Effect of Laser Heat Input on the Microstructures and Low-Cycle Fatigue Properties of Ti60 Laser Welded Joints

In this paper, the effects of laser heat input on the microstructures, tensile strength, and fatigue properties of Ti60 laser welded joints were investigated. The results show that with the increase in laser heat input, the macro morphology of the weld zone (WZ) changes from the Y-type to X-type. In the Y-type WZ, the porosity defects are almost eliminated. In contrast, there are a lot of porosity defects in the lower part of the X-type WZ. The microstructure of the base metal (BM) comprises equiaxed alpha phases, and beta phases are mainly distributed at the boundaries of alpha phases. The heat-affected zone (HAZ) is comprised of alpha phases and acicular alpha ' phases, while the WZ mainly contains acicular alpha ' phases. With the increase in laser heat input, the quantity of the alpha phase gradually decreases and the acicular alpha ' phase gradually increases in the HAZ, and the size of the acicular alpha ' phase in the WZ gradually decreases. Due to the different microstructures, the hardness of BM is lower than the HAZ and WZ under different laser heat input conditions. In the tensile tests and low-cycle fatigue tests, the welded joints are fractured in BM. The porosity defects do not have decisive effects on the tensile and low-cycle fatigue properties of Ti60 laser welded joints.