Litcius/Paper detail

Healing cracks in additively manufactured NiTi shape memory alloys

Jianing Zhu, Zhao-Ying Ding, E. V. Borisov, Xiyu Yao, J.C. Brouwer, Anatoly Popovich, M. J. M. Hermans, Vera Popovich

2023Virtual and Physical Prototyping13 citationsDOIOpen Access PDF

Abstract

The pursuit of enhancing NiTi superelasticity through laser powder bed fusion (L-PBF) and [001] texture creation poses a challenge due to increased susceptibility to hot cracking in the resulting microstructure with columnar grains. This limitation restricts NiTi's application and contributes to material waste. To overcome this, we introduce a pioneering approach: utilising spark plasma sintering (SPS) to heal directional cracks in [001] textured L-PBF NiTi shape memory alloy. Diffusion bonding and oxygen utilisation for Ti2NiOx formation was found to successfully heal the cracks. SPS enhances mechanical properties, superelasticity at higher temperatures, and two-way shape memory strain during thermomechanical cycling. This work provides an alternative solution for healing cracks in L-PBF parts, enabling the sustainable reuse of cracked materials. By implementing SPS, this approach effectively addresses hot cracking limitations, expanding the application potential of L-PBF NiTi parts while improving their functional and mechanical properties.

Topics & Concepts

PseudoelasticityNickel titaniumShape-memory alloyMaterials scienceSpark plasma sinteringMicrostructureMetallurgyCrackingTexture (cosmology)Composite materialMartensiteComputer scienceArtificial intelligenceImage (mathematics)Shape Memory Alloy Transformations