Damage analysis of low-cycle fatigue under non-proportional loading

This paper proposes a new model for low cycle fatigue of metal alloys based on material sensibility to non-proportionality of loading. The model was examined by application to the prediction of the fatigue life in proportional and non-proportional low cycle fatigue tests for type BT1-0 titanium allo

A numerical model for low cycle fatigue damage analysis of valve membranes is presented in this paper. The isotropic and non-linear kinematic hardening laws of Lemaı ˆtre-Chaboche, which define both the cyclic hardening and the ratchetting phenomenon, are adopted. The model for prediction of the num

In this paper, a series of low cycle fatigue tests under multiaxial non-proportional loading at constant room temperature is carried out. It is observed that 63Sn37Pb solder exhibits non-additional cyclic hardening effect under non-proportional loading compared with proportional loading. A damage co

We know from experimental phenomena that the ductility of materials decreases with increasing numbers of cycles in the process of cycle fatigue loading, from which a new fatigue damage variable D \* based on the material ductility property is defined. Then a continuum damage mechanics model for low-

The work here presented intends to study the influence of the shape of loading on the fatigue life in case of multiaxial loading. The practical undergoing problem is the fatigue life of high speed railways wheels. They are here considered as loaded in tension (or compression) and in torsion. Severa

Combined tension-torsion fatigue tests were conducted on nickel-based alloy GH4169 under proportional and nonproportional loading at 650 °C. The fatigue cracks on the specimen surface were found basically initiating and propagating along the maximum shear plane. Taking into account the materials in