Influence of the cooling / heating rate on the martensitic transformation and functional properties of the quenched Ni51Ti49 shape memory alloy

A.M. Ivanov, S.P. Belyaev, N.N. Resnina, V.A. Andreev show affiliations and emails
Received 28 September 2019; Accepted 06 November 2019;
Citation: A.M. Ivanov, S.P. Belyaev , N.N. Resnina, V.A. Andreev. Influence of the cooling / heating rate on the martensitic transformation and functional properties of the quenched Ni51Ti49 shape memory alloy. Lett. Mater., 2019, 9(4) 485-489
BibTex   https://doi.org/10.22226/2410-3535-2019-4-485-489

Abstract

A decrease in the cooling/heating rate increased the temperatures of the forward martensitic transformation. This is caused by the realisation of the forward transformation under isothermal conditions.The influence of the cooling / heating rate on the martensitic transformation temperatures and the strain variation in the quenched Ni51Ti49 alloy was studied. It was found that a decrease in the cooling / heating rate increased the temperatures of the forward transformation. It was assumed that this was due to the fact that the Ni51Ti49 alloy was able to undergo the forward transformation on cooling, as well as during isothermal holding, which increased the transformation temperatures on slow cooling. The influence of the cooling / heating rate on the transformation temperatures depended on whether the stress affected the cooling and heating or not. It was shown that if the forward transformation occurred under a constant stress, then the influence of the cooling / heating rate on its temperatures became weak. However, the temperatures of the reverse transformation under load depended on the cooling / heating rate and this dependence was more significant for the start temperature of the reverse transformation As than for the finish temperature. It was found that the cooling / heating rate did not affect the shape memory effect, however, this influenced the irreversible strain depending on the stress acting on cooling and heating. It was assumed that this might be caused by different mechanisms of the oriented martensite appearance.

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Funding

1. Russian Science Foundation - 18-19-00226