Litcius/Paper detail

Stabilising mechanism of cathode jet and droplet transfer in hybrid-laser–GMAW-based directed energy deposition of titanium alloy

Xiao Xiao, Chi Zhang, Dongsheng Wu, Hisaya Komen, Junfeng Gou, Yongkang Zhang, Keke Zhang, Shigeaki Uchida, Manabu Tanaka

2024Virtual and Physical Prototyping8 citationsDOIOpen Access PDF

Abstract

A hybrid laser–GMAW-based directed energy deposition (DED) was developed to stabilise the cathode jet and droplet transfer in DED of Ti alloy. High-speed photography, spectroscopic diagnostic, theoretical calculation, and numerical simulation were employed to investigate the stabilising mechanisms. At a high laser energy density, the highest temperature of the molten pool was located in the laser-irradiated zone, generating a stable cathode jet. Ti atoms easily ionised into Ti ions at high temperatures (>8200 K); therefore, the cathode jet was primarily composed of Ti ions. The laser-induced metal vapour attracted and contracted the arc, resulting in an increase in the arc temperature, and strong evaporation near the wire during the peak-current stage. Therefore, the distribution areas of Ti I and Ti II were enlarged. Introducing the laser inhibited the obstructive effect of the cathode jet on the droplet, thereby enhancing the stability of droplet transfer.

Topics & Concepts

CathodeMaterials scienceJet (fluid)LaserEvaporationDeposition (geology)Vacuum arcTitaniumAlloyGas metal arc weldingComposite materialMetallurgyAnalytical Chemistry (journal)OpticsChemistryMechanicsThermodynamicsWeldingHeat-affected zoneBiologySedimentPhysicsPaleontologyPhysical chemistryChromatographyAdditive Manufacturing Materials and ProcessesWelding Techniques and Residual StressesLaser-induced spectroscopy and plasma