Heat transfer characteristics and enhancement of weld properties in thin stainless steel using synchronous cold air heat sink assisted laser welding

IF 4.6 2区 物理与天体物理 Q1 OPTICS Optics and Laser Technology Pub Date : 2024-10-20 DOI:10.1016/j.optlastec.2024.111973
Zuguo Liu , Dabin Zhang , Xiangzhong Jin , Chaojing Yu , Zhengwen Zhang
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Abstract

In this paper, a new type of hybrid laser welding is introduced to weld SUS301 stainless steel. The influence mechanism of synchronous cold air heat sink process on weld pool thermodynamics and weld microstructure during laser welding of SUS301L stainless steel sheet was analyzed by experiment and simulation. Firstly, the dynamic characteristics of the molten pool were analyzed using high-speed camera technology. The results indicate that applying heat sink can significantly reduce the characteristic length of molten pool. When the heat sink flow rate is 200 ml, the length of molten pool increases by 60.6 % as the heat sink distance increases from 5 mm to 20 mm. Furthermore, a simulation model of SHSLW is established. The simulation results illustrate that cold air heat sink will form a rapid cooling zone at the tail of weld pool, which leads to the disappearance of weld comet characteristics, and improves the temperature field at the tail of weld pool, and the refinement mechanism of heat sink on microstructure was described based on the theory of constitutional supercooling (CS). This new understanding provides an opportunity to make better use of heat sink to control grain structure, and in turn to improve the mechanical properties of the welds, which is also verified by the test results of the properties of the welds. EBSD analysis shows that after adding heat sink, the average size of small grains was 8.43 μm, accounting for 74 % of the entire grain area, the proportion of low angle grain boundaries decreased to 59.1 %. Compared with LW, the longitudinal and transverse Vickers hardness values of weld fusion zone under SHSLW are increased by 4.17 % and 7.70 % respectively, the tensile strength and maximum ductility increased by 12.03 % and 21.37 %, respectively. It can be concluded that the application of heat sink is an effective way to improve the tensile strength and toughness of the welds by laser welding of metals.
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同步冷空气散热器辅助激光焊接的传热特性和薄不锈钢焊缝性能的提高
本文介绍了一种用于 SUS301 不锈钢焊接的新型混合激光焊接。通过实验和模拟分析了 SUS301L 不锈钢板激光焊接过程中同步冷风散热过程对熔池热力学和焊缝显微组织的影响机理。首先,利用高速摄像技术分析了熔池的动态特性。结果表明,使用散热器可以显著减少熔池的特征长度。当散热器流量为 200 ml 时,当散热器距离从 5 mm 增加到 20 mm 时,熔池长度增加了 60.6%。此外,还建立了 SHSLW 的模拟模型。模拟结果表明,冷空气散热器会在焊池尾部形成快速冷却区,从而导致焊接彗星特征的消失,并改善了焊池尾部的温度场。这一新的认识为更好地利用散热来控制晶粒结构,进而改善焊缝的机械性能提供了契机,焊缝的性能测试结果也验证了这一点。EBSD 分析表明,加入散热器后,小晶粒的平均尺寸为 8.43 μm,占整个晶粒面积的 74%,低角度晶界的比例下降到 59.1%。与 LW 相比,SHSLW 焊接熔合区的纵向和横向维氏硬度值分别提高了 4.17 % 和 7.70 %,抗拉强度和最大延展性分别提高了 12.03 % 和 21.37 %。由此可以得出结论,应用散热器是提高金属激光焊接焊缝抗拉强度和韧性的有效方法。
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来源期刊
CiteScore
8.50
自引率
10.00%
发文量
1060
审稿时长
3.4 months
期刊介绍: Optics & Laser Technology aims to provide a vehicle for the publication of a broad range of high quality research and review papers in those fields of scientific and engineering research appertaining to the development and application of the technology of optics and lasers. Papers describing original work in these areas are submitted to rigorous refereeing prior to acceptance for publication. The scope of Optics & Laser Technology encompasses, but is not restricted to, the following areas: •development in all types of lasers •developments in optoelectronic devices and photonics •developments in new photonics and optical concepts •developments in conventional optics, optical instruments and components •techniques of optical metrology, including interferometry and optical fibre sensors •LIDAR and other non-contact optical measurement techniques, including optical methods in heat and fluid flow •applications of lasers to materials processing, optical NDT display (including holography) and optical communication •research and development in the field of laser safety including studies of hazards resulting from the applications of lasers (laser safety, hazards of laser fume) •developments in optical computing and optical information processing •developments in new optical materials •developments in new optical characterization methods and techniques •developments in quantum optics •developments in light assisted micro and nanofabrication methods and techniques •developments in nanophotonics and biophotonics •developments in imaging processing and systems
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