Abstract
In this paper high-temperature shape memory alloys based on TiPd and TiPt are reviewed. The effect of the alloying elements in ternary TiPd and TiPt alloys on phase transformation and strain recovery is also discussed. Generally, the addition of alloying elements decreases the martensitic transformation temperature and improves the strength of the martensite and austenite phases. Additionally, it also decreases irrecoverable strain, but without perfect recovery due to plastic deformation. With the aim to improve the strength of high-temperature shape memory alloys, multi-component alloys, including medium- and high-entropy alloys, have been investigated and proposed as new structural materials. Notably, it was discovered that the martensitic transformation temperature could be controlled through a combination of the constituent elements and alloys with high austenite finish temperatures above 500 °C. The irrecoverable strain decreased in the multi-component alloys compared with the ternary alloys. The repeated thermal cyclic test was effective toward obtaining perfect strain recoveries in multi-component alloys, which could be good candidates for high-temperature shape memory alloys.
Highlights
Shape recovery in shape memory alloys (SMAs) occurs during a reverse martensitic transformation from martensite to austenite phases
Application of HEAs and Medium-entropy alloy (MEA) to High-temperature shape memory alloys (HT-SMAs) is expected in this area for which results on multi-component alloys, in MEAs and HEAs, are presented in this paper
The martensitic transformation temperature (MTT) of the TiPd and TiPt alloys measured through differential scanning calorimetry (DSC)
Summary
Shape recovery in shape memory alloys (SMAs) occurs during a reverse martensitic transformation from martensite to austenite phases. ◦ C; and martensite finish temperature, Mf : 240 ◦ C, was applied for active clearance control actuation in the high-pressure turbine section of a turbofan engine [1] This indicates that the design can offer a small and lightweight package without requiring motion amplifiers that cause efficiency losses and introduce an additional failure mode [1]. The effects of both Zr [31] and Ag addition [32] into TiAu on the martensitic transformation and strain recovery was investigated; the MTT decreased by 10% with the addition of. It is difficult to achieve perfect strain recovery in HT-SMAs because of the easy introduction of plastic deformation at high temperatures. Application of HEAs and MEAs to HT-SMAs is expected in this area for which results on multi-component alloys, in MEAs and HEAs, are presented in this paper
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