In this paper, the effect of a combined bending/tension loading on the fatigue resistance and on the fatigue crack growth characteristics of a nickel-based alloy at room temperature is studied. For this purpose, a device was specifically designed so that it can be mounted onto a servohydraulic push-pull testing machine. With the device, a simultaneous displacement and rotation of the specimen extremities generate a combined bending/axial stress; the ratio between the bending stress and the axial stress may be specified by adjusting the eccentricity between the specimen axis and the load axis. Stress-controlled fatigue tests were carried out on plate specimens under bending/tension loading with a surface stress ratio of −0.52 (ratio between the maximum cyclic stress on the back face and that on the front face of the specimen). During each test, the fatigue crack length was monitored using two traveling video-cameras. The experimental results obtained under bending/tension loading have been analyzed in connection with the data obtained under pure tension loading. In particular, the fatigue crack propagation rate expressed in terms of the stress intensity factor of a crack under combined loading was examined.

Issue Section:
Research Papers
Topics:
Alloys, Low cycle fatigue, Nickel, Tension, Stress, Fatigue cracks, Bending (Stress), Displacement, Fatigue, Fatigue testing, Fracture (Materials), Machinery, Rotation, Temperature, Testing, Video cameras
1.
Bui-Quoc, T., Bernard, M., and Julien, D., 1995, “Axial/Bending Effect on Low Cycle Fatigue Behaviour of Waspaloy at High Temperature,” E´cole Polytechnique, preliminary report CDT P1904, submitted to Pratt & Whitney Canada.
2.
Fuchs, H. O., and Stephens, R. I., 1980, Metal Fatigue in Engineering, Wiley-Interscience Publication, pp. 94–98.
3.
Hongoh, M., 1996, Pratt & Whitney Canada, private communications.
4.
Julien, D., Bui-Quoc, T., and Bernard, M., 1996, “An Effective Fixture for Studying Low-Cycle Fatigue under Axial/Bending Loading,” E´cole Polytechnique, Technical Report GACM-FR96, submitted to Pratt & Whitney Canada.
5.
Kawahara, M., and Kurihara, M., 1977, “Fatigue Crack Growth from a Surface Flaw,” Proceedings, 4th International Conference Fracture ed., D. Taplin, Vol. 2, pp. 1361–1373.
6.
Mahmoud
M. A.
,
1990
, “
Surface Fatigue Crack Growth under Combined Tension and Bending Loading
,”
Engineering Fracture Mechanics
, Vol.
36
, No.
3
, pp.
389
395
.
7.
Lin
X. B.
, and
Smith
R. A.
,
1995
, “
Numerical Prediction of Fatigue Crack Growth of a Surface Defect
,”
Fatigue Fracture Engineering Materials and Structures
, Vol.
18
, No.
2
, pp.
247
256
.
8.
Nam
K. W.
,
Ando
K.
,
Ogura
N.
, and
Matui
K.
,
1994
, “
Fatigue Life and Penetration Behaviour of a Surface-Cracked Plate under Combined Tension and Bending
,”
Fatigue Fracture Engineering Materials and Structures
, Vol.
17
, No.
8
, pp.
873
882
.
9.
Nam
K. W.
,
Fujibayashi
S.
,
Ando
K.
, and
Ogura
N.
,
1988
, “
The Fatigue Life and Fatigue Crack Through-Thickness Behavior of a Surface-Cracked Plate (Effect of Stress Concentration)
,”
JSME International Journal
, Vol.
31
, pp.
272
279
.
10.
Newman, J. C., and Raju, I. S., 1984, “Stress-Intensity Factor Equations for Cracks in Three-Dimensional Finite Bodies Subjected to Tension and Bending Loads,” NASA Technical Memorandum 85793, NASA Langley Research Center.
11.
Tada, H., Paris, P. C., and Irwin, G. R., 1985, The Stress Analysis of Cracks Handbook, Paris Productions Incorporated (and Del Research Corporation).
12.
Tanaka
K.
,
Hoshide
T.
, and
Maekawa
O.
,
1982
, “
Surface-Crack Propagation in Plane-Bending Fatigue of Smooth Specimen of Low-Carbon Steel
,”
Engineering Fracture Mechanics
, Vol.
16
, No.
2
, pp.
207
220
.
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