Abstract

Joining of copper materials has become a key factor in laser material processing of electric components like electric engines, batteries, or power electronics. A paramount challenge is the design of the laser welding process, which has to fulfil the requirements of high energy efficiency and highest seam quality at the same time. By now, high-power laser beam sources emitting visible laser radiation are available to promote the well-suited noncontact joining method, which is furthermore characterized by local energy input and high automation potential. These laser sources can now face the challenges of welding highly conductive and reflective materials, such as copper, which originate mainly in the low absorption of conventionally used infrared wavelengths at room temperature and the rapid jump of absorptivity at transition from solid to liquid state. An increase in absorption of electromagnetic radiation to more than 40% for copper at room temperature for λ = 515 nm leads to increasing energy input in the material and promotes a more efficient process therefore. However, up to now, mostly the heat conduction welding regime has been examined and the effects of shorter wavelengths on deep penetration welding have not been understood in detail. A strong deviation in weld seam depth between infrared and green laser radiation is observed for identical process parameters depending on the use of additional gas supply [F. Kaufmann, A. Meier, J. Ermer, S. Roth, and M. Schmidt, “Influence of defocusing in deep penetration welding of copper by using visible wavelength,” in Proceedings of the Eleventh International WLT-Conference on Lasers in Manufacturing, Munich, 21–24 June 2021 (M. Reth, Munich, 2021)]. Consequently, radiation attenuation by the metal vapor inside and above the keyhole plays a substantial role in the case of 515 nm laser welding [M. Haubold, A. Ganser, T. Eder, and M. F. Zäh, “Laser welding of copper using a high power disc laser at green wavelength,” Procedia CIRP 74, 446–449 (2018)]. In this work, we investigate in situ measurements of plume attenuation during laser beam welding of copper with 515 and 1030 nm laser beam sources. Both laser sources are equipped with comparable optical setups to achieve identical focal diameters on the material surface. We investigate the plume characteristics in the deep penetration welding mode of copper. A range of industry-relevant process parameters are investigated to create a basis for comparison with theoretical models. It is found that a significant difference in the attenuation of both laser wavelengths occurs in the case of deep penetration welding copper specimen and blowing the vapor plume out of the beam path is recommended therefore for an efficient welding process.

Highlights

  • Increasing demand for electric powertrains brings copper to a material that is widely used in drive and battery technology these days

  • We investigate in situ measurements of plume attenuation during laser beam welding of copper with 515 and 1030 nm laser beam sources

  • Weld seams processed with a green laser show a weld seam depth increased by a factor of 67% and a molten area increased by 33% in size on average for all types of gasses applied in this work for identical operating parameters otherwise. This behavior can be attributed to the increased absorptivity of copper for visible wavelengths, as a higher portion of incident laser energy gets coupled into the material by multiple reflections in vapor capillary

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Summary

Introduction

Increasing demand for electric powertrains brings copper to a material that is widely used in drive and battery technology these days. Compared to other manufacturing processes, like arc welding, it is characterized by high precision, scitation.org/journal/jla efficiency, and high reproducibility.. Compared to other manufacturing processes, like arc welding, it is characterized by high precision, scitation.org/journal/jla efficiency, and high reproducibility.1 Until now, this process is mainly dominated by laser beam sources in the infrared wavelength range. A significantly higher value is found for visible wavelengths, which represents one motivation for the development of high-power laser beam sources with λ = 515 and 450 nm. These are recently available in the kW-range of laser output power to face the challenges of welding highly conductive and reflective materials, such as copper. Up to now, mostly the heat conduction welding regime has been examined, and there is still no deep knowledge of how the processes in and above the material differ due to the use of shorter wavelength during deep penetration welding

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