Litcius/Paper detail

Optimizing the Voce–Chaboche Model Parameters for Fatigue Life Estimation of Welded Joints in High-Strength Marine Structures

Alice Petry, Pasquale Gallo, Heikki Remes, Ari Niemelä

2022Journal of Marine Science and Engineering18 citationsDOIOpen Access PDF

Abstract

This work studies the Voce–Chaboche (V–C) material model parameter optimization for high-strength steel welded joints subjected to cyclic loading. The model parameters of each material zone in a S690 steel butt-welded joint were determined using an optimization algorithm based on the Newton trust region (NTR) method and an accumulated true strain parameter. The model parameters were fitted to stress–strain histories from uniaxial strain-controlled cyclic tests. To validate the model, fully-reversed variable amplitude fatigue experiments were performed under load control. The experimental results were then compared to numerical results from a finite element analysis. When the elastic modulus is optimized as a V–C parameter, the results indicate that the V–C model slightly underestimates the strain range, leading to conservative fatigue life estimates. However, the results can be improved by using an elastic modulus obtained experimentally. In this case, the resulting material model slightly overestimates the strain range, leading to a non-conservative, but more accurate, fatigue life estimation. It can be concluded that the NTR-based accumulated true strain approach successfully determined the V–C model parameters for different material zones in the welded joint, and closely estimated the strain range and the fatigue life for a variable amplitude load history.

Topics & Concepts

WeldingMaterials scienceStructural engineeringJoint (building)AmplitudeFinite element methodStrain (injury)ModulusRange (aeronautics)Stress–strain curveStress (linguistics)Deformation (meteorology)Composite materialEngineeringPhysicsLinguisticsMedicineQuantum mechanicsPhilosophyInternal medicineFatigue and fracture mechanicsStructural Load-Bearing AnalysisStructural Integrity and Reliability Analysis