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The International Journal of Advanced Manufacturing Technology
Published in: The International Journal of Advanced Manufacturing Technology 1-2/2022

30-10-2021 | ORIGINAL ARTICLE

Fabrication of multi-functional Ni–Ti alloys by laser powder bed fusion

Authors: Jianran Lv, Hongyao Shen, Jianzhong Fu

Published in: The International Journal of Advanced Manufacturing Technology | Issue 1-2/2022

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Abstract

Ni–Ti alloys with multiple transformation temperatures for a single component can be called multi-functional Ni–Ti alloys. Multi-functional Ni–Ti alloys can increase the flexibility of designing complex systems and have broad application prospects. Existing research mainly focuses on manufacturing multi-functional Ni–Ti alloys through welding or changing the local Ni/Ti ratio. However, the above-mentioned methods have problems such as the low connection strength of the welded part, difficulty of precisely controlling the Ni–Ti ratio, and poor design flexibility. In this paper, laser powder bed fusion (LPBF) was used to successfully fabricate multi-functional Ni–Ti alloys. Ni-rich (Ni53.4-Ti46.6 (at.%)) powders and Ti–rich (Ni46.4-Ti53.6 (at.%)) powders were prepared. The Ni-rich powder was first used to fabricate super-elasticity (SE) parts with a high relative density. The Ti–rich powder was then used to manufacture shape memory effect (SME) parts with different process parameters based on the SE parts. These integrated components were processed into dog-bone shapes and subjected to tensile tests. The sample that had the highest ultimate tensile strength while manufactured at a relatively low energy density was selected for further analysis. The properties of the sample, such as the microstructure and transformation temperature, were analysed through a series of tests. The results confirm that LPBF is a suitable method to fabricate multi-functional Ni–Ti alloys.
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Literature
1.
Otsuka K, Ren X (2005) Physical metallurgy of Ti–Ni-based shape memory alloys[J]. Prog Mater Sci 50(5):511–678CrossRef
2.
Yamauchi K, Ohkata I, Tsuchiya K, Miyazaki S (2011) Shape memory and superelastic alloys: Technologies and applications
3.
Mohd Jani J, Leary M, Subic A, Gibson MA (2014) A review of shape memory alloy research, applications and opportunities Mater. Des 56:1078–1113
4.
Elahinia M, Hashemi M, Tabesh M, Bhaduri SB (2012) Manufacturing and processing of NiTi implants: a review Prog. Mater Sci 57:911–946
5.
Duerig T, Pelton A, Stöckel D (1999) An overview of nitinol medical applications Mater. Sci Eng A 15:149–160CrossRef
6.
Fernandes F, Oliveira JP, Machado A et al (2014) XRD study of NiTi endodontic files using synchrotron radiation[J]. J Mater Eng Perform 23(7):2477–2481
7.
McDonald Schetky L (1991) Shape memory alloy applications in space systems. Mater Des 12:29–32CrossRef
8.
Stoeckel D (1990) Shape memory actuators for automotive applications. Mater Des 11:302–307CrossRef
9.
Mehrpouya M, Gisario A, Broggiato GB et al (2019) Effect of welding parameters on functionality of dissimilar laser-welded NiTi superelastic (SE) to shape memory effect (SME) wires[J]. Int J Adv Manuf Technol 103(1):1593–1601CrossRef
10.
Zeng Z, Yang M, Oliveira J P, et al (2016) Laser welding of NiTi shape memory alloy wires and tubes for multi-functional design applications[J]. Smart Materials and Structures 25(8)
11.
Zamani N (2017) Fabrication and model based position estimation of novel laser processed shape memory alloy actuator with an embedded strain gauge sensor[J]. Sensors Actuators A Phys 263:234–245CrossRef
12.
Engeberg ED, Dilibal S, Vatani M, Choi JW, Lavery J (2015) Anthropomorphic finger antagonistically actuated by SMA plates. Bioinspir Biomim 10(5):056002CrossRef
13.
Mehrpouya M, Gisario A, Elahinia M (2018) Laser welding of NiTi shape memory alloy: a review. J Manuf Process 31:162–186CrossRef
14.
Shariat BS, Meng Q, Mahmud AS et al (2017) Functionally graded shape memory alloys: design, fabrication and experimental evaluation[J]. Mater Des 124(JUN):225–237CrossRef
15.
Tam B, Khan M, Zhou Y (2011) Mechanical and functional properties of laser-welded Ti-55.8 Wt Pct Ni nitinol wires Metall. Mater Trans A 42:2166–2175CrossRef
16.
Falvo A, Furgiuele FM, Maletta C (2005) Laser welding of a NiTi alloy: mechanical and shape memory behaviour Mater. Sci Eng A 412:235–240CrossRef
17.
Stoeckel D (2001) Forming of nitinol–a challenge[J]. New developments in forging Technolog 119–134
18.
Wu SK, Lin HC, Chen CC (1999) A study on the machinability of a Ti49 6Ni50 4 shape memory alloy[J]. Mater Lett 40(1):27–32CrossRef
19.
Biermann D, Kahleyss F, Krebs E et al (2011) A study on micro-machining technology for the machining of NiTi: five-axis micro-milling and micro deep-hole drilling[J]. J Mater Eng Perform 20(4–5):745–751CrossRef
20.
Bellouard Y (2008) Shape memory alloys for microsystems: a review from a material research perspective[J]. Mater Sci Eng, A 481:582–589CrossRef
21.
Mehrpouya M, Shahedin AM, Daood Salman Dawood S, Kamal Ariffin A (2017) An investigation on the optimum machinability of NiTi based shape memory alloy. Mater Manuf Process 32(13):1497–1504CrossRef
22.
Bormann T, Schumacher R, Müller B et al (2012) Tailoring selective laser melting process parameters for NiTi implants[J]. J Mater Eng Perform 21(12):2519–2524CrossRef
23.
Wang X, Kustov S, Van Humbeeck J (2018) A short review on the microstructure, transformation behavior and functional properties of NiTi shape memory alloys fabricated by selective laser melting[J]. Materials 11(9):1683CrossRef
24.
Dadbakhsh S, Speirs M, Kruth JP et al (2014) Effect of SLM parameters on transformation temperatures of shape memory nickel titanium parts[J]. Adv Eng Mater 16(9):1140–1146CrossRef
25.
Haberland C, Elahinia M, Walker JM et al (2014) On the development of high quality NiTi shape memory and pseudoelastic parts by additive manufacturing[J]. Smart Mater Struct 23(10):104002CrossRef
26.
Bormann T, Müller B, Schinhammer M et al (2014) Microstructure of selective laser melted nickel–titanium[J]. Mater Charact 94:189–202CrossRef
27.
Khoo ZX, Liu Y, An J et al (2018) A review of selective laser melted NiTi shape memory alloy[J]. Materials 11(4):519CrossRef
28.
Elahinia M, Moghaddam NS, Andani MT et al (2016) Fabrication of NiTi through additive manufacturing: a review[J]. Prog Mater Sci 83:630–663CrossRef
29.
Frenzel J, George EP, Dlouhy A et al (2010) Influence of Ni on martensitic phase transformations in NiTi shape memory alloys[J]. Acta Mater 58(9):3444–3458CrossRef
Metadata
Title
Fabrication of multi-functional Ni–Ti alloys by laser powder bed fusion
Authors
Jianran Lv
Hongyao Shen
Jianzhong Fu
Publication date
30-10-2021
Publisher
Springer London
Published in
The International Journal of Advanced Manufacturing Technology / Issue 1-2/2022
Print ISSN: 0268-3768
Electronic ISSN: 1433-3015
DOI
https://doi.org/10.1007/s00170-021-08039-6

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