A New Critical Plane Multiaxial Fatigue Criterion with an Exponent to Account for High Mean Stress Effect

The mean stress effect remains a critical aspect in multiaxial fatigue analysis. This work presents a new criterion that, based on the classical Findley criterion, applies a material-dependent exponent to the mean normal stress term and includes the ultimate tensile stress as a fitting parameter. Th...

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Bibliographic Details
Published in:Metals (Basel ) 2024-09, Vol.14 (9), p.964
Main Authors: Abasolo, Mikel, Pallares-Santasmartas, Luis, Eizmendi, Martin
Format: Article
Language:English
Subjects:
Aluminum
Criteria
critical plane criterion
Fatigue
fatigue failure prediction
Fatigue tests
Load
mean stress effect
Metals
multiaxial fatigue
Normal stress
Shear stress
Strains and stresses
Stress relaxation (Materials)
Stress relieving (Materials)
structural components
Tensile stress
Testing
Titanium alloys
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Summary:The mean stress effect remains a critical aspect in multiaxial fatigue analysis. This work presents a new criterion that, based on the classical Findley criterion, applies a material-dependent exponent to the mean normal stress term and includes the ultimate tensile stress as a fitting parameter. This way of considering the non-linear effect of the mean stress, with a material-dependent rather than a fixed exponent, is totally innovative among the multiaxial fatigue criteria found in the literature. In order to verify its accuracy, the new criterion has been checked against an extended version of the Papuga database of multiaxial experimental tests with 485 results, and compared with the criteria by Findley, Robert, and Papuga. The new criterion provides outstanding results for pure uniaxial cases, with multiaxial performance similar to the Robert criterion with a smaller range of error and a conservative trend, even surpassing the popular Papuga method in several relevant loading scenarios. These features enhance the applicability and versatility of the criterion for its use in the fatigue design of structural components.
ISSN:2075-4701
2075-4701
DOI:10.3390/met14090964