Litcius/Paper detail

Microstructure and mechanical properties of laser metal deposited Ti6Al4V alloy with near equiaxed β grain structure

Yuke Liu, Fubin Wang, De Xu, Jiandong Wang, Fengchun Jiang, Mehrdad Zarinejad, Y.X. Tong

2022Journal of Materials Research and Technology38 citationsDOIOpen Access PDF

Abstract

Ti6Al4V alloy produced by additive manufacturing are generally characterized by their columnar β grain structure and the resulting anisotropy in mechanical properties as a critical challenge in engineering applications. In the present work, a near equiaxed β grain structure is obtained in the Ti6Al4V alloy thin-wall specimens produced by laser metal deposition through tailoring laser power and interlayer dwell time. Microstructure, texture, and mechanical properties of the as-deposited alloys are investigated as functions of processing parameters. When the interlayer dwell time is fixed at 10 s, the columnar β grain structure changes to a near equiaxed morphology, and the grain width (size) decreases with increasing laser power from 1200 W to 1500 W. Recrystallization of the previously deposited layers during processing is suggested to be responsible for the formation of the near-equiaxed β grain structure. All the as-deposited alloys consist of a weakly textured α phase and the β phase at room temperature. The as-deposited alloys with the near-equiaxed β grains show superior mechanical properties, as evidenced by large elongation values up to 14%.

Topics & Concepts

Equiaxed crystalsMaterials scienceMicrostructureTitanium alloyMetallurgyAlloyTexture (cosmology)Recrystallization (geology)Laser power scalingGrain growthGrain sizeComposite materialLaserOpticsImage (mathematics)Artificial intelligenceBiologyPaleontologyComputer sciencePhysicsAdditive Manufacturing Materials and ProcessesTitanium Alloys Microstructure and PropertiesWelding Techniques and Residual Stresses