Modern gas turbine combustors are made of high temperature alloys, employ effusion cooling, and are protected by a thermal barrier coating (TBC). Gas turbine combustor failure modes, such as TBC spallation, cracking, and distortion resulting from oxidation, creep, and thermal fatigue, are driven by hot spot peak temperature and the associated thermal gradient. Standard material characterization tests, such as creep, oxidation, and low cycle fatigue are indicators of a material’s potential performance but they neither fully represent the combustor geometric/material system nor fully represent the thermal fatigue conditions a combustor is subjected to during engine operation. Combustor rig tests and/or engine cyclic endurance tests to determine the suitability of new material systems for combustors are time-consuming and costly. Therefore, a simple yet efficient test method for screening material systems under representative combustor conditions is needed. An experimental system has been developed to fill this gap. This paper discusses the configured specimen geometry, test methodology, observed test results, and a comparison with typical failure modes observed in combustors.

Issue Section:
Gas Turbines: Manufacturing, Materials, and Metallurgy
Keywords:
cobalt alloys, combustion equipment, creep, durability, failure analysis, gas turbines, nickel alloys, thermal barrier coatings, thermal stress cracking
Topics:
Combustion chambers, Durability, Temperature, Cycles, Cooling, Temperature gradient, Creep, Oxidation, Engines, Gas turbines, Thermal barrier coatings
1.
ASTM International
, 2004, “
Standard Practice for Strain Controlled Thermo-Mechanical Fatigue Testing E 2368-04
,” ASTM Standards, West Conshohecken.
2.
Halford
,
G. R.
,
McGaw
,
M. A.
,
Bill
,
R. C.
, and
Fanti
,
P. D.
, 1988, “
Bithermal Fatigue: A Link Between Isothermal and Thermaomechanical Fatigue
,”
ASTM Spec. Tech. Publ.
0066-0558
942
,
625
637
.
3.
Chen
,
W. R.
,
Archer
,
R.
,
Huang
,
X.
, and
Marple
,
B. R.
, 2008, “
TGO Growth and Crack Propagation in a Thermal Barrier Coating
,”
J. Therm. Spray Technol.
1059-9630,
17
(
5–6
), pp.
858
864
.
4.
Wu
,
F.
,
Jordan
,
E. H.
,
Ma
,
X.
, and
Gell
,
M.
, 2008, “
Thermally Grown Oxide Growth Behavior and Spallation Lives of Solution Precursor Plasma Spray Thermal Barrier Coatings
,”
Surf. Coat. Technol.
0257-8972,
202
(
9
), pp.
1628
1635
.
Crossref
Search ADS
 
5.
Bolcavage
,
A.
,
Feuerstein
,
A.
,
Foster
,
J.
, and
Moore
,
P.
, 2004, “
Thermal Shock Testing of Thermal Barrier Coating/Bondcoat Systems
,”
J. Mater. Eng. Perform.
1059-9495,
13
, pp.
389
397
.
Crossref
Search ADS
 
6.
Chen
,
W. R.
,
Wu
,
X.
,
Marple
,
B. R.
, and
Patnaik
,
P. C.
, 2005, “
Oxidation and Crack Nucleation/Growth in an Air-Plasma-Sprayed Thermal Barrier Coating With NiCrAlY Bond Coat
,”
Surf. Coat. Technol.
0257-8972,
197
(
1
), pp.
109
115
.
Crossref
Search ADS
 
7.
Zhu
,
D.
,
Nesbitt
,
J. A.
,
Barrett
,
C. A.
,
McCue
,
T. R.
, and
Miller
,
R. A.
, 2004, “
Furnace Cyclic Oxidation Behavior of Multicomponent Low Conductivity Thermal Barrier Coatings
,”
J. Therm. Spray Technol.
1059-9630,
13
(
1
), pp.
84
92
.
Crossref
Search ADS
 
8.
Nesbitt
,
J. A.
, 1998, “
Hot Corrosion of Single-Crystal NiA-X Alloys
,” NASA TM 113128.
9.
Greving
,
D.
,
Hann
,
B.
,
McIver
,
J.
, and
Rudrapatna
,
N. S.
, 2009, “
Curved Test Specimen
,” Patent Pending, Feb. 17.
Copyright © 2011
 by American Society of Mechanical Engineers
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