Microstructure Analysis and Fatigue Behavior of Laser Beam Welding 2060-T8/2099-T83 Aluminum–Lithium Alloys

Wen-jie Cheng, Hongbing Liu, Tan Jie, Zhishui Yu, Q. Shu
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引用次数: 2

Abstract

In this paper, the microstructure analysis and performance research of dual laser beam welded 2060-T8/2099-T83 aluminum–lithium alloys were carried out. First, the macroscopic morphology and microstructure characteristics of T-joint aluminum–lithium alloys under different welding conditions were observed. Then the effect of welding parameters and pore defects on tensile and fatigue properties of the weld were carried out and the experimental results were analyzed. It was found that the weld heat input has a significant influence on the penetration of the welded aluminum–lithium alloys joint. When the laser power is too high, the weld will absorb more laser energy and the increase in the evaporation of magnesium will further increase the weld penetration. When the penetration depth increases, the transverse tensile strength tends to decrease. There is no obvious rule for the effect of pore defects on the tensile strength of the weld. At the same time, the heat input of the weld is inversely proportional to the porosity. When the weld heat input increases from 19.41 to 23.33 kJ/m, the porosity decreases from 5.35% to 2.08%. During the fatigue test, it was confirmed that the existence of pore defects would reduce the fatigue life of the weld. In addition, from the analysis of the fatigue fracture morphology it can be found that when the porosity is low, the weld toe is the main source of fatigue cracks. The crack propagation zone shows a typical beach pattern and the final fracture of the base metal presents the characteristics of a brittle fracture. While, when the porosity is high, the crack source is mainly located at the pore defects. T-joint fractures from the inside of the weld and the fracture in the final fracture zone have obvious pore defects and dimples.
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2060-T8/2099-T83铝锂合金激光焊接组织分析及疲劳行为
本文对2060-T8/2099-T83双激光束焊接铝锂合金进行了显微组织分析和性能研究。首先,观察了不同焊接条件下t型连接铝锂合金的宏观形貌和显微组织特征。研究了焊接参数和气孔缺陷对焊缝拉伸和疲劳性能的影响,并对试验结果进行了分析。结果表明,焊接热输入对铝锂合金焊接接头的熔透有显著影响。当激光功率过高时,焊缝会吸收更多的激光能量,镁的蒸发增加会进一步增加焊缝的熔透。随着侵彻深度的增加,横向抗拉强度有减小的趋势。气孔缺陷对焊缝抗拉强度的影响没有明显规律。同时,焊缝的热输入与气孔率成反比。当焊缝热输入从19.41 kJ/m增加到23.33 kJ/m时,气孔率从5.35%降低到2.08%。在疲劳试验中,证实了气孔缺陷的存在会降低焊缝的疲劳寿命。此外,从疲劳断口形貌分析可以发现,当孔隙率较低时,焊缝趾部是疲劳裂纹的主要来源。裂纹扩展区呈典型的滩状,母材最终断裂呈现脆性断裂特征。而当孔隙率较高时,裂纹源主要位于孔隙缺陷处。t形接头焊缝内部断口和最终断口处均有明显的孔洞缺陷和韧窝。
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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