Dynamic Characteristics of Plasma in Ultrasonic-Assisted Narrow-Gap Laser Welding with Filler Wire

Ren, Wei; He, Zhenxing; Kan, Xiaoyang; Li, Ké; Chen, Fugang; Fu, Juan; Zhao, Yixin

doi:10.3390/ma16020502

Cited by 3 publications

(2 citation statements)

References 25 publications

(25 reference statements)

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“…Kovalev et al,in [13], discussed different methods for producing light-trapping "black" silicon, namely laser, chemical and hybrid chemical/laser. Wang et al,in [14], presented the results of a study where a steel plate was welded by ultrasonic-assisted narrow-gap laser welding with a filler wire, and the plasma was observed using a high-speed camera and spectrograph. Fu et al,in [15], presented a research study in which duplex stainless steel was welded by alternating a magnetic field with a laser-arc.…”

Section: Resultsmentioning

confidence: 99%

Advances in Plasma and Laser Engineering

Jasiński

2024

Materials

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Section: Resultsmentioning

confidence: 99%

Advances in Plasma and Laser Engineering

Jasiński

2024

Materials

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“…Through a large number of experiments, Long et al [ 10 ] found that the key to solve the incomplete fusion was the ratio of the welding line energy to the wire feed. Wang et al [ 11 ] reduced the porosity defects effectively with ultrasonic assistance and found that the electron temperature and density of the laser-induced plasma increased [ 12 ]. Jiang et al [ 13 ] found that laser oscillation brought a strong stirring effect, which changed the growth pattern of the sidewall grain and reduced the porosity defects.…”

Section: Introductionmentioning

confidence: 99%

Study on Porosity Defect Detection in Narrow Gap Laser Welding Based on Spectral Diagnosis

Liu

Xu²,

Feng

et al. 2023

Materials

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As an advanced connection technology for large thick-walled components, narrow gap laser welding has the advantages of small heat input and high efficiency and quality. However, porosity defects are prone to occur inside the weld due to the complex welding environment. In this study, the influence of the process parameters and pollutants such as water and oil on the porosity defect were explored. The action mechanism of water on the electron temperature and spectral intensity of the laser-induced plasma was analyzed. The results showed that the spectral intensity during narrow gap laser welding was weaker than that of flat plate butt welding. Under the optimal welding process conditions, the electron temperature during narrow gap laser self-fusion welding was calculated as 7413.3 K by the Boltzmann plot method. The electron density was 5.6714 × 1015 cm−3, conforming to the thermodynamic equilibrium state. With six groups of self-fusion welding parameters, only sporadic porosity defects were observed according to the X-ray detection. When there was water on the base metal surface, a large number of dense pores were observed on the weld surface and in the weld through X-ray inspection. Compared with the spectral data obtained under the normal process, the relative light intensity of the spectrometer in the whole band was reduced. The electron temperature decreased to the range of 6900 to 7200 K, while the electron density increased. The spectrum variation during narrow gap laser wire filling welding was basically the same as that of laser self-fusion welding. The porosity defects caused by water and oil pollutants in the laser welding could be effectively identified based on the intensity of the Fe I spectral lines.

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