The Effect of AZ31 Alloy Flow Stress Description on the Accuracy of Forward Extrusion FE Simulation Results

The Effect of AZ31 Alloy Flow Stress Description on the Accuracy of Forward Extrusion FE Simulation Results Hot compression tests of the AZ31 magnesium alloy, performed for wide ranges of temperature and strain rate, revealed two different flow curve types for the material investigated. At higher st...

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Bibliographic Details
Published in:Archives of metallurgy and materials 2012-03, Vol.57 (1), p.199-204
Main Authors: Cyganek, Z., Tkocz, M.
Format: Article
Language:English
Subjects:
Accuracy
AZ31
Billets
Compacting
Compression tests
Computer simulation
Deformation
Deformation effects
Extruders
Extrusion
Extrusion billets
Extrusion rate
FE simulation
Flow stress
Forming
Forward extrusion
Heat transmission
Hot pressing
Hydraulic presses
magnesium alloy
Magnesium alloys
Magnesium base alloys
Mathematical analysis
Mathematical models
Metal forming
Numerical models
Parameter estimation
Simulation
Strain rate
Stress functions
Temperature
Tooling
Yield strength
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Summary:The Effect of AZ31 Alloy Flow Stress Description on the Accuracy of Forward Extrusion FE Simulation Results Hot compression tests of the AZ31 magnesium alloy, performed for wide ranges of temperature and strain rate, revealed two different flow curve types for the material investigated. At higher strain rates and lower temperatures, flow curves exhibit a distinct peak. At lower strain rates and higher temperatures, flow stress values change less rapidly. This makes it difficult to find a single function able to accurately describe the deformation behaviour of AZ31 alloy in the entire forming range. The present study discusses an effect of the AZ31 magnesium alloy flow stress description on the accuracy of extrusion force prediction by means of FE simulation. A number of forward extrusion trials were carried out in order to acquire experimental data on AZ31 alloy deformation behavior in various forming conditions. Cylindrical billets of 40 mm in diameter and the tooling were initially heated to temperatures in the range of 200 to 400°C and placed in the working space of the 1500 kN hydraulic press to produce extruded rods of 12 mm in diameter. Numerical models for conducting corresponding extrusion simulations were prepared in Forge 2009 software and the selected form of Hensel-Spittel function was applied for the material flow stress description. Function coefficients were calculated both for the entire forming range of AZ31 alloy as well as for the ranges of parameters specific to a certain extrusion trial conditions. The numerical results were compared to the experimental ones and the accuracy of both approaches were estimated. It was found that the selected flow stress function, determined for the wide ranges of temperature and strain rate, allows to achieves a tis factory accuracy of AZ31 alloy extrusion force prediction by FE simulations.
ISSN:1733-3490
2300-1909
DOI:10.2478/v10172-012-0010-y