Litcius/Paper detail

Effect of Fe addition on the microstructure, transformation behaviour and superelasticity of NiTi alloys fabricated by laser powder bed fusion

Rui Xi, Hao Jiang, Guichuan Li, Zhihui Zhang, Guoqun Zhao, Kim Vanmeensel, S. Kustov, Jan Van Humbeeck, Xiebin Wang

2022Virtual and Physical Prototyping33 citationsDOIOpen Access PDF

Abstract

NiTi-Fe ternary shape memory alloys were produced by laser powder bed fusion (L-PBF) using the pre-alloyed NiTi and elemental Fe powders. A large process window exists to fabricate dense NiTiFe 0.3 and NiTiFe 0.5 alloys, while severe cracks occur in the NiTiFe 2 alloy. The cracking susceptibility is studied through thermodynamic analysis. Fe is mainly dissolved in the NiTi matrix, which is mainly due to the low Fe addition and rapid cooling associated with L-PBF process. The martensite transformation temperatures (MTTs) decrease monotonously with the increase of scanning speed, the decrease of laser power, or the increase of Fe addition, providing a feasible approach to tailoring the MTTs. Due to the decrease of the MTTs, the NiTiFe 0.3 and NiTiFe 0.5 alloys show good superelasticity, e.g. the NiTiFe 0.3 alloy shows a superelastic recoverable strain of 5.2% (pre-strain of 6%). This work suggests that L-PBF is a potential method to in-situ synthesise ternary NiTiFe alloys.

Topics & Concepts

PseudoelasticityMaterials scienceNickel titaniumShape-memory alloyTernary operationMicrostructureMetallurgyAlloyFusionMartensiteDiffusionless transformationLinguisticsPhilosophyProgramming languageComputer scienceShape Memory Alloy TransformationsAdditive Manufacturing Materials and ProcessesHigh Entropy Alloys Studies