Flexible Hot Rolling of Extruded Shapes of Aluminum Alloy EN AW-6082

Olexandr Grydin; Nikolay Sotirov; Andriy Samsonenko; Nikolay Biba; Anatolii Andreiev; Mykhailo Stolbchenko; Teresa Behr; Iaroslav Frolov; Mirko Schaper

doi:10.4028/www.scientific.net/MSF.949.85

Paper Titles

A Simulation-Based Approach to Predict the Springback Behavior of Ultra-High Strength Spring Strips
p.48

Hot Deformation Behaviour and Processing Maps of an as-Cast Mg-6.8Y-2.5Zn-0.4Zr Alloy
p.57

Trends and Solutions for Future Steel Grade Development
p.66

Application Specific Microstructure Development in Microalloyed Bainitic Hot Strip
p.76

Flexible Hot Rolling of Extruded Shapes of Aluminum Alloy EN AW-6082
p.85

Modeling of Microstructural Evolution in the Hot Rolling Process of Fe-16Cr-4Mn-4Ni-0.05C-0.17N Austenitic Stainless Steel
p.93

Simulation Assisted Process Development for Tailored Forming
p.101

Simulation-Based Investigation of the Influence of Process Parameter Deviations on the Quality of Clinch Connections with Preformed Hole
p.112

Development of a Friction Welded Joint for Future Industrial Application
p.119

HomeMaterials Science ForumMaterials Science Forum Vol. 949Flexible Hot Rolling of Extruded Shapes of...

Flexible Hot Rolling of Extruded Shapes of Aluminum Alloy EN AW-6082

Abstract:

One of the strategies employed to lower weight and to decrease material consumption is reducing part thickness itself. Thus, functionally graded materials in which structural reinforcement is adjusted locally, are of great interest. With regard to conventional industrial processes, such as extrusion or flexible cold rolling, thickness variations can only be achieved either longitudinally or through the cross-section of the semi-finished products. Hence, a combined thickness variation (along both axes) is difficult to generate solely by extrusion or rolling. A simultaneous thickness variation in both directions, however, would enable further weight savings in structural components such as car body parts. In this study, a promising approach with extruded shapes, serving as a billet for a flexible hot rolling process, is elaborated upon. By employing the described process modification, shapes with simultaneous thickness variations in longitudinal as well as in transverse direction are feasible. Initial numerical analysis reveals the weight-saving potential of using these semi-finished products for structural parts in a car body. A demonstration of the production process for the semi-finished parts and the occurring challenges are discussed. To verify and adjust the new technology, a numerical model of the flexible hot rolling process has been created based on the finite element software QForm VX. This model is also employed for tool design optimization to produce semi-finished components with the required geometrical quality. Finally, the results of hot rolling experiments conducted using the adjusted roll design are presented.

By email View Pdf

You have full access to the following eBook

Simulation-Based Technology Development for Material Forming

Read eBook

Info:

Periodical:

Materials Science Forum (Volume 949)

Pages:

85-92

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.949.85

Citation:

Cite this paper

Online since:

March 2019

Authors:

Olexandr Grydin, Nikolay Sotirov, Andriy Samsonenko, Nikolay Biba, Anatolii Andreiev, Mykhailo Stolbchenko, Teresa Behr, Iaroslav Frolov, Mirko Schaper

Keywords:

Aluminum, Extruded Shape, Hot Deformation, Rolling

Export:

RIS, BibTeX

Permissions:

Creative Commons CC BY 4.0

References

[1] D. Lesniak, W. Libura, Extrusion of sections with varying thickness through pocket dies, Journal of Materials Processing Technology 194 (2007) 38–45.

DOI: 10.1016/j.jmatprotec.2007.03.123

Google Scholar

[2] O. Engler, C. Schäfer, H. Brinkman, J. Brecht, P. Beiter, K. Nijhof, Flexible rolling of aluminium alloy sheet – Process optimization and control of materials properties, Journal of Materials Processing Technology 229 (2016) 139–148.

DOI: 10.1016/j.jmatprotec.2015.09.010

Google Scholar

[3] G. Hirt, D. H. Dávalos-Julca, Tailored Profiles Made of Tailor Rolled Strips by Roll Forming – Part 1 of 2, Steel Research International 83 (2012) 100–105.

DOI: 10.1002/srin.201100269

Google Scholar

[4] QForm – Software for simulation and optimization of metal forming processes and metal profile extrusion, QFX Simulations Ltd., http://www.qform3d.com.

Google Scholar

[5] A. Hensel, T. Spittel, Kraft - und Arbeitsbedarf bildsamer Formgebungsverfahren, Deutscher Verlag für Grundstoffindustrie, Leipzig, 1978 (in German).

Google Scholar

[6] A.N. Levanov, V.L. Kolmogorov, S.P. Burkin, B.R. Kartak, Yu.V. Ashpur, Yu.I. Spasskiy, Contact friction in metal forming processes, Mashinostroenie, Moscow, 1975 (in Russian).

Google Scholar

[7] B.K. Chen, P.F. Thomson, S.K. Choi, Temperature distribution in the roll-gap during hot flat rolling, Journal of Materials Processing Technology 30 (1992) 115–130.

DOI: 10.1016/0924-0136(92)90042-q

Google Scholar

[8] M. G. Cockcroft, D. J. Latham, Ductility and the workability of metals, Journal of the Institute of Metals, 96 (1968) 33-39.

Google Scholar

[9] O. Grydin, A. Andreiev, N. Sotirov, M. Stolbchenko, T. M. Behr, A. Ashkelianets, I. Frolov, M. Schaper, Water quenching of hot rolled aluminum strips: Process integrated heat treatment of the alloy EN AW-6082, The Journal of the Minerals Metals & Materials Society (2018) 1–12.

DOI: 10.1007/s11837-018-3144-1

Google Scholar