Design methodology of the Ni50Ti50 shape memory alloy beam actuator: Heat treatment, training and numerical simulation

Design methodology of the Ni50Ti50 shape memory alloy beam actuator: Heat treatment, training and numerical simulation

[Display omitted] •Forward design method for SMA beam actuators was proposed with shape evolution during training firstly considered.•The appropriate heat treatment temperature for Ni50Ti50 SMA beam actuators was determined.•The shape evolution trend of SMA beam actuators through training under vari...

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Bibliographic Details
Published in:Materials & design Vol. 217; p. 110615
Main Authors: Rao, Zhixiang, Wang, Xiaoyuan, Leng, Jiaming, Yan, Zehong, Yan, Xiaojun
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-05-2022
Elsevier
Subjects:
Actuator
Design method
Heat treatment
NiTi
Shape memory alloy beam
Training
Training
Shape memory alloy beam
Heat treatment
NiTi
Design method
Actuator
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Summary:[Display omitted] •Forward design method for SMA beam actuators was proposed with shape evolution during training firstly considered.•The appropriate heat treatment temperature for Ni50Ti50 SMA beam actuators was determined.•The shape evolution trend of SMA beam actuators through training under various bias load was investigated.•The simulation method for the interaction of the SMA beam actuator with the driven structure was proposed.•A design case was studied, with high accuracy of design result demonstrated. Shape memory alloy (SMA) beam actuators are widely used in morphing structures, which leads to a surgent demand for a comprehensive design method. Previous methods have not considered the heat treatment and the evolution of actuation performance during training. In this study, an in-depth investigation was conducted into the Ni50Ti50 (at%) SMA beam actuator from the perspective of heat treatment, training, numerical simulation for developing a comprehensive and novel design methodology. The proper heat treatment conditions that result in the relatively high actuation performance for the Ni50Ti50 SMA beam were determined. The dependence of the thermomechanical behavior evolution on the training load was established. Moreover, a numerical analysis method for the SMA beam actuator based on a 3-D constitutive model with tension-compression asymmetry considered was detailed, followed by the calibration of material parameters. A forward design method for the SMA beam actuator was proposed with the shape and actuation performance evolution during training under various training loads fully considered in the design process. The proposed design method was applied for a design case and the accuracy of the design results demonstrated its feasibility.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2022.110615