Deep Drawing of Ti6Al4V: Experiments and Modeling over a Wide Range of Strain Rates and Temperatures

Benjamin Chartrel; Elisabeth Massoni

doi:10.4028/www.scientific.net/KEM.554-557.190

Paper Titles

Submicrocristalline Structure and Dynamic Recovery of Cold Flowformed ELI Grade Ti-6Al-4V
p.157

Prediction of Surface Roughening and Necking Behavior for Metal Foils by Inhomogeneous FE Material Modeling
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Design of an Experimental Device for Biaxial Tension Tests Used in a Uniaxial Test Machine
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Determination of Flow Curve Using Bulge Test and Calibration of Damage for Ito-Goya Models
p.182

Deep Drawing of Ti6Al4V: Experiments and Modeling over a Wide Range of Strain Rates and Temperatures
p.190

Analysis of the Incremental Forming of Titanium F67 Grade 2 Sheet
p.195

Effect of the Mechanical Parameters Used as Input Data in the Yield Criteria on the Accuracy of the Finite Element Simulation of Sheet Metal Forming Processes
p.204

On the Development and Identification of Phenomenological Damage Models - Application to Industrial Wire Drawing and Rolling Processes
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Optimization Analysis of A7075 Bicycle Stem Forging Process
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HomeKey Engineering MaterialsKey Engineering Materials Vols. 554-557Deep Drawing of Ti6Al4V: Experiments and Modeling...

Deep Drawing of Ti6Al4V: Experiments and Modeling over a Wide Range of Strain Rates and Temperatures

Abstract:

A combined experimental-numerical approach using digital image correlation (DIC) and finite element simulation in order to get the temperature dependent mechanical behaviour is presented. Results from a series of experiments on a Ti6Al4V titanium alloy sheet are shown. Tensile tests were carried out on specimens along 3 different orientations in order to characterise the material anisotropy. The strain-rates are varied from 10-1 to 10-2 s-1 while observations are made at temperatures from 903 to 1003 K. The samples are heated by Joule effect, which allows to use the image correlation in order to obtain the deformation fields and thus the coefficients of Lankford [1]. Differences in the responses of this alloy are observed in terms of work hardening, strain rate and temperature sensitivities. The Norton-Hoff model and the Hill [2] criterion are used to effectively simulate the observed responses obtained from these experiments. An inverse analysis model using kriging meta-model [3] is applied to determine each parameter of the mechanical behaviour law. The model, with the constants determined from these experiments, is then used to predict the mechanical behaviour of Ti6Al4V. Thus, the model is implemented into the implicit finite element code Forge® to model forming of thin-walled structures. The predictions are found to be very close to the observations.

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Periodical:

Key Engineering Materials (Volumes 554-557)

Pages:

190-194

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.554-557.190

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Online since:

June 2013

Authors:

Benjamin Chartrel, Elisabeth Massoni

Keywords:

Behavior Law, Sheet Forming, Ti6Al4V, Titanium Alloy

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