Temporal and spatial determination of solidification rate during pulsed laser beam welding of hot-crack susceptible aluminum alloys by means of high-speed synchrotron X-ray imaging
M. Seibold , K. Schricker , L. Schmidt , D. Diegel , H. Friedmann , P. Hellwig , F. Fröhlich , F. Nagel , P. Kallage , A. Rack , H. Requardt , Y. Chen , J.P. Bergmann
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引用次数: 0
Abstract
Pulsed laser beam welding is primarily used to join thin-walled components. The use of 6xxx group aluminum alloys is characterized by good mechanical properties but these alloys are prone to hot cracking during solidification, i.e., requirements regarding strength and tightness, as increasingly important for electromobility related applications, cannot be fulfilled. The solidification rate has been identified as dominant factor in pulsed conduction welding which can be adjusted by the pulse shape, i.e., by varying the beam power over time for a single pulse.
Pulse shapes with different, linear ramp-down slopes were studied to describe the interaction between beam power and resulting solidification rate for spot welds. Based on rotationally symmetric conditions of the spot welds, the solidification rate can be measured in radial and vertical directions. The welding process of EN AW 6082 alloy was examined by in situ high-speed synchrotron X-ray imaging at the European Synchrotron Radiation Facility (ESRF) for this reason. Frame rates up to 120,000 Hz and subsequent image analysis allowed in-depth analysis of the solidification processes, their dependence on different spatial directions, and the resulting effects on hot crack formation.
利用高速同步辐射 X 射线成像技术确定脉冲激光束焊接易产生热裂纹的铝合金过程中凝固速率的时间和空间参数
脉冲激光束焊接主要用于连接薄壁部件。使用 6xxx 组铝合金具有良好的机械性能,但这些合金在凝固过程中容易产生热裂纹,因此无法满足强度和密封性方面的要求,而这对于电动汽车相关应用来说越来越重要。凝固速率已被确定为脉冲传导焊接中的主导因素,可通过脉冲形状进行调节,即通过改变单个脉冲的束功率随时间的变化来调节凝固速率。根据点焊的旋转对称条件,可在径向和纵向测量凝固速率。为此,我们在欧洲同步辐射设施(ESRF)利用原位高速同步 X 射线成像技术对 EN AW 6082 合金的焊接过程进行了研究。通过高达 120,000 Hz 的帧频和后续图像分析,可以深入分析凝固过程、凝固过程对不同空间方向的依赖性以及由此对热裂纹形成的影响。