Numerical and experimental study of the variation of keyhole depth with an aluminum alloy (AA1050)

Akash Meena*, Andreas Andersson Lassila, Dan Lonn, Kent Salomonsson, Wei Wang, Chris Valentin Nielsen, Mohamad Bayat

*Corresponding author for this work

Research output: Contribution to journalJournal articleResearchpeer-review

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Abstract

The keyhole depth is a key measurement characteristic in the laser welding of busbar to battery tabs in battery packs for electric vehicles (EV), as it directly affects the quality of the weld. In this work, experiments are carried out with controlled and adjusted laser power and feed rate parameters to examine their influence on the keyhole width, keyhole depth and porosities. A 3D numerical model of laser keyhole welding of an aluminum alloy (A1050) has been developed to describe the porosity formation and the keyhole depth variation. A new integration model of the recoil pressure and the rate of evaporation model is implemented which is closer to the natural phenomena as compared to the conventional methods. Additionally, major physical forces are employed including plume formation, upward vapor pressure and multiple reflection in the keyhole. The results show that keyhole depth is lower at higher feed rate, while lower feed rates result in increased keyhole depth.
Original languageEnglish
Article number100196
JournalJournal of Advanced Joining Processes
Volume9
Number of pages13
ISSN2666-3309
DOIs
Publication statusPublished - 2024

Keywords

  • Multiphysics simulation
  • Laser welding
  • Incident angle
  • Melt pool
  • Keyhole depth and width

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