Abstract
In this work, we are interested in examining the strain rate effect on the mechanical behavior of Ni–Ti superelastic wires after hydrogen charging and ageing for 24 h. Specimens underwent 50 cycles of loading-unloading, reaching an imposed deformation of 7.6%. During loading, strain rates from 10−4 s−1 to 10−2 s−1 were achieved. With a strain rate of 10−2 s−1, the specimens were charged by hydrogen for 6 h and aged for one day showed a superelastic behavior marked by an increase in the residual deformation as a function of the number of cycles. In contrast, after a few number of cycles with a strain rate of 10−4 s−1, the Ni-Ti alloy archwire specimens fractured in a brittle manner during the martensite transformation stage. The thermal desorption analysis showed that, for immersed specimens, the desorption peak of hydrogen appeared at 320 °C. However, after annealing the charged specimens by hydrogen at 400 °C for 1 h, an embrittlement took place at the last cycles for the lower strain rates of 10−4 s−1. The present study suggests that the embrittlement can be due to the development of an internal stress in the subsurface of the parent phase during hydrogen charging and due to the creation of cracks and local zones of plasticity after desorption.
Highlights
The NiTi shape memory alloy (SMA) is considered as a smart material thanks to its thermomechanical behavior, such as the mechanical shape memory effect (SME) and the thermal effect (TE) [1,2], which make this alloy suitable for aerospace and Micro-Electro-Mechanical Systems industries [3]
After 6 h of hydrogen charging with a current density of 10 A/m2 and ageing, the cyclic tensile curves of the superelastic Ni–Ti SMA strongly depends on the strain rate
An embrittlement is detected in the 18th cycle for the imposed lower strain rate of 10−4 s−1
Summary
The NiTi shape memory alloy (SMA) is considered as a smart material thanks to its thermomechanical behavior, such as the mechanical shape memory effect (SME) and the thermal effect (TE) [1,2], which make this alloy suitable for aerospace and Micro-Electro-Mechanical Systems industries [3]. The equiatomic NiTi SMA has been successfully used in various areas, like cardio stents, orthopedic implants and orthodontic devices, because they process, in addition to good corrosion resistance and biocompatibility with the human body, remarkable high strain recovery [4,5,6]. Superelastic NiTi wires, in the austenitic active alloy phase, undergo a martensitic transformation phase either by temperature change or stress application [8,9]. This superelasticity is manifested by a flat or nearly flat plateau in the stress-strain diagram indicating a reversible transformation from an austenite parent phase B2 to a monoclinic B19’ martensite phase.
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