Structure, martensitic transformations and mechanical behaviour of NiTi shape memory alloy produced by wire arc additive manufacturing

The gas metal arc welding (GMAW) based wire arc additive manufacturing (WAAM) process has been employed to deposit 5-layered NiTi alloy on the Titanium substrate using Ni50.9Ti49.1 wire as the feedstock. The heterogeneity of the piled up layers has been evaluated in terms of the variation in microst...

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Bibliographic Details
Published in:Journal of alloys and compounds 2021-01, Vol.851, p.156851, Article 156851
Main Authors: Resnina, N., Palani, I.A., Belyaev, S., Prabu, S.S. Mani, Liulchak, P., Karaseva, U., Manikandan, M., Jayachandran, S., Bryukhanova, V., Sahu, Anshu, Bikbaev, R.
Format: Article
Language:English
Subjects:
Additive manufacturing
Arc deposition
Chemical composition
Deformation effects
Gas metal arc welding
Grains
Heterogeneity
Intermetallic compounds
Martensite
Martensitic transformation
Martensitic transformations
Mechanical properties
Nickel base alloys
Nickel compounds
Nickel titanides
NiTi
Raw materials
Room temperature
Shape effects
Shape memory alloys
Solidification
Substrates
Temperature
Titanium compounds
Transformation temperature
Wire
Wire arc additive manufacturing
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Summary:The gas metal arc welding (GMAW) based wire arc additive manufacturing (WAAM) process has been employed to deposit 5-layered NiTi alloy on the Titanium substrate using Ni50.9Ti49.1 wire as the feedstock. The heterogeneity of the piled up layers has been evaluated in terms of the variation in microstructure, composition and phases present. The melting of the Ti substrate under the first layer led to a substantial increase in Ti concentration in the melt during the deposition of the first layer and facilitated the formation of Ti-rich NiTi/Ti2Ni mixture during the solidification. In the 2nd – 5th layers columnar grains appeared in the inner space, whereas equiaxed grains formed on the top of the layers. The chemical composition of the 1st – 3rd layers differed from the nominal composition of the feedstock wire i.e. the layers in proximity of the substrate had lesser Ni concentration. As the result, the temperatures of the B2 ↔ B19’ martensitic transformation were different across the layers and the start temperature of the forward transformation changed from 73 °C (1st layer) to −16 °C (5th layer). Using the EDX and calorimetric data, the Ni distribution in each layer was determined and its influence on the martensitic transformation temperatures was discussed in detail. The difference in Ni concentration has made various layers to be present in different states (martensite or austenite) at room temperature. In this case, the layers (2–4) were deformed by different mechanisms during tension at room temperature. The deformation of the layers by reversible mechanisms was confirmed by the shape memory effect on heating of the pre-deformed NiTi sample produced by WAAM. •5-Layered NiTi alloy sample was deposited by gas metal arc welding on Ti substrate.•Structure, martensitic transformations and chemical composition was studied in layers.•Melting of Ti substrate under the 1st layer changed composition of the 1st–3rd layers.•B2 ↔ B19′ martensitic transformation occurred in all layers at different temperatures.•During tension different layers were deformed by various reversible mechanisms.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2020.156851