Publication: Melting by Reflected Laser Beam during Vertical Welding via Hot-Wire Laser Welding
Issued Date
2019-01-01
Resource Type
ISSN
02884771
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2-s2.0-85075999758
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Mahidol University
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SCOPUS
Bibliographic Citation
Yosetsu Gakkai Ronbunshu/Quarterly Journal of the Japan Welding Society. Vol.37, No.4 (2019), 208-214
Suggested Citation
Sittisak Charunetratsamee, Eakkachai Warinsiriruk, Shinozaki Kenji, Yamamoto Motomichi Melting by Reflected Laser Beam during Vertical Welding via Hot-Wire Laser Welding. Yosetsu Gakkai Ronbunshu/Quarterly Journal of the Japan Welding Society. Vol.37, No.4 (2019), 208-214. doi:10.2207/qjjws.37.208 Retrieved from: https://repository.li.mahidol.ac.th/handle/20.500.14594/50881
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Title
Melting by Reflected Laser Beam during Vertical Welding via Hot-Wire Laser Welding
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Abstract
© 2019 Japan Welding Society. All rights reserved. We investigated the melting of a base metal, molten pool growth, and joint creation during vertical welding via hot-wire-laser welding. Three laser-weaving conditions were investigated by changing the weaving frequency and waveform to study the effects of the irradiation duration near the groove surface. In addition, high-speed and cross-sectional imaging were performed to investigate the heating and melting processes on the groove surface during hot-wire laser welding. The irradiation duration near the groove surface in a cycle had a marked effect on the melting of the groove surface. The combination of a 5 Hz laser frequency with an exponential waveform led to a longer duration near the groove surface during a cycle and realized improved fusion compared with the other combinations with a 15 Hz laser frequency and a sine waveform. The laser beam reflected from the molten pool surface was the main source of heat for melting the groove surface. Hot-wire feeding provided a continuous and efficient supply of melted material and a stable heat input on the groove surface via the reflected laser beam.