nach oben

Shape Memory and Superelasticity

13.03.2024 | ORIGINAL RESEARCH ARTICLE

Shape Memory NiTiHf Machined Helical Springs: Balancing Displacement and Force Output for Actuation

verfasst von: P. E. Caltagirone, P. Naghipour Ghezeljeh, O. Benafan

Erschienen in: Shape Memory and Superelasticity

Einloggen, um Zugang zu erhalten

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

NiTiHf shape memory alloys are of high interest to the scientific community due to their high strength, excellent stability, and high transformation temperature. While many geometrical forms can be manufactured using NiTiHf, traditional springs are difficult to manufacture due to the material’s limited workability to wire form. Machined springs offer a great alternative to achieve a spring form using NiTiHf. Machined springs were fabricated from Ni_50.3Ti_29.7Hf₂₀ (at.%) at spring rates of 87.6, 175.1, and 262.7 N mm⁻¹. To manufacture the springs, a solid rod was cored out and a helix was machined into the tube. For each spring rate, two spring types were made: single–start and dual–start. The springs were subjected to constant-force thermal cycling tests, isothermal tests, and constant displacement thermal cycling tests. Computational modeling was used to determine the stress profiles within the springs. The NiTiHf springs showed very good stability, with less than 0.5 mm of change between the nineteenth and twentieth cycles. The machined springs were capable of actuation displacements up to 15.5 mm, over 50% extension from the original flexure length, superelastic stresses greater than 2.4 GPa, and tensile blocking forces ranging from 750 to more than 2000 N.

Barros CDDR, Gomes JADCP (2021) Influence of Cu addition and autoclave sterilization on corrosion resistance and biocompatibility of NiTi for orthodontics applications. Mater Res. https://doi.org/10.1590/1980-5373-mr-2020-0369CrossRef

Gil F, Planell J (1999) Effect of copper addition on the superelastic behavior of Ni-Ti shape memory alloys for orthodontic applications. J Biomed Mater Res 48(5):682–688CrossRefPubMed

Iijima M, Ohno H, Kawashima I, Endo K, Mizoguchi I (2002) Mechanical behavior at different temperatures and stresses for superelastic nickel–titanium orthodontic wires having different transformation temperatures. Dent Mater 18(1):88–93CrossRefPubMed

McCoy B (1996) Comparison of compositions and differential scanning calorimetric analyses of the new copper-Ni-Ti wires with existing Ni-Ti orthodontic wires, Thesis, available from The Ohio State University. Thesis completed 1996

Pun DK, Berzins DW (2008) Corrosion behavior of shape memory, superelastic, and nonsuperelastic nickel-titanium-based orthodontic wires at various temperatures. Dent Mater 24(2):221–227CrossRefPubMed

Takagi T, Sutou Y, Kainuma R, Yamauchi K, Ishida K (2006) Effect of prestrain on martensitic transformation in a Ti_46.4Ni_47.6Nb_6.0 superelastic alloy and its application to medical stents. J Biomed Mater Res Part B 76(1):179–183CrossRef

Aiyer A, Russell NA, Pelletier MH, Myerson M, Walsh WR (2016) The Impact of nitinol staples on the compressive forces, contact area, and mechanical properties in comparison to a claw plate and crossed screws for the first tarsometatarsal arthrodesis. Foot Ankle Spec 9(3):232–240CrossRefPubMed

Duerig T, Pelton A, Stöckel D (1999) An overview of nitinol medical applications. Mater Sci Eng A 273–275:149–160CrossRef

Pelton AR, Duerig TW, Berg B, Hodgson D, Mertmann M, Mitchell M, Proft J, Wu M, Yang J (2005) Nitinol medical devices. Adv Mater Process 163:13

10.

Szold A (2006) Nitinol: Shape-memory and super-elastic materials in surgery. Surg Endosc Other Interv Tech 20(9):1493–1496CrossRef

11.

Fezi K, Bigelow G, Benafan O (2020) Forging and hot rolling of high temperature actuator alloy NiTi₂0Hf. International Materials Applications & Technologies (IMAT), Cleveland, OH, Sept 2020

12.

Wojcik CC (2009) Properties and heat treatment of high transition temperature Ni-Ti-Hf alloys. J Mater Eng Perf 18(5):511–516CrossRef

13.

Akgul O, Kockar B (2023) The effect of rolling process on the actuation fatigue behavior of Ni₅₀Ti₂₅Hf₂₅ high temperature shape memory alloy. Shape Mem Superelasticity 3:1

14.

Johnson AD, Martynov VV, Minners RS (1995) Sputter deposition of high transition temperature Ti-Ni-Hf alloy thin films. J Phys IV 5(8):83–88

15.

Sanjabi S, Cao YZ, Barber ZH (2005) Multi-target sputter deposition of Ni₅₀Ti₅₀−XHfx shape memory thin films for high temperature microactuator application. Sens Actuators A Phys 121(2):543–548CrossRef

16.

Bigelow G, Benafan O, Garg A (2019) Towards the determination of shape set parameters for Ni_50.3Ti_29.7Hf₂₀ shape memory alloy. The ASME 2019 conference on smart materials, adaptive structures and intelligent systems (SMASIS), Louisville, KY, Sept 2019

17.

Canadinc D, Trehern W, Ozcan H, Hayrettin C, Karakoc O, Karaman I, Sun F, Chaudhry Z (2017) On the deformation response and cyclic stability of Ni₅₀Ti₃₅Hf₁₅ high temperature shape memory alloy wires. Scr Mater 135:92–96CrossRef

18.

Ley NA, Wheeler RW, Benafan O, Young ML (2019) Characterization of thermomechanically processed high-temperature Ni-lean NiTi–20 at.% Hf shape memory wires. Shape Mem Superelasticity 5(4):476–485CrossRefADS

19.

Young AW, Wheeler RW, Ley NA, Benafan O, Young ML (2019) Microstructural and thermomechanical comparison of Ni-rich and Ni-lean NiTi-20 at.% Hf high temperature shape memory alloy wires. Shape Mem Superelasticity 5(4):397–406CrossRefADS

20.

Gantz F, Wall MT, Young ML, Forbes DJ (2022) Extending fatigue life of NiTiHf shape memory alloy wires through rapid thermal annealing. Shape Mem Superelasticity 8(4):439–451CrossRefADS

21.

Elahinia M, Shayesteh Moghaddam N, Amerinatanzi A, Saedi S, Toker GP, Karaca H, Bigelow GS, Benafan O (2018) Additive manufacturing of NiTiHf high temperature shape memory alloy. Scr Mater 145:90–94CrossRef

22.

Nematollahi M, Toker G, Saghaian SE, Salazar J, Mahtabi M, Benafan O, Karaca H, Elahinia M (2019) Additive manufacturing of Ni-rich NiTiHf20: Manufacturability, composition, density, and transformation behavior. Shape Mem Superelasticity 5(1):113–124CrossRef

23.

Toker GP, Nematollahi M, Saghaian SE, Baghbaderani KS, Benafan O, Elahinia M, Karaca HE (2020) Shape memory behavior of NiTiHf alloys fabricated by selective laser melting. Scr Mater 178:361–365CrossRef

24.

Nematollahi M (2022) Tailoring the properties of NiTi(Hf) alloys by laser powder bed fusion. PhD Thesis, available from University of Toledo. Thesis completed 2022

25.

Benafan O, Gaydosh DJ (2020) Machined helical springs from NiTiHf shape memory alloy. Smart Mater Struct 29(12):125001CrossRefADS

26.

Wang J, Huang B, Gu X, Zhu J, Zhang W (2022) Actuation performance of machined helical springs from NiTi shape memory alloy. Int J Mech Sci 236:107744CrossRef

27.

Chen T, Zhang Y, Qiu S, Jiang J, Zhang Q, Zhang X (2022) Experiments and modeling of machined spring rotary actuators with shape memory alloys. Mater 15(19):6674CrossRef

28.

Saleeb AF, Padula SA, Kumar A (2011) A multi-axial, multimechanism based constitutive model for the comprehensive representation of the evolutionary response of SMAs under general thermomechanical loading conditions. Int J Plast 27(5):655–687CrossRef

29.

Saleeb AF, Dhakal B, Hosseini MS, Padula SA II (2013) Large scale simulation of NiTi helical spring actuators under repeated thermomechanical cycles. Smart Mater Struct 22(9):094006CrossRefADS

30.

Benafan O, Bigelow GS, Garg A, Noebe RD, Gaydosh DJ, Rogers RB (2021) Processing and scalability of NiTiHf high-temperature shape memory alloys. Shape Mem Superelasticity 7(1):109–165CrossRefADS

31.

ASTM International, E3097-23: standard test method for uniaxial constant force thermal cycling of shape memory alloys, 2023

32.

Liesecke G (1933) Berechnung zylindrischer Schrauben-federn mit rechteckigem Drahtquerschnit. Z Ver Dtsch Ing 77:425–426

33.

Göhner O (1932) Die Berechnung zylindrischer Schraubenfedern. Z Ver Dtsch Ing 76:269–272

34.

Arnold SM, Saleeb AF, Wilt TE (1995) A modeling investigation of thermal and strain induced recovery and nonlinear hardening in potential based viscoplasticity. J Eng Mater Technol 117(2):157–167CrossRef

35.

Saleeb A, Arnold S, Castelli M, Wilt T, Graf W (2001) A general hereditary multimechanism-based deformation model with application to the viscoelastoplastic response of titanium alloys. Int J Plast 17(10):1305–1350CrossRef

36.

Saleeb AF, Dhakal B, Dilibal S, Owusu-Danquah JS, Padula SA (2015) On the modeling of the thermo-mechanical responses of four different classes of NiTi-based shape memory materials using a general multi-mechanism framework. Mech Mater 80:67–86CrossRef

37.

Fish J, Belytschko T (2007) A first course in finite elements. Wiley, West SussexCrossRef

38.

Benafan O, Bigelow GS, Wood L, Luna HA (2022) Ruggedness evaluation of ASTM international standard test methods for shape memory materials: E3097 standard test method for mechanical uniaxial constant force thermal cycling of shape memory alloys. ASTM International, West Conshohocken

39.

Benafan O, Noebe RD, Halsmer TJ (2016) Static rock splitters based on high temperature shape memory alloys for planetary explorations. Acta Astronaut 118:137–157CrossRefADS

Titel: Shape Memory NiTiHf Machined Helical Springs: Balancing Displacement and Force Output for Actuation
verfasst von: P. E. Caltagirone
P. Naghipour Ghezeljeh
O. Benafan
Publikationsdatum: 13.03.2024
Verlag: Springer US
Erschienen in: Shape Memory and Superelasticity
Print ISSN: 2199-384X
Elektronische ISSN: 2199-3858
DOI: https://doi.org/10.1007/s40830-024-00479-9

Premium Partner

Marktübersichten

Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

Zur Marktübersicht

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Premium Partner

Marktübersichten