Paper Titles

Lightweight Battery Housings from Thin-Walled, Large-Scale Aluminum Profiles by Hot Extrusion
p.51

Calibrating a Lode-Parameter-Dependent Damage Evolution Equation to Cold Extrusion Experiments
p.63

Effect of Chemical Composition on Hot Extrudability and Tribological Behavior of 7000 Series Aluminum Alloys
p.73

Using Tungsten Inert Gas Welding Equipment to Locally Heat Tubes and Achieve Inhomogeneous Thickness in Tube Sinking Processes
p.83

Charge Weld Evolution in Profile Extrusion: Variability across Billets and Multi-Profile Designs
p.93

Development of a System for Ultrasonic Die Oscillations during Extrusion of Aluminum Hollow Profiles
p.109

Detection of Charge Welds in Lateral Angular Co-Extrusion Using Non-Destructive Testing
p.121

Comparative Characterization through Torsion Tests of Primary and Secondary Aluminum Alloys for the Extrusion Process
p.133

Transient Thermal Analysis of Multiple Extrusion Runs with Nitrogen Cooling by Means of Qform Code
p.151

HomeKey Engineering MaterialsKey Engineering Materials Vol. 1048Charge Weld Evolution in Profile Extrusion:...

Charge Weld Evolution in Profile Extrusion: Variability across Billets and Multi-Profile Designs

Article Preview

View Pdf By email

Abstract:

Transverse (charge) welds form during billet transitions in aluminium extrusion when incoming material progressively replaces residual metal inside the die, defining the length of extrudate that must be scrapped. This study aimed to quantify charge weld evolution under industrially relevant conditions that are often underestimated in scrap length assessment, including multi-cavity flow imbalance, non-symmetric multi-profile placement, and billet-to-billet thermal stabilisation effects. Three case studies were analysed using finite element simulation in QForm UK: (i) the International Extrusion Benchmark 2023 multicavity die producing three hollow tubes with intentionally varied port and bearing designs, (ii) an industrial two-profile die with translated (non-mirrored) profile positioning to avoid post-extrusion rotation, and (iii) a complex industrial profile extruded over multiple consecutive billets. The benchmark study demonstrated strong agreement between simulation and experimental charge weld evolution for two profiles, supporting the reliability of the predicted cavity-dependent differences driven by port volume. In the translated two-profile configuration, the charge weld cut length required for full purity increased from 1674 mm to 1940 mm (+16.0%), and by +15.9% under the 95% industrial criterion (1458.1 mm vs 1690.7 mm). Billet-to-billet variability was substantial, with charge weld length increasing by +70.1% from the first to the fifth billet (2819.0 mm to 4791.7 mm), before stabilising. Overall, the results show that charge weld length is governed by residence-time differences through ports and flow channels, requiring profile-specific assessment and consideration of process stabilisation. In this context, FE simulation provides an effective means to localise the mixed zone and to support die optimisation strategies aimed at reducing scrap.

You might also be interested in these eBooks

Extrusion and Drawing

Info:

Periodical:

Key Engineering Materials (Volume 1048)

Pages:

93-107

DOI:

https://doi.org/10.4028/p-86kenT

Citation:

Cite this paper

Online since:

April 2026

Authors:

Ivan Kniazkin*, Ivan Kulakov, Nikolay Biba

Keywords:

Aluminum, Charge Weld, Defect, FEA, QForm, Quality, Simulation, Transverse Weld

Export:

RIS, BibTeX

Permissions:

Creative Commons CC BY 4.0

Share:

Citation:

* - Corresponding Author

[1] T. Sheppard, Extrusion of Aluminium Alloys, Springer, 1999.

[2] Y. Mahmoodkhani, M. Wells, N. Parson, C. Jowett, W. Poole, Modeling the formation of transverse weld during billet-on-billet extrusion, Materials 7 (2014) 3470-3480.

DOI: 10.3390/ma7053470

[3] A.J. den Bakker, L. Katgerman, S. van der Zwaag, Analysis of the structure and resulting mechanical properties of aluminium extrusions containing a charge weld interface, Journal of Materials Processing Technology 229 (2016) 9-21.

DOI: 10.1016/j.jmatprotec.2015.09.013

[4] N. Nanninga, C. White, R. Dickson, Charge weld effects on high cycle fatigue behavior of a hollow extruded AA6082 profile, Journal of Materials Engineering and Performance 20 (2011) 1235-1241.

DOI: 10.1007/s11665-010-9755-5

[5] I. Kniazkin, R. Pelaccia, S. Di Donato, L. Donati, B. Reggiani, N. Biba, R. Rezvykh, I. Kulakov, Investigation of the skin contamination predictability by means of QForm UK extrusion code, Materials Research Proceedings, 28 (2023) 543-552.

DOI: 10.21741/9781644902479-59

[6] Q. Li, C. Harris, M.R. Jolly, Finite element modelling simulation of transverse welding phenomenon in aluminium extrusion process, Materials & Design 24 (2003) 493-496.

DOI: 10.1016/s0261-3069(03)00123-7

[7] B. Reggiani, L. Donati, Experimental, numerical, and analytical investigations on the charge weld evolution in extruded profiles, The International Journal of Advanced Manufacturing Technology 99 (2018) 1379-1387.

DOI: 10.1007/s00170-018-2595-4

[8] E.C. Sariyarlioglu, M. Negozio, T. Welo, J. Ma, Charge weld evolution in hollow aluminum extrusion: Experiments and modeling, CIRP Journal of Manufacturing Science and Technology 49 (2024) 14-27.

DOI: 10.1016/j.cirpj.2023.12.007

[9] B. Reggiani, A. Segatori, L. Donati, L. Tomesani, Prediction of charge welds in hollow profiles extrusion by FEM simulations and experimental validation, The International Journal of Advanced Manufacturing Technology 69 (2013) 1855-1872.

DOI: 10.1007/s00170-013-5143-2

[10] B. Reggiani, L. Donati, L. Tomesani, Multi-goal optimization of industrial extrusion dies by means of meta-models, The International Journal of Advanced Manufacturing Technology 88 (2017) 3281-3293.

DOI: 10.1007/s00170-016-9009-2

[11] M. Crosio, D. Hora, C. Becker, P. Hora, Realistic representation and investigation of charge weld evolution during direct porthole die extrusion processes through FE-analysis, Procedia Manufacturing 15 (2018) 232-239.

DOI: 10.1016/j.promfg.2018.07.214

[12] B. Reggiani, T. Pinter, L. Donati, Scrap assessment in direct extrusion, The International Journal of Advanced Manufacturing Technology 107 (2020) 2635-2647.

DOI: 10.1007/s00170-020-05127-x

[13] E.C. Sariyarlioglu, J. Ma, T. Welo, Prediction of charge-weld strength in aluminum extrusion using solid-state welding models, Materials Research Proceedings 54 (2025) 754-763.

DOI: 10.21741/9781644903599-81

[14] M. Negozio, R. Pelaccia, L. Donati, B. Reggiani, T. Pinter, & L. Tomesani, Finite element model prediction of charge weld behaviour in AA6082 and AA6063 extruded profiles, Journal of Materials Engineering and Performance 30.6 (2021) 4691-4699.

DOI: 10.1007/s11665-021-05752-x

[15] E.C. Sariyarlioglu, T. Welo, Towards In-process Scrap Reduction in Aluminium Extrusion: A Multiscale Investigation of Charge-Weld Integrity Advances in Industrial and Manufacturing Engineering 100183 (2026).

DOI: 10.1016/j.aime.2026.100183

[16] A. Hansel, T. Spittel, Kraft- und Arbeitsbedarf Bildsamer Formgebungsverfahren, Deutscher Verlag für Grundstoffindustrie, Leipzig, 1978.

[17] R. Pelaccia, M. Negozio, S. Di Donato, B. Reggiani, L. Donati, Extrusion Benchmark 2023: Effect of die design on profile speed, seam weld quality and microstructure of hollow tubes, Key Engineering Materials 988 (2024) 47-62.

DOI: 10.4028/p-gnxrc5

[18] G.J. Oberhausen, A.A. Christopher, & D.R. Cooper, Reducing aluminum extrusion transverse weld process scrap, In Forming the Future: Proceedings of the 13th International Conference on the Technology of Plasticity (2021) 1003-1019.

DOI: 10.1007/978-3-030-75381-8_84

[19] A. Bakker, Weld Seams in Aluminium Alloy Extrusions: Microstructure and Properties, Ph.D. Thesis, Delft University 2016.