High cycle fatigue (HCF) induced failures in aircraft gas turbine and rocket engine turbopump blades is a pervasive problem. Single crystal nickel turbine blades are being utilized in rocket engine turbopumps and jet engines throughout industry because of their superior creep, stress rupture, melt resistance, and thermomechanical fatigue capabilities over polycrystalline alloys. Currently the most widely used single crystal turbine blade superalloys are PWA 1480/1493, PWA 1484, RENE’ N-5 and CMSX-4. These alloys play an important role in commercial, military and space propulsion systems. Single crystal materials have highly orthotropic properties making the position of the crystal lattice relative to the part geometry a significant factor in the overall analysis. The failure modes of single crystal turbine blades are complicated to predict due to the material orthotropy and variations in crystal orientations. Fatigue life estimation of single crystal turbine blades represents an important aspect of durability assessment. It is therefore of practical interest to develop effective fatigue failure criteria for single crystal nickel alloys and to investigate the effects of variation of primary and secondary crystal orientation on fatigue life. A fatigue failure criterion based on the maximum shear stress amplitude [Δτmax] on the 24 octahedral and 6 cube slip systems, is presented for single crystal nickel superalloys (FCC crystal). This criterion reduces the scatter in uniaxial LCF test data considerably for PWA 1493 at 1200°F in air. Additionally, single crystal turbine blades used in the alternate advanced high-pressure fuel turbopump (AHPFTP/AT) are modeled using a large-scale three-dimensional finite element model. This finite element model is capable of accounting for material orthotrophy and variation in primary and secondary crystal orientation. Effects of variation in crystal orientation on blade stress response are studied based on 297 finite element model runs. Fatigue lives at critical points in the blade are computed using finite element stress results and the failure criterion developed. Stress analysis results in the blade attachment region are also presented. Results presented demonstrates that control of secondary and primary crystallographic orientation has the potential to significantly increase a component’s resistance to fatigue crack growth without adding additional weight or cost.

1.
Cowles
,
B. A.
,
1996
, “
High Cycle Fatigue Failure in Aircraft Gas Turbines: An Industry Perspective
,”
Int. J. Fract.
,
80
, pp.
147
163
.
2.
Moroso, J., 1999, “Effect of Secondary Crystal Orientation on Fatigue Crack Growth in Single Crystal Nickel Turbine Blade Superalloys,” M. S. thesis, Mechanical Engineering Department, University of Florida, Gainesville, FL, May.
3.
Deluca, D., and Annis, C., 1995, “Fatigue in Single Crystal Nickel Superalloys,” Office of Naval Research, Department of the Navy FR23800, Aug.
4.
Stouffer, D. C., and Dame, L. T., 1996, Inelastic Deformation of Metals, John Wiley and Sons, New York.
5.
Milligan, W. W., and Antolovich, S. D., 1985, “Deformation Modeling and Constitutive Modeling for Anisotropic Superalloys,” NASA Contractor Report 4215, Feb.
6.
Telesman
,
J.
, and
Ghosn
,
L.
,
1989
, “
The Unusual Near Threshold FCG Behavior of a Single Crystal Superalloy and the Resolved Shear Stress as the Crack Driving Force
,”
Eng. Fract. Mech.
,
34
, No.
5–6
, pp.
1183
1196
.
7.
Deluca, D. P., and Cowles, B. A., 1989, “Fatigue and Fracture of Single Crystal Nickel in High Pressure Hydrogen,” Hydrogen Effects on Material Behavior, By N. R. Moody and A. W. Thomson, eds., TMS., Warrendale, PA.
8.
Kandil, F. A., Brown, M. W., and Miller, K. J., 1982, Biaxial Low Cycle Fatigue of 316 Stainless Steel at Elevated Temperatures, Metals Soc., London. pp. 203–210.
9.
Socie, D. F., Kurath, P., and Koch, J., 1985, “A Multiaxial Fatigue Damage Parameter,” presented at the Second International Symposium on Multiaxial Fatigue, Sheffield, U.K.
10.
Fatemi
,
A.
, and
Socie
,
D.
,
1998
, “
A Critical Plane Approach to Multiaxial Fatigue Damage Including Out-of-Phase Loading
,”
Fatigue Fracture in Engineering Materials
,
11
, No.
3
, pp.
149
165
.
11.
Smith
,
K. N.
,
Watson
,
P.
, and
Topper
,
T. M.
,
1970
, “
A Stress-Strain Function for the Fatigue of Metals
,”
J. Mater.
,
5
,
767
778
.
12.
Banantine, J. A., and Socie, D. F., 1985, “Observations of Cracking Behavior in Tension and Torsion Low Cycle Fatigue,” presented at ASTM Symposium on Low Cycle Fatigue—Directions for the Future, Philadelphia, PA.
13.
Lekhnitskii, S. G., 1963, “Theory of Elasticity of an Anisotropic Elastic Body,” Holden-Day, San Francisco, pp. 1–40.
14.
Pratt and Whitney, 1996, “SSME Alternate Turbopump Development Program HPFTP Critical Design Review.” P&W FR24581-1 Dec. 23, NASA Contract NAS8-36801.
15.
Sayyah, T., 1999, “Alternate Turbopump Development Single Crystal Failure Criterion for High Pressure Fuel Turbopump First Stage Blades,” Report No.: 621-025-99-001, NASA Contract NAS 8-40836, May 27.
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