Influence of the ultrasonic vibration amplitude on the melt pool dynamics and the weld shape of laser beam welded EN AW-6082 utilizing a new excitation system for laser beam welding

Laser beam welding is a commonly used technology for joining similar and dissimilar materials. In order to improve the mechanical properties of the weld, the introduction of ultrasonic vibration into the weld zone has been proposed [5]. The ultrasonic system consists of an electronic control, a powe...

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Veröffentlicht in:Production engineering (Berlin, Germany) Germany), 2021-04, Vol.15 (2), p.151-160
Hauptverfasser: Ohrdes, H., Nothdurft, S., Nowroth, C., Grajczak, J., Twiefel, J., Hermsdorf, J., Kaierle, S., Wallaschek, J.
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container_end_page 160
container_issue 2
container_start_page 151
container_title Production engineering (Berlin, Germany)
container_volume 15
creator Ohrdes, H.
Nothdurft, S.
Nowroth, C.
Grajczak, J.
Twiefel, J.
Hermsdorf, J.
Kaierle, S.
Wallaschek, J.
description Laser beam welding is a commonly used technology for joining similar and dissimilar materials. In order to improve the mechanical properties of the weld, the introduction of ultrasonic vibration into the weld zone has been proposed [5]. The ultrasonic system consists of an electronic control, a power supply, a piezoelectric converter and a sonotrode, which introduces the vibration into the weld zone. Its proper design is of great importance for the process performance. Furthermore, the effects of ultrasound in a melt pool need to be understood to evaluate and optimize the process parameters. In addition, it is important to find out the limits of ultrasonic excitation with respect to a maximum vibration amplitude. Therefore, firstly different methods of ultrasonic excitation are investigated and compared with respect to their performance. A system which is based on using longitudinal vibrations turns out to be the best alternative. Secondly, the system design is described in detail to understand the boundary conditions of the excitation and finally, simulations about the influence of ultrasonic vibrations are done by using a simplified model. The system is used to perform experiments, which aim at detecting the maximum vibration amplitude doing bead on plate welds of EN AW-6082 aluminum alloy. The experiments reveal a significant change of the weld shape with increasing ultrasonic amplitude, which matches the simulative findings. If the amplitudes are small, there is a marginal effect on the weld shape. If the amplitudes are high, melt is ejected and the weld shape is disturbed. In the present case, amplitudes over 4 µm were found to disturb the weld shape.
doi_str_mv 10.1007/s11740-020-01008-0
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1863-7353
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subjects Aluminum base alloys
Amplitudes
Bead on plate welding
Boundary conditions
Converters
Dissimilar material joining
Dissimilar materials
Electronic control
Engineering
Excitation
Industrial and Production Engineering
Laser beam welding
Lasers
Mechanical properties
Piezoelectricity
Process parameters
Production
Production Process
Shape effects
Systems design
Ultrasonic testing
Ultrasonic vibration
Vibration
Welded joints
title Influence of the ultrasonic vibration amplitude on the melt pool dynamics and the weld shape of laser beam welded EN AW-6082 utilizing a new excitation system for laser beam welding
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