Metallurgical analysis of rotating blades operating in advanced gas turbine engines is important in establishing actual operating conditions, degradation modes, remaining life, and most importantly, the proper repair and rejuvenation techniques to be used in developing optimum component life strategies. The elevated firing temperatures used in the latest engine designs result not only in very high metal surface temperatures but also in very high temperature gradients and concommitant thermal strains induced in part by the complex and efficient cooling systems. This has changed the primary function of today’s superalloy-coating systems from one of hot corrosion protection to moderating high temperature oxidation reactions. Furthermore, as a result of the high thermal strains induced by the cooling systems, long-term metallurgical structural stability issues now revolve around optimizing both thermal mechanical fatigue (TMF) resistance and creep life. Thus the gradual change to directionally solidified (DS) and single crystal (SC) alloys throughout the industry. The use of DS and SC alloys coated with state of the art TBC, platinum modified aluminide and MCrAlY coatings with or without subsequent aluminizing applied by vacuum plasma spray (VPS), high velocity oxygen fuel (HVOF), physical vapor deposition (PVD), air plasma spray (APS), and by chemical vapor deposition (CVD) methods along with the widespread use of internal aluminide coatings have made today’s rotating components prohibitively expensive to replace after only one cycle of operation. It is therefore, or should now be a high priority for all cost conscious gas turbine users to help develop reliable repair and rejuvenation strategies and techniques to minimize their operating cost. Traditional metallurgical considerations required for life assessment and the reliable refurbishment and requalification of gas turbine blades are reviewed along with some new exciting techniques. Examples of component degradation modes are presented. Appropriate attention to metallurgical issues allows turbine users to more successfully and economically operate their turbines.

1.
Daleo, J. A., and Boone, D. H., 1997, “Failure Mechanisms of Coating Systems Applied to Advanced Turbine Components,”ASME Paper 97-GT-486.
2.
Rairden, III, J. R., 1982, U.S. Patent, Re. 30,995, reissued July 13.
3.
Ellison, K. A., Daleo, J. A., and Boone, D. H., 1998, “Metallurgical Temperature Estimates Based on Inter-diffusion Between CoCrAlY Overlay Coatings and a Directionally Solidified Nickel-Base Superalloy Substrate,” Proceedings of the 6th Liege Conference, Vol. 5, Part III, Forschungszentrum Julich GmbH, p. 1523.
4.
Wells, C., 1996, “Eddy Current Measurements of the In-Service Degradation of the GT29PLUS Coating System On GTD111 Turbine Blades,” Final Report of Project GE96-20, Report number SIW-96-025, Structural Integrity Associates.
5.
Daleo, J. A., and Boone, D. H., 1996, “Metallurgical Evaluation Techniques in Gas Turbine Failure Analysis and Life Assessment,” Failures 96, Risk, Economy and Safety, Failure Minimization and Analysis, R. K. Penny, ed., A. A. Balkema, Rotterdam, pp. 187–201.
6.
Tien, J. K., and Caulfield, T., eds., 1989, Superalloys, Supercomposites and Superceramics, Academic Press, San Diego, CA, p. 138.
7.
ASM Metals Reference Book, 2nd Ed., 1983, ASM, Metals Park, OH, p. 415.
8.
Beddoes
,
J. C.
, and
Wallace
,
W.
,
1980
, “
Heat Treatment of Hot Isostatically Processed IN-738 Investment Castings
,”
Metallography
,
13
, pp.
185
194
.
9.
Daleo
,
J. A.
,
Ellison
,
K. A.
, and
Woodford
,
D. A.
,
1999
, “
Application of Stress Relaxation Testing in Metallurgical Life Assessment Evaluations of GTD111 Alloy Turbine Blades
,”
ASME J. Eng. Gas Turbines Power
,
121
, pp.
129
137
.
10.
Soderberg
,
C. R.
,
1936
, “
The Interpretation of Creep Tests for Machine Design
,”
Trans. ASME
,
58
, p.
733
733
.
11.
Oding, I. A., et al., 1959, Creep and Stress Relaxation in Metals, Academy of Sciences of the USSR (English translation by A. J. Kennedy, Oliver and Boyd Ltd.).
12.
Lee
,
D.
, and
Hart
,
E. W.
,
1971
, “
Stress Relaxation and Mechanical Behavior of Metals
,”
Metall. Trans.
,
2
, pp.
1245
1248
.
13.
Woodford, D. R., Van Steele, K., Amberg, K., and Stiles, D., 1992, “Creep Strength Evaluation for IN 738 Based on Stress Relaxation,” Superalloys 1992, S. D. Antolovich et al., eds., The Minerals, Metals and Materials Society, pp. 657–664.
14.
Woodford
,
D. A.
,
1993
, “
Test Methods for Accelerated Development, Design and Life Assessment of High Temperature Materials
,”
Mater. Des.
,
14
, No.
4
, pp.
231
242
.
15.
Woodford, D. A., and Daleo J. A., 1999, “Life Assessment of Hot Section Gas Turbine Components,” Proceedings of a conference held at Heriot Watt University, R. Townsend et al., eds., Edinburgh, UK, Oct. 5–7, IOM Communications, London, pp. 293–310.
16.
Robinson
,
E. L.
,
1952
, “
Effects of Temperature Variations on the Long Time Rupture Strength of Steels
,”
Trans. ASME
,
74
, pp.
777
781
.
17.
Monkman
,
F. C.
, and
Grant
,
N. J.
,
1956
, “
An Empirical Relationship Between Rupture Life and Minimum Creep Rate in Creep Rupture Tests
,”
Proc. ASTM
,
56
, p.
593
593
.
18.
Daleo
,
J. A.
, and
Wilson
,
J. R.
,
1998
, “
GTD111 Alloy Material Study
,”
ASME J. Eng. Gas Turbines Power
,
121
, pp.
375
382
.
19.
Larson
,
F. R.
, and
Miller
,
J.
,
1952
, “
Time-Temperature Relationships for Rupture and Creep Stresses
,”
Trans. ASME
,
74
, p.
765
765
.
20.
Schilke
,
P. W.
,
Foster
,
A. D.
,
Pepe
,
J. J.
, and
Beltran
,
A. M.
,
1992
, “
Advance Materials Propel Progress in Land-Base Gas Turbines
,”
Adv. Mat. Processes
, Apr., pp.
22
30
.
21.
Woodford, D. R., Daleo, J. A., and Wilson, J. R., 1996, “Analysis of Service Run Ruston TB5000 Components,” 96Mpa/W&D01, Materials Performance Analysis, Wilson & Daleo, Inc., internal report.
22.
Daniels, A., Bales, M., Bishop, C., Becker, E., and Van Dijk, M., “Infrared Testing of Turbine Blades and Vanes Using Both Transmission and Reflective Methodologies,” presented at the 1995 ASNT Quality Testing Show, Dallas, TX.
23.
Daniels, A., 1996, “Non-destructive Pulsed Infrared Quantitative Evaluation of Metals,” Thermosense XVIII:An International Conference on Thermal Sensong and Imaging Diagnostic Applications, Apr. SPIE.
24.
Stiglish J. J., Bishhop C. C., Daleo J. A., Boone D. H., and Eelkema T. E., 1999, “The Thermal Inertia Analysis Technique in Gas Turbine Component Reliability Assessment,” Materials Solutions 98, ASM International, pp. 138–144.
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