Short Circuiting Transfer, Formation, and Microstructure of Ti-6Al-4V Alloy by External Longitudinal Magnetic Field Hybrid Metal Inert Gas Welding Additive Manufacturing

Abstract: In this work, the external longitudinal magnetic field hybrid metal inert gas welding (M-MIG) additive manufacturing method is employed to produce the Ti-6Al-4V alloy part. The effect of process parameters on the droplet transfer formation and microstructure of the part was studied by a high-speed camera, optical microscope, and electron backscattered diffraction. The results showed that a typical short-circuiting transfer was obtained with the wire feeding speed of 2 m/min–4 m/min. An external longitudinal ma… Show more

“…Shi et al [12] investigate the short-circuiting transfer, formation, and microstructure of Ti-6Al-4V alloy by external longitudinal magnetic field hybrid metal inert gas welding additive manufacturing. Cao et al [13] analyze microstructure evolution of the Ti-46Al-8Nb-2.5V alloy during hot compression and subsequent annealing at 900 • C. Lu et al [14,15] investigate the mechanical properties and microstructure of spiral tubes and actuators for controlled extension and retraction (STACERs) fabricated with beryllium bronze strips and Co40NiCrMo alloy.…”

Special Issue: “Advanced Light Metal and Alloys: Preparation, Characterization, and Applications”

“…Shi et al [12] investigate the short-circuiting transfer, formation, and microstructure of Ti-6Al-4V alloy by external longitudinal magnetic field hybrid metal inert gas welding additive manufacturing. Cao et al [13] analyze microstructure evolution of the Ti-46Al-8Nb-2.5V alloy during hot compression and subsequent annealing at 900 • C. Lu et al [14,15] investigate the mechanical properties and microstructure of spiral tubes and actuators for controlled extension and retraction (STACERs) fabricated with beryllium bronze strips and Co40NiCrMo alloy.…”

Special Issue: “Advanced Light Metal and Alloys: Preparation, Characterization, and Applications”

Numerical and experimental study of TIG welding arc in high frequency longitudinal magnetic field

Enhancing wire arc additive manufacturing in vibrational environments with longitudinal magnetic fields