使用usp激光器和长距离工作距离的玻璃焊接

M. Kahle, D. Nodop, P. Wiemuth
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引用次数: 1

摘要

即使使用最新的技术,光学眼镜的连接也是一个挑战。用超短脉冲激光焊接是一种不需要添加剂或宏观热张力连接相似或不同玻璃的方法。激光束通过工件聚焦在待焊界面上。由于激光聚焦的高强度,光束通过非线性效应在直径约20 μ m的体积内被吸收。几个激光脉冲将材料加热到工作点,而导热性将热影响区限制在1毫米以下。这个过程通常用显微镜物镜进行。它们的工作距离短,限制了工件的厚度、可用激光功率和加工的进给速度。为了将焊接伙伴的可能尺寸和工艺速度提高到工业水平,我们提出了使用电激扫描仪和普通f -theta透镜的usp焊接。尽管存在自聚焦效应,但实验表明该过程是稳定可控的。此外,激光束发生丝化,形成直径几微米、高度几百微米的长圆柱形焊缝区。这一巨大长度的熔化区大大降低了对工件调整的要求。对焊接试样进行了拉伸试验。试验表明,焊缝的断裂强度达到母材的数量级。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Glass-welding with USP-lasers and long working distances
The joining of optical glasses is a challenge even with the latest technology. Welding with ultrashort pulsed lasers is a way to join similar or dissimilar glasses without additives or macroscopic thermal tensions. The laser beam is focused through the work piece on the interface to be welded. Due to the high intensity in the laser focus, the beam is absorbed via nonlinear effects in a volume with about 20 µm in diameter. Several laser pulses heat up the material to the working point, while the thermal conductivity limits the heat affected zone well below 1 mm. This process is usually conducted with microscope objectives. Their short working distance limits the thickness of the work piece, the usable laser power and the feed rate of the process. To increase the possible dimensions of the welding partners and the process speed to industrial levels, we present USP-welding with a galvoscanner and a common F-theta-lens. Despite self-focusing effects, our experiments show that the process is stable and controllable. Furthermore, filamentation of the laser beam occurs and long cylindrical weld zones of some micrometers diameter and several hundreds of micrometers height are generated. The enormous length of this molten zone significantly lowers the demands on the work piece adjustment. Tensile tests were conducted on the welded samples. The tests show that the weld can reach a breaking strength in the order of magnitude of the base material.
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