Biaxial fatigue for proportional and non-proportional loading paths

In order to study the use of a local approach to predict crack-initiation life on notches in mechanical components under multiaxial fatigue conditions, the study of the local cyclic elasto-plastic behaviour and the selection of an appropriate multiaxial fatigue model are essential steps in fatigue-life prediction. The evolution of stress-strain fields from the initial state to the stabilized state depends on the material type, loading amplitude and loading paths. A series of biaxial tension-compression tests with static or cyclic torsion were carried out on a biaxial servo-hydraulic testing machine. Specimens were made of an alloy steel 42CrMo4 quenched and tempered. The shear stress relaxations of the cyclic tension-compression with a steady torsion angle were observed for various loading levels. Finite element analyses were used to simulate the cyclic behaviour and good agreement was found. Based on the local stabilized cyclic elastic-plastic stress-strain responses, the strain-based multiaxial fatigue damage parameters were applied and correlated with the experimentally obtained lives. As a comparison, a stress-invariant-based approach with the minimum circumscribed ellipse (MCE) approach for evaluating the effective shear stress amplitude was also applied for fatigue life prediction. The comparison showed that both the equivalent strain range and the stress-invariant parameter with non-proportional factors correlated well with the experimental results obtained in this study.