Simultaneously enhancing strength and toughness of heat-treated near β titanium alloy fabricated by laser-directed energy deposition

Abstract

In order to achieve strength-plasticity matching and improve the fracture toughness of near β titanium alloy Ti55531 fabricated by laser-directed energy deposition (LDED), the heat-treated microstructure and the corresponding tensile properties and fracture toughness were investigated. Microstructure evolution during heat treatment and deformation behavior during mechanical testing were analyzed. The results showed that the primary β grains were approximately equiaxed with weak texture in LDED-built Ti55531. After subcritical solution and single/double aging (SS-SA and SS-DA) treatment, the continuous grain boundary α phases appeared, and the intercrystalline α phase was very fine. These make the strength high and the elongation and fracture toughness very poor because the cracks easily initiate and propagate along grain boundaries. In contrast, the treatment of supercritical β annealing and aging (SBA-A and SBCA-A) presented the Widmanstätten grain boundaries and zigzag grain boundaries in LDED-built Ti55531, respectively. Because these grain boundaries can effectively inhibit crack propagation, the elongation and fracture toughness were significantly improved. Especially for SBA-A treatment, it presents the optimal strength-plasticity matching with a or the strength of 1045 ± 12 MPa and elongation of 12.0 ± 1.2% and excellent fracture toughness of 81.7 ± 1.1 MPa m1/2.