Department of Materials Science and Mineral Engineering
University of California at Berkeley
 

J. O. Peters,¹ O. Roder,^1,2 B. L. Boyce,¹ A. W. Thompson,¹ and
R. O. Ritchie¹

¹Department of Materials Science and Mineral Engineering, University of California, Berkeley, CA 94720-1760, U.S.A.
²currently at Daimler Chrysler Aerospace - MTU Munich, 80976 Munich, Germany
 

July 1999

submitted to
Metallurgical and Materials Transactions A
 

Work supported by the Air Force Office of Scientific Research, Grant No. F49620-96-1-0478 under the auspices of the Multidisciplinary University Research Initiative on High Cycle Fatigue to the University of California.

The increasing incidence of military aircraft engine failures that can be traced to high-cycle fatigue (HCF) has prompted a reassessment of the design methodologies for HCF-critical components, such as turbine blades and disks. Because of the high-frequency vibratory loading involved, damage-tolerant design methodologies based on a threshold for no crack growth offer a preferred approach. As impact damage from ingested debris is a prime source of HCF-related failures, the current study is focused on the role of such foreign object damage (FOD) in influencing fatigue-crack growth thresholds and early crack growth of both large and small cracks in a fan blade alloy, Ti-6Al-4V. FOD, which was simulated by the high-velocity (200-300 m/s) impacts of steel spheres on a flat surface, was found to reduce markedly the fatigue strength, primarily due to earlier crack initiation. This is discussed in terms of four salient factors: (i) the stress concentration associated with the FOD indentation, (ii) the presence of small microcracks in the damaged zone, (iii) the localized presence of tensile residual hoop stresses at the base and rim of the indent sites, and (iv) microstructural damage from FOD-induced plastic deformation. It was found that no crack growth occurred from FOD impact sites in this alloy at DK values below ~2.9 MPaÖ m, i.e., over 50% higher than the "closure-free", worse-case threshold value of DK_TH = 1.9 MPaÖ m, defined for large cracks in bimodal Ti-6Al-4V at the highest possible load ratio. It is therefore concluded that such worst-case, large-crack thresholds can thus be used as a practical lower-bound to FOD-initiated cracking in this alloy.