Numerical and experimental investigation of the formability of AA6013-T6

AA6013 is an age-hardenable, aluminum alloy with the potential for structural applications in weight-sensitive automotive components. The alloy is at peak strength in the T6 temper, but exhibits relatively low room temperature formability. In an effort to avoid costly post-forming heat-treatments, w...

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Bibliographic Details
Published in:Journal of physics. Conference series 2017-09, Vol.896 (1), p.12114
Main Authors: DiCecco, S., Di Ciano, M., Butcher, C., Worswick, M.
Format: Article
Language:English
Subjects:
Age hardening
Aluminum base alloys
Anisotropy
Automotive parts
Digital imaging
Evolution
Formability
Forming limit diagrams
Hardenability
High temperature
Isothermal flow
Necking
Physics
Plane strain
Room temperature
Strain distribution
Strain measurement
Strain rate
Temper (metallurgical)
Tensile tests
Thinning
Weight reduction
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Summary:AA6013 is an age-hardenable, aluminum alloy with the potential for structural applications in weight-sensitive automotive components. The alloy is at peak strength in the T6 temper, but exhibits relatively low room temperature formability. In an effort to avoid costly post-forming heat-treatments, warm forming of the AA6013 in the T6 temper is investigated in the current work. The experimental formability of the alloy is characterized from room temperature to 250°C through limiting dome height (LDH) tests with a Nakazima hemispherical punch and in-situ stereoscopic digital image correlation (DIC) strain measurement. A forming limit diagram (FLD) is generated from the application of a curvature-based necking criterion to the elevated temperature LDH test results. The evolution of the strain distribution prior to necking is explored using models of the plane strain LDH tests at room temperature and 200°C. At 200°C, strain rate effects are explored relative to the local temporal strain evolution. Modelling efforts include development of a Barlat Yld2000 yield surface to capture the anisotropy of the alloy and use of experimentally obtained isothermal flow-stress curves. The effects of different tensile gage lengths on flow-stress and yield surface calibration for warm tensile testing are discussed. The room temperature model was found to accurately depict the thinning strain distribution consistent with the "safe" thinning strain distribution at room temperature. At 200°C, it is shown that the temporal strain evolution is strongly influenced by strain-rate effects.
ISSN:1742-6588
1742-6596
DOI:10.1088/1742-6596/896/1/012114