Use of schlieren methods to study gas flow in laser technology

L. Mrňa, J. Pavelka, P. Horník, J. Hrabovsky
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Abstract

Laser technologies such as welding and cutting rely on process gases. We suggest to use schlieren imaging to visualize the gas flow during these processes. During the process of laser welding, the shielding gas flows to the welded area to prevent oxidation of the weld pool by surrounding air. The gas also interacts with hot plasma spurting from the key hole induced by the laser beam incident on the molten material. This interaction is quite complicated because hot plasma mixes with the cold shielding gas while the system is moving along the weld. Three shielding gases were used in the presented experiment: Ar, He and N2. Differences in dynamics of the flow are clearly visible on schlieren images. Moreover, high speed recording reveals a structure consisting of hot gas bubbles. We were also able to determine the velocity of the bubbles from the recording. During laser cutting, the process gas flows coaxially with the laser beam from the nozzle to remove the molten material out of the kerf. The gas flow is critical for the quality of the resulting edge of the cut. Schlieren method was used to study gas flow under the nozzle and then under the material being cut. This actually creates another slot nozzle. Due to the very low speed of flow below the material the schleiren method is already at the limit of its sensitivity. Therefore, it is necessary to apply a differential technique to increase the contrast. Distinctive widening of the flow shaped by the kerf was observed.
用纹影法研究激光技术中的气体流动
焊接和切割等激光技术依赖于工艺气体。我们建议使用纹影成像来可视化这些过程中的气体流动。在激光焊接过程中,保护气体流向焊接区,防止焊缝熔池被周围空气氧化。该气体还与入射到熔融材料上的激光束诱导的从关键孔喷出的热等离子体相互作用。这种相互作用相当复杂,因为当系统沿着焊缝移动时,热等离子体与冷保护气体混合。实验采用了氩、氦和氮气三种保护气体。流动动力学的差异在纹影图像上清晰可见。此外,高速记录揭示了一个由热气泡组成的结构。我们还能从录音中确定气泡的速度。在激光切割过程中,加工气体随激光束从喷嘴同轴流动,将熔融材料从切口中去除。气体流动对切割的最终边缘的质量至关重要。采用纹影法研究了喷嘴下和被切割材料下的气流。这实际上创造了另一个槽式喷嘴。由于材料下方的流动速度非常低,施莱伦法的灵敏度已经达到极限。因此,有必要采用差分技术来增加对比度。观察到由切口形成的水流明显变宽。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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