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Main Authors: Rupp, Marco, Schwarzkopf, Karen, Doering, Markus, Hayashi, Shuichiro, Schmidt, Michael, Arnold, Craig B.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2404.07195
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author Rupp, Marco
Schwarzkopf, Karen
Doering, Markus
Hayashi, Shuichiro
Schmidt, Michael
Arnold, Craig B.
author_facet Rupp, Marco
Schwarzkopf, Karen
Doering, Markus
Hayashi, Shuichiro
Schmidt, Michael
Arnold, Craig B.
contents Spatially selective melting of metal materials by laser irradiation allows for the precise welding as well as the 3D printing of complex metal parts. However, the simple scanning of a conventional Gaussian beam typically results in a melt track with randomly distributed surface features due to the complex and dynamic behavior of the melt pool. In this study, the implications of utilizing a dynamically oscillating energy input on driving melt track fluctuations is investigated. Specifically, the laser intensity and/or intensity distribution is sinusoidally modulated at different scan speeds, and the effect of modulation frequency on the resulting surface features of the melt track is examined. The formation of periodically oriented surface features indicates an evident frequency coupling between the melt pool and the modulation frequency. Moreover, such a frequency coupling becomes most prominent under a specific modulation frequency, suggesting resonant behavior. The insights provided in this study will enable the development of novel methods, allowing for the control and/or mitigation of inherent fluctuations in the melt pool through laser-driven resonances.
format Preprint
id arxiv_https___arxiv_org_abs_2404_07195
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Laser driven melt pool resonances through dynamically oscillating energy inputs
Rupp, Marco
Schwarzkopf, Karen
Doering, Markus
Hayashi, Shuichiro
Schmidt, Michael
Arnold, Craig B.
Materials Science
Optics
Spatially selective melting of metal materials by laser irradiation allows for the precise welding as well as the 3D printing of complex metal parts. However, the simple scanning of a conventional Gaussian beam typically results in a melt track with randomly distributed surface features due to the complex and dynamic behavior of the melt pool. In this study, the implications of utilizing a dynamically oscillating energy input on driving melt track fluctuations is investigated. Specifically, the laser intensity and/or intensity distribution is sinusoidally modulated at different scan speeds, and the effect of modulation frequency on the resulting surface features of the melt track is examined. The formation of periodically oriented surface features indicates an evident frequency coupling between the melt pool and the modulation frequency. Moreover, such a frequency coupling becomes most prominent under a specific modulation frequency, suggesting resonant behavior. The insights provided in this study will enable the development of novel methods, allowing for the control and/or mitigation of inherent fluctuations in the melt pool through laser-driven resonances.
title Laser driven melt pool resonances through dynamically oscillating energy inputs
topic Materials Science
Optics
url https://arxiv.org/abs/2404.07195