This article deals with the problem of multiaxial fatigue life assessment of engineering components. General aspects of the critical plane damage models are discussed first. A computer-based procedure for multiaxial fatigue life assessment incorporating critical plane damage models, suitable for use in design evaluations of engineering components based on finite element analysis results, is presented and applied to correlate results from tests conducted on SAE 1045 steel notched shaft specimens. From experimental data correlations, it is found that the second variant of the critical plane models (in which critical planes are defined as the planes experiencing the maximum damage) provides better life estimates than the first variant (in which critical planes are defined as the planes experiencing the maximum range of strain) or the conventional local strain based life prediction method, even for simple and short loading histories made up of repeating cycles.
[1]
R. W. Landgraf,et al.
Advances in Fatigue Lifetime Predictive Techniques
,
1992
.
[2]
A. Fatemi,et al.
A CRITICAL PLANE APPROACH TO MULTIAXIAL FATIGUE DAMAGE INCLUDING OUT‐OF‐PHASE LOADING
,
1988
.
[3]
D. Socie.
Critical Plane Approaches for Multiaxial Fatigue Damage Assessment
,
1993
.
[4]
Soon-Bok Lee,et al.
A critical review on multiaxial fatigue assessments of metals
,
1996
.
[5]
Ja Bannantine,et al.
A Multiaxial Fatigue Life Estimation Technique
,
1992
.
[6]
K. N. Smith.
A Stress-Strain Function for the Fatigue of Metals
,
1970
.