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Shape Memory and Superelasticity
Erschienen in: Shape Memory and Superelasticity 4/2017

30.10.2017 | SPECIAL ISSUE: A TRIBUTE TO PROF. SHUICHI MIYAZAKI – FROM FUNDAMENTALS TO APPLICATIONS, INVITED REVIEW PAPER

Shape Memory Alloys for Monitoring Minor Over-Heating/Cooling Based on the Temperature Memory Effect via Differential Scanning Calorimetry: A Review of Recent Progress

verfasst von: T. X. Wang, W. M. Huang

Erschienen in: Shape Memory and Superelasticity | Ausgabe 4/2017

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Abstract

The recent development in the temperature memory effect (TME) via differential scanning calorimetry in shape memory alloys is briefly discussed. This phenomenon was also called the thermal arrest memory effect in the literature. However, these names do not explicitly reveal the potential application of this phenomenon in temperature monitoring. On the other hand, the standard testing process of the TME has great limitation. Hence, it cannot be directly applied for temperature monitoring in most of the real engineering applications in which temperature fluctuation occurs mostly in a random manner within a certain range. However, as shown here, after proper modification, we are able to monitor the maximum or minimum temperature in either over-heating or over-cooling with reasonable accuracy.
Vorheriger Artikel Civil Engineering Applications: Specific Properties of NiTi Thick Wires and Their Damping Capabilities, A Review
Nächster Artikel Numerical Study of the Plasticity-Induced Stabilization Effect on Martensitic Transformations in Shape Memory Alloys

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Literatur
1.
Otsuka K, Wayman CM (1998) Shape memory materials. Cambridge University Press, Cambridge
2.
Huang WM, Ding Z, Wang CC, Wei J, Zhao Y, Purnawali H (2010) Shape memory materials. Mater Today. 13:54–61CrossRef
3.
Miyazaki S, Fu YQ, Huang WM (2009) Thin film shape memory alloys: fundamentals and device applications. Cambridge University Press, New YorkCrossRef
4.
Wei ZG, Sandstrom R, Miyazaki S (1998) Shape-memory materials and hybrid composites for smart systems—part I shape-memory materials. J Mater Sci 33:3743–3762CrossRef
5.
Shariat BS, Meng Q, Mahmud AS, Wu Z, Bakhtiari R, Zhang J et al (2017) Experiments on deformation behaviour of functionally graded NiTi structures. Data Brief 13:562–568CrossRef
6.
Madangopal KT, Banerjee S, Lele S (1994) Thermal arrest memory effect. Acta Metall Mater. 42:1875–1885CrossRef
7.
Airoldi G, Corsi A, Riva G (1993) Micromemory effects in shape memory alloys. Nuovo Cimento D 15:365–374CrossRef
8.
Airoldi G, Riva G (1991) Step-wise stimulated martensitic transformations. Key engineering materials. Trans Tech Publications, Zurich, pp 5–16
9.
Wang ZG, Zu XT, Zhu S, Wang LM (2005) Temperature memory effect induced by incomplete transformation in TiNi shape memory alloy. Mater Lett 59:491–494CrossRef
10.
Airoldi G, Corsi A, Riva G (1998) Step-wise martensite to austenite reversible transformation stimulated by temperature or stress: a comparison in NiTi alloys. Mater Sci Eng A 241:233–240CrossRef
11.
Krishnan M (2005) New observations on the thermal arrest memory effect in Ni-Ti alloys. Scr Mater 53:875–879CrossRef
12.
Zheng YJ, Cui LS, Schrooten J (2004) Temperature memory effect of a nickel-titanium shape memory alloy. Appl Phys Lett 84:31–33CrossRef
13.
He XM, Xiang JH, Li MS, Duo SW, Guo SB, Zhang RF et al (2006) Temperature memory effect induced by incomplete transformation in TiNi-based shape memory alloy. J Alloy Compd 422:338–341CrossRef
14.
Wang ZG, Zu XT (2005) Effect of incomplete transformation on the transformation behavior in TiNi shape memory alloys. J Mater Sci 40:2663–2665CrossRef
15.
Wang ZG, Zu XT, Fu YQ, Wang LM (2005) Temperature memory effect in TiNi-based shape memory alloys. Thermochim Acta 428:199–205CrossRef
16.
Wang TX, Huang WM, Xiao R, Lu HB, Kang SF (2016) Temperature memory effect and its stability revealed via differential scanning calorimetry in ethylene-vinyl acetate (EVA) within glass transition range. J Polym Sci B Polym Phys 54:1731–1737CrossRef
17.
Sun L, Wang TX, Leow WC, Huang WM, Cui H, Gao XY (2016) Temperature memory effect in differential scanning calorimeter test in thermoplastic polyurethane. J Polym Res 23:63CrossRef
18.
Sun L, Huang WM (2010) Mechanisms of the multi-shape memory effect and temperature memory effect in shape memory polymers. Soft Matter 6:4403–4406CrossRef
19.
Otsuka K (1990) Introduction to the R-phase transition. Engineering aspects of shape memory alloys. Butterworth-Heinemann, London, pp 36–45CrossRef
20.
Sun L, Huang WM, Cheah JY (2010) The temperature memory effect and the influence of thermo-mechanical cycling in shape memory alloys. Smart Mater Struct 19:055005CrossRef
21.
Nurveren K, Akdogan A, Huang WM (2008) Evolution of transformation characteristics with heating/cooling rate in NiTi shape memory alloys. J Mater Process Technol 196:129–134CrossRef
22.
Liu N, Huang WM (2006) Comments on “Incomplete transformation induced multiple-step transformation in TiNi shape memory alloys” [Scripta Mater 2005;53:335]. Scr Mater 55:493–495CrossRef
23.
Tang C, Wang TX, Huang WM, Sun L, Gao XY (2016) Temperature sensors based on the temperature memory effect in shape memory alloys to check minor over-heating. Sens Actuators A Phys 238:337–343CrossRef
24.
Huang W, Wong YL (1999) Effects of pre-strain on transformation temperatures of NiTi shape memory alloy. J Mater Sci Lett 18:1797–1798CrossRef
25.
Liu N, Huang WM (2006) DSC study on temperature memory effect of NiTi shape memory alloy. Trans Nonferrous Metal Soc 16:S37–S41CrossRef
26.
Zhou M, Huang W, Meng X (2017) Temperature memory effect in a magnetic shape memory alloy for monitoring of minor over-cooling. Scr Mater 127:41–44CrossRef
Metadaten
Titel
Shape Memory Alloys for Monitoring Minor Over-Heating/Cooling Based on the Temperature Memory Effect via Differential Scanning Calorimetry: A Review of Recent Progress
verfasst von
T. X. Wang
W. M. Huang
Publikationsdatum
30.10.2017
Verlag
Springer International Publishing
Erschienen in
Shape Memory and Superelasticity / Ausgabe 4/2017
Print ISSN: 2199-384X
Elektronische ISSN: 2199-3858
DOI
https://doi.org/10.1007/s40830-017-0130-3

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