H.-J., 1997, “Laser Induced Creep and Fracture in Ceramics,” Materials Science and Engineering, A233 (1-2), Elsevier Science, The Netherlands, pp. 167–175.
8.
Zhu
D.
,
Miller
R. A.
,
1997
, “
Investigation of Thermal Fatigue Behavior of Thermal Barrier Coating Systems
,”
Surface and Coatings Technology
, Vol.
94–95
, pp.
94
101
.
9.
Thurn, G., 1997, “Hochtemperatureigenschaften und Scha¨digungsverhalten plasmagespritzter ZrO2-Wa¨rmebarrieren,” thesis, Universita¨t Stuttgart, Germany.
10.
Thurn
G.
,
Aldinger
F.
,
Schneider
G. A.
,
1997
, “
High-Temperature deformation of Plasma-Sprayed ZrO2 Thermal Barrier Coatings
,”
Materials Science and Engineering A
, Vol.
233
, pp.
176
182
.
This content is only available via PDF.
Copyright © 1999
 by The American Society of Mechanical Engineers
You do not currently have access to this content.