Investigations on the effect of different ultrasonic amplitudes and positions in the vibration distribution on the microstructure of laser beam welded stainless steel

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Autoren

  • Sarah Nothdurft
  • Hendrik Ohrdes
  • Jens Twiefel
  • Jörg Wallaschek
  • Jörg Hermsdorf
  • Ludger Overmeyer
  • Stefan Kaierle

Organisationseinheiten

Externe Organisationen

  • Laser Zentrum Hannover e.V. (LZH)
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Titel des SammelwerksHigh-Power Laser Materials Processing
UntertitelApplications, Diagnostics, and Systems IX
Herausgeber/-innenStefan Kaierle, Stefan W. Heinemann
Herausgeber (Verlag)SPIE
ISBN (elektronisch)9781510633094
PublikationsstatusVeröffentlicht - 2 März 2020
VeranstaltungSPIE LASE - San Francisco, California, USA / Vereinigte Staaten
Dauer: 1 Feb. 20206 Feb. 2020

Publikationsreihe

NameProceedings of SPIE - The International Society for Optical Engineering
Band11273
ISSN (Print)0277-786X
ISSN (elektronisch)1996-756X

Abstract

Laser beam welding is a necessary and helpful tool in modern production technology. It provides low and located heat input, narrow weld widths, high welding speeds and weld depths. Nevertheless, in the weld metal and the surrounding area the microstructure and the mechanical characteristics can be changed afterwards. A decrease of strength and fatigue life is a possible result. To realize a manipulation or control of the weld metal's microstructure during the welding process is a great challenge. Improving the strength as well as the homogeneity of mechanical properties and chemical composition are the aims of this approach. With indirect introduced ultrasonic amplitudes, the weld pool dynamics and the solidification are affected. The investigation focusses on the effects in the microstructure of high power (8 kW) laser beam welded stainless steel (AISI 304) with weld depths up to 15 mm. For two different amplitudes (3 and 6 μm) and three different positions of the weld pool in the vibration distribution (antinode, centered and node position) the weld metal is evaluated with metallographic cross sections. The types and the amount of microstructures are analyzed. The solidification of the weld metal is influenced by the vibration. Thus, the orientation, size and growth of the grains as well as the growth direction are changed. Furthermore, the weld characteristics (weld depth, weld width, weld area) are compared to the previously considered aspects.

ASJC Scopus Sachgebiete

Zitieren

Investigations on the effect of different ultrasonic amplitudes and positions in the vibration distribution on the microstructure of laser beam welded stainless steel. / Nothdurft, Sarah; Ohrdes, Hendrik; Twiefel, Jens et al.
High-Power Laser Materials Processing: Applications, Diagnostics, and Systems IX. Hrsg. / Stefan Kaierle; Stefan W. Heinemann. SPIE, 2020. 112730J (Proceedings of SPIE - The International Society for Optical Engineering; Band 11273).

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Nothdurft, S, Ohrdes, H, Twiefel, J, Wallaschek, J, Hermsdorf, J, Overmeyer, L & Kaierle, S 2020, Investigations on the effect of different ultrasonic amplitudes and positions in the vibration distribution on the microstructure of laser beam welded stainless steel. in S Kaierle & SW Heinemann (Hrsg.), High-Power Laser Materials Processing: Applications, Diagnostics, and Systems IX., 112730J, Proceedings of SPIE - The International Society for Optical Engineering, Bd. 11273, SPIE, SPIE LASE, San Francisco, California, USA / Vereinigte Staaten, 1 Feb. 2020. https://doi.org/10.1117/12.2566035
Nothdurft, S., Ohrdes, H., Twiefel, J., Wallaschek, J., Hermsdorf, J., Overmeyer, L., & Kaierle, S. (2020). Investigations on the effect of different ultrasonic amplitudes and positions in the vibration distribution on the microstructure of laser beam welded stainless steel. In S. Kaierle, & S. W. Heinemann (Hrsg.), High-Power Laser Materials Processing: Applications, Diagnostics, and Systems IX Artikel 112730J (Proceedings of SPIE - The International Society for Optical Engineering; Band 11273). SPIE. https://doi.org/10.1117/12.2566035
Nothdurft S, Ohrdes H, Twiefel J, Wallaschek J, Hermsdorf J, Overmeyer L et al. Investigations on the effect of different ultrasonic amplitudes and positions in the vibration distribution on the microstructure of laser beam welded stainless steel. in Kaierle S, Heinemann SW, Hrsg., High-Power Laser Materials Processing: Applications, Diagnostics, and Systems IX. SPIE. 2020. 112730J. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.2566035
Nothdurft, Sarah ; Ohrdes, Hendrik ; Twiefel, Jens et al. / Investigations on the effect of different ultrasonic amplitudes and positions in the vibration distribution on the microstructure of laser beam welded stainless steel. High-Power Laser Materials Processing: Applications, Diagnostics, and Systems IX. Hrsg. / Stefan Kaierle ; Stefan W. Heinemann. SPIE, 2020. (Proceedings of SPIE - The International Society for Optical Engineering).
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title = "Investigations on the effect of different ultrasonic amplitudes and positions in the vibration distribution on the microstructure of laser beam welded stainless steel",
abstract = "Laser beam welding is a necessary and helpful tool in modern production technology. It provides low and located heat input, narrow weld widths, high welding speeds and weld depths. Nevertheless, in the weld metal and the surrounding area the microstructure and the mechanical characteristics can be changed afterwards. A decrease of strength and fatigue life is a possible result. To realize a manipulation or control of the weld metal's microstructure during the welding process is a great challenge. Improving the strength as well as the homogeneity of mechanical properties and chemical composition are the aims of this approach. With indirect introduced ultrasonic amplitudes, the weld pool dynamics and the solidification are affected. The investigation focusses on the effects in the microstructure of high power (8 kW) laser beam welded stainless steel (AISI 304) with weld depths up to 15 mm. For two different amplitudes (3 and 6 μm) and three different positions of the weld pool in the vibration distribution (antinode, centered and node position) the weld metal is evaluated with metallographic cross sections. The types and the amount of microstructures are analyzed. The solidification of the weld metal is influenced by the vibration. Thus, the orientation, size and growth of the grains as well as the growth direction are changed. Furthermore, the weld characteristics (weld depth, weld width, weld area) are compared to the previously considered aspects.",
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AU - Nothdurft, Sarah

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AU - Twiefel, Jens

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AU - Hermsdorf, Jörg

AU - Overmeyer, Ludger

AU - Kaierle, Stefan

N1 - Funding Information: The results presented in this publication were obtained from the Collaborative Research Centre 1153 “Process chain to produce hybrid high performance components with Tailored Forming” in subproject A3. The authors would like to thank the German Research Foundation (DFG) for the financial and organizational support of this project.

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N2 - Laser beam welding is a necessary and helpful tool in modern production technology. It provides low and located heat input, narrow weld widths, high welding speeds and weld depths. Nevertheless, in the weld metal and the surrounding area the microstructure and the mechanical characteristics can be changed afterwards. A decrease of strength and fatigue life is a possible result. To realize a manipulation or control of the weld metal's microstructure during the welding process is a great challenge. Improving the strength as well as the homogeneity of mechanical properties and chemical composition are the aims of this approach. With indirect introduced ultrasonic amplitudes, the weld pool dynamics and the solidification are affected. The investigation focusses on the effects in the microstructure of high power (8 kW) laser beam welded stainless steel (AISI 304) with weld depths up to 15 mm. For two different amplitudes (3 and 6 μm) and three different positions of the weld pool in the vibration distribution (antinode, centered and node position) the weld metal is evaluated with metallographic cross sections. The types and the amount of microstructures are analyzed. The solidification of the weld metal is influenced by the vibration. Thus, the orientation, size and growth of the grains as well as the growth direction are changed. Furthermore, the weld characteristics (weld depth, weld width, weld area) are compared to the previously considered aspects.

AB - Laser beam welding is a necessary and helpful tool in modern production technology. It provides low and located heat input, narrow weld widths, high welding speeds and weld depths. Nevertheless, in the weld metal and the surrounding area the microstructure and the mechanical characteristics can be changed afterwards. A decrease of strength and fatigue life is a possible result. To realize a manipulation or control of the weld metal's microstructure during the welding process is a great challenge. Improving the strength as well as the homogeneity of mechanical properties and chemical composition are the aims of this approach. With indirect introduced ultrasonic amplitudes, the weld pool dynamics and the solidification are affected. The investigation focusses on the effects in the microstructure of high power (8 kW) laser beam welded stainless steel (AISI 304) with weld depths up to 15 mm. For two different amplitudes (3 and 6 μm) and three different positions of the weld pool in the vibration distribution (antinode, centered and node position) the weld metal is evaluated with metallographic cross sections. The types and the amount of microstructures are analyzed. The solidification of the weld metal is influenced by the vibration. Thus, the orientation, size and growth of the grains as well as the growth direction are changed. Furthermore, the weld characteristics (weld depth, weld width, weld area) are compared to the previously considered aspects.

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