Numerical and Experimental Analysis of Residual Stress Induced by Elastic-Plastic Bending, Tension or Torsion Loading

A. Lahlal; Jean Michel Sprauel; H. Michaud

doi:10.4028/www.scientific.net/MSF.524-525.331

Paper Titles

The Influence of Aluminium Alloy Quench Sensitivity on the Magnitude of Heat Treatment Induced Residual Stress
p.305

Effect of Residual Stress on High Temperature Deformation in a Weld Stainless Steel
p.311

Influence of Heat Treatment and Grinding Conditions on Surface Residual Stresses in the Production of Rollers
p.317

Residual Stress Prediction and Relaxation in Welded Tubular Joints under Constant Cyclic Loading
p.323

Numerical and Experimental Analysis of Residual Stress Induced by Elastic-Plastic Bending, Tension or Torsion Loading
p.331

Analysis of the Impact of a Shot at Low Velocity Using the Finite Element Method. Application to the Ultrasonic Shot-Peening Process
p.337

Residual Stress Analysis in Shot Peened and Fretting Fatigued Samples by the Eigenstrain Method
p.343

Finite Element Simulation of the Residual Stress States after Shot Peening
p.349

Residual Stresses due to High Temperature Annealing. Mathematical Model and Calculations
p.355

HomeMaterials Science ForumMaterials Science Forum Vols. 524-525Numerical and Experimental Analysis of Residual...

Numerical and Experimental Analysis of Residual Stress Induced by Elastic-Plastic Bending, Tension or Torsion Loading

Abstract:

In this work a complete analytical model of elastic-plastic bending, tension and / or torsion has been developed to simulate the manufacturing of leaf springs and coil suspensions. A special procedure was also implemented to simulate mechanical surface treatments such as shot peening. These models allow predicting the plastic strains and residual stresses induced by successive loadings of the part. Our approach required first defining the mechanical behaviour of the material. The constitutive laws of the employed steels were therefore identified starting from cyclic loops recorded for tests carried out at various imposed strains. These laws were introduced in the plasticity model to simulate the different steps of manufacturing: forming of the part, presetting operations, shot peening, elastic-plastic shake down produced by the first cycles of fatigue. In order to validate the model, residual stress maps were also characterized by X-Ray diffraction. However, to retrieve the maximum of information from this kind of measurement, the experimental data has been analysed through a global method which processes the whole acquired diffraction peaks at once.