Microstructural control of additively manufactured Ti-6Al-4V

The game-changing design freedom offered by Additive Manufacturing (AM) has opened new doors for producing customized products previously unattainable through conventional manufacturing techniques. LPBF, among various AM methods, stands out as the most well-known technique for the production of metallic parts, with a primary objective of producing fully dense parts with minimal porosity. However, the unique properties of the Ti-6Al-4V alloy, such as its martensitic microstructure, pose challenges in achieving the desired balance of strength and ductility.

Researchers from EPFL and PSI  have unveiled an effective strategy for controlling the microstructure of additively manufactured Ti-6Al-4V. The implementation of in-situ Selective Laser Heat Treatment (SLHT) has been designed and tested on various geometries, using a combination of numerical simulations and operando X-ray diffraction measurements. This innovative approach allows for precise control of local microstructural changes within a short time scale, opening avenues for tailored microstructures in additively manufactured parts.

The implications of this research are profound for the field of additive manufacturing. The ability to control microstructure at a local scale opens doors for creating intricate 3D architected (or composite-like) microstructures in the as-built state. This not only addresses challenges associated with the Ti-6Al-4V alloy but also contributes to a deeper understanding of martensite decomposition in LPBF processes.

The X-ray diffraction experiments were performed at the MicroXAS and MS beam line of the Swiss Light Source. This work was supported by the Swiss National Science Foundation.