Effect of Heat Treatment Time and Temperature on the Microstructure and Shape Memory Properties of Nitinol Wires

In this study, the effect of heat treatment parameters on the optimized performance of Ni-rich nickel-titanium wires (NiTi/Nitinol) were investigated that were intended for application as actuators across various industries. In this instance, the maximum recovery strain and actuation angle achievable by a nitinol wire were employed as indicators of optimal performance. Nitinol wires were heat treated at different temperatures, 400-500 degrees C, and times, 30-120 min, to study the effects of these heat treatment parameters on the actuation performance and properties of the nitinol wires. Assessment covered changes in density, hardness, phase transition temperatures, microstructure, and alloy composition resulting from these heat treatments. DSC analysis revealed a decrease in the austenite transformation temperature, which transitioned from 42.8 degrees C to 24.39 degrees C with an increase in heat treatment temperature from 400 degrees C to 500 degrees C and was attributed to the formation of Ni4Ti3 precipitates. Increasing the heat treatment time led to an increase in the austenite transformation temperature. A negative correlation between the hardness of the heat-treated samples and the heat treatment temperature was found. This trend can be attributed to the formation and growth of Ni4Ti3 precipitates, which in turn affect the matrix properties. A novel approach involving image analysis was utilized as a simple yet robust analysis method for measurement of recovery strain for the wires as they underwent actuation. It was found that increasing heat treatment temperature from 400 degrees C to 500 degrees C above 30 min raised recovery strain from 0.001 to 0.01, thereby maximizing the shape memory effect.

Automated summary

This study investigates the effect of heat treatment parameters on the performance of Ni-rich nickel-titanium wires intended for use as actuators. The study examines the changes in density, hardness, phase transition temperatures, microstructure, and alloy composition resulting from different heat treatment temperatures and times. It is found that increasing the heat treatment temperature and time can increase recovery strain and maximize the shape memory effect.