Abstract Existing theories for the growth of cracks at weld toes have proved difficult to verify because of a lack of experimental proof at short crack depths and slow growth rates. Arbitrary initial defect sizes have been employed in life calculations coupled with approximate two-dimensional stress analyses. In this study, the fatigue performance of a stress relieved fillet weld is determined by both theory and experiment. Crack growth results for shallow (less than 1 mm depth) elliptical cracks at weld toes are used to test an elastic expression for stress intensity using a correction factor from a three-dimensional stress analysis. No evidence of higher than expected growth rates, observed by others for very short cracks and cracks in notch plastic zones, is apparent. Integration of a growth law that includes the threshold stress intensity factor provides fatigue life predictions for various stress ratios and from experimentally measured defect depths. Needle peening the weld toe improves the fatigue life by retarding crack growth up to 1 mm below the weld toe.
[1]
P. C. Paris,et al.
A Critical Analysis of Crack Propagation Laws
,
1963
.
[2]
Ian F. C. Smith,et al.
Fatigue Life Prediction of Welded Components Based on Fracture Mechanics
,
1980
.
[3]
A. Hartman,et al.
The effects of environment and load frequency on the crack propagation law for macro fatigue crack growth in aluminium alloys
,
1970
.
[4]
S. J. Maddox,et al.
An analysis of fatigue cracks in fillet welded joints
,
1975
.
[5]
F. V. Lawrence,et al.
Estimating the fatigue crack initiation life of welds
,
1978
.
[6]
K. J. Miller,et al.
Fatigue cracks at notches
,
1977
.
[7]
W. Brown,et al.
Plane strain crack toughness testing of high strength metallic materials.
,
1966
.
[8]
Timothy Russell Gurney,et al.
Fatigue of Welded Structures
,
1980
.
[9]
Ian F. C. Smith,et al.
Defects and crack shape development in fillet welded joints
,
1982
.
[10]
Ian F. C. Smith,et al.
Measuring fatigue cracks in fillet welded joints
,
1982
.