A coupled experimental/numerical approach for the characterization of material behaviour at high strain-rate using electromagnetic tube expansion testing

•Instrumentation and modelling of electromagnetic tube expansion are developed.•The behaviour of AA-1050 at strain-rates of 1000 s−1 to 5000 s−1 is identified.•The parameters of the Johnson–Cook model are highly correlated in these tests.•The sensitivity of characterization to experimental uncertain...

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Bibliographic Details
Published in:International journal of impact engineering 2016-12, Vol.98, p.75-87
Main Authors: Jeanson, Anne-Claire, Bay, François, Jacques, Nicolas, Avrillaud, Gilles, Arrigoni, Michel, Mazars, Gilles
Format: Article
Language:English
Subjects:
Electromagnetic forming
Engineering Sciences
Johnson–Cook model
Material characterization
Materials
Sensitivity analysis
Strain rate
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Summary:•Instrumentation and modelling of electromagnetic tube expansion are developed.•The behaviour of AA-1050 at strain-rates of 1000 s−1 to 5000 s−1 is identified.•The parameters of the Johnson–Cook model are highly correlated in these tests.•The sensitivity of characterization to experimental uncertainties is evaluated. High speed forming processes such as magnetic pulse forming are gaining interest in the sheet metal industry. Their design and development require specific effort on numerical modelling as well as on the characterization of the high strain-rate mechanical behaviour of metals. Standard dynamic tests (SHPB, plate impact, simple tension…) are limited in their representativeness of the deformation modes encountered in high speed processes. The present study describes how the electromagnetic tube expansion test can be used as a high strain-rate test for the identification of material constitutive parameters. Through numerical analysis, the deformation mode and the sensitivity of radial expansion to material constitutive behaviour are depicted. Then, the material parameter identification methodology is applied to annealed 1050 aluminium tubes. It is shown that the test is capable of highlighting the strain-rate sensitivity of behaviour, in spite of relatively high sensitivity to measurement uncertainties.
ISSN:0734-743X
1879-3509
DOI:10.1016/j.ijimpeng.2016.07.002