Fatigue life of welded joints according to energy criteria in the critical plane

Many engineering structures experience multiaxial fatigue states of stress-strain in the vicinity of welded joints. Fatigue assessment of welded joints under proportional (in-phase) cyclic loading can be performed by using conventional hypotheses (e.g., see the von Mises criterion or the Tresca crit

Steel structures such as ships, ocean structures, automobile, aircraft and bridges should be designed and manufactured to be able to endure under various environmental conditions such as static load, impact, fatigue and torsion etc. Especially, many researches about improvement of fatigue strength h

The fatigue life of MIG welded cruciform joint failing from root (LOP) region was successfully predicted using new fracture mechanics equations. These equations were developed by combining Paris' law and AK~-endurance equation and incorporating an integral factor (Ip), obtained by integrating Paris'

## Abstract In this paper generalized criteria of multiaxial random fatigue based on stress, strain and strain energy density parameters in the critical plane have been discussed. The proposed criteria reduce multiaxial state of stress to the equivalent uniaxial tension–compression or alternating b

This paper compares the calculated fatigue life with the tested life, for an embedded crack in the friction weld between two axially loaded rods. The initial crack is caused by lack of fusion in the centre of the friction weld. The radius for the initial circular crack is 5±6 mm. The stress intensit