Modelling the Combined Effect of Room Temperature Storage and Cold Deformation on the Age-Hardening Behaviour of Al-Mg-Si Alloys-Part 2

Carmen Schäfer; Ole Runar Myhr; Henk Jan Brinkman; Olaf Engler; Jürgen Hirsch

doi:10.4028/www.scientific.net/MSF.794-796.722

Paper Titles

The Effect of Hot Deformation on Dispersoid Evolution in a Model 3xxx Alloy
p.697

Study of Aging Precipitation of Al-Zn-Mg Alloys with Er Additions by Monte Carlo Simulation
p.704

Constitutive Analyses of Tensile Tests on Pre-Rolled AA3003 Sheets
p.710

An Advanced Dynamic Repair of Edge Crack Aluminum Plate with a Composite Patch
p.716

Modelling the Combined Effect of Room Temperature Storage and Cold Deformation on the Age-Hardening Behaviour of Al-Mg-Si Alloys-Part 2
p.722

Modeling of Static and Geometric Dynamic Recrystallization during Hot Extrusion of Al-Mg-Si Alloy
p.728

Analysis of the Rate of Recovery and Recrystallization in Pure Aluminum by a New Rate Equation
p.734

Phase Field Modeling of Solute Trapping in a Al-Sn Alloy during Rapid Solidification
p.740

Grain Refinement Mechanism of Al-5Ti-1B Master Alloy by Ab Initio Calculations
p.746

HomeMaterials Science ForumMaterials Science Forum Vols. 794-796Modelling the Combined Effect of Room Temperature...

Modelling the Combined Effect of Room Temperature Storage and Cold Deformation on the Age-Hardening Behaviour of Al-Mg-Si Alloys-Part 2

Abstract:

The present investigation deals with modelling of the age-hardening behaviour of 6xxx series automotive sheet alloys. The basis for this work is the established precipitation model NaMo developed for coupled nucleation, growth, dissolution and coarsening in Al-Mg-Si extrusion alloys. It has recently been extended for applicability for Al-Mg-Si automotive sheet alloys by incorporating the important effects of room temperature (RT) storage and deformation prior to the final artificial ageing of Al-Mg-Si sheet alloys. The 6xxx automotive sheet alloys change due to natural ageing during the time elapsing between their processing and their paint baking in the customers process. This RT storage time has an impact on the artificial ageing response during the OEMs paint baking cycle. A second effect originates from the deformation introduced in the material during the part forming process prior to the artificial ageing in the paint bake cycle. This deformation leads to the introduction of dislocations which further modify the artificial ageing response by providing heterogeneous nucleation sites for nucleation of additional strengthening phases. Part 1 of this work deals with the theoretical background and experimental validation of the extended version of NaMo, while Part 2 focuses on the new applications of the extended model by simulation of ageing during paint baking according to typical customer requirements. The model validation is based on a comprehensive set of tensile tests. A comparison between model predictions and measurements shows reasonable agreement, and it is concluded that, after some further development, the model can be used to model the yield strength response of 6xxx automotive sheet alloys incorporating the (combined) effects of natural ageing, deformation and the accurate heat treatments in the paint bake cycle.