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通过无光学接触的皮秒激光焊接实现铝硅酸盐玻璃与6061铝合金的连接

Realization of Joints of Aluminosilicate Glass and 6061 Aluminum Alloy via Picosecond Laser Welding without Optical Contact.

作者信息

Tan Caiwang, Lu Xing, Liu Fuyun, Song Wei, Guo Guanghui, Li Qige, Liu Yuhang, Su Jianhui, Song Xiaoguo

机构信息

State Key Laboratory of Precision Welding & Joining of Materials and Structures, Harbin Institute of Technology, Harbin 150001, China.

School of Materials Engineering, Shandong Institute of Shipbuilding Technology, Weihai 264209, China.

出版信息

Materials (Basel). 2024 Aug 30;17(17):4299. doi: 10.3390/ma17174299.

DOI:10.3390/ma17174299
PMID:39274690
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11395786/
Abstract

To achieve laser direct welding of glass and metal without optical contact is hard, owing to the large difference in thermal expansion and thermal conductivity between glass and metal and an insignificant melting area. In this study, the high-power picosecond pulsed laser was selected to successfully weld the aluminosilicate glass/6061 aluminum alloy with a gap of 35 ± 5 μm between glass and metal. The results show that the molten glass and metal diffuse and mix at the interface. No defects such as microcracks or holes are observed in the diffusion mixing zone. Due to the relatively large gap, the glass collapsed after melting and caulking, resulting in an approximately arc-shaped microcrack between modified glass and unmodified glass or weakly modified glass. The shape of the glass modification zone and thermal accumulation are influenced by the single-pulse energy and linear energy density of the picosecond laser during welding, resulting in variations in the number and size of defects and the shape of the glass modification zone. By reasonably tuning the two factors, the shear strength of the joint reaches 15.98 MPa. The diffusion and mixing at the interface and the mechanical interlocking effect of the glass modification zone are the main reasons for achieving a high shear strength of the joint. This study will provide reference and new ideas for the laser transmission welding of glass and metal in the non-optical contact conditions.

摘要

由于玻璃和金属之间的热膨胀和热导率差异很大,且熔化面积微不足道,因此在没有光学接触的情况下实现玻璃与金属的激光直接焊接很困难。在本研究中,选择了高功率皮秒脉冲激光成功焊接了铝硅酸盐玻璃/6061铝合金,玻璃与金属之间的间隙为35±5μm。结果表明,熔融的玻璃和金属在界面处扩散并混合。在扩散混合区未观察到微裂纹或孔洞等缺陷。由于间隙相对较大,玻璃在熔化和填缝后坍塌,导致改性玻璃与未改性玻璃或弱改性玻璃之间出现近似弧形的微裂纹。焊接过程中,皮秒激光的单脉冲能量和线能量密度会影响玻璃改性区的形状和热积累,从而导致缺陷数量和尺寸以及玻璃改性区形状的变化。通过合理调整这两个因素,接头的剪切强度达到15.98MPa。界面处的扩散和混合以及玻璃改性区的机械联锁效应是接头获得高剪切强度的主要原因。本研究将为非光学接触条件下玻璃与金属的激光透射焊接提供参考和新思路。

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