Influence of NiTi Spring Dimensions and Temperature on the Actuator Properties

Zina A. Al shadidi, Ahmed Kadhum Falih, M. Suhail, Suha Salem Haidrah
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Abstract

Nitinol (NiTi) is used in many medical applications, including hard tissue replacements, because of its suitable characteristics, including a close elastic modulus to that of bones. Due to the great importance of the mechanical properties of this material in tissue replacements, this work aims to study the hysteresis response in an attempt to explore the ability of the material to remember its previous mechanical state in addition to its ability to withstand stress and to obtain the optimal dimensions and specifications for the manufacturer of NiTi actuators. Stress-strain examination is done in a computational way using a mutable Lagoudas MATLAB code for various coil radii, environment temperatures, and coil lengths. The computational methodology was done by varying the dimensions and the ambient temperature of the simulated NiTi spring actuator. The hysteresis loop is studied by increasing the external stress for a reversible martensitic transformation. The coil radius, spring height, and wire radius affect the spring force and deformations. In the same way, these parameters affect the strain and stress point values. These changes are shown through the martensite and austenite start and finish values. The NiTi hysteresis loop narrows with increasing ambient temperature or initial spring height. At a higher temperature, the force supplied to the actuator must be less for the same deformation; therefore, a higher ambient temperature provides more efficiency for the shape memory devices and a longer lifetime for the actuator.
NiTi弹簧尺寸和温度对执行器性能的影响
镍钛诺(NiTi)被用于许多医疗应用,包括硬组织替代,因为它具有合适的特性,包括与骨骼相近的弹性模量。由于该材料的力学性能在组织置换中非常重要,因此本工作旨在研究迟滞响应,试图探索该材料除了承受应力的能力外,还能记住其先前的力学状态,并为NiTi执行器制造商获得最佳尺寸和规格。应力应变检查是在计算方式使用可变Lagoudas MATLAB代码对各种线圈半径,环境温度和线圈长度。计算方法是通过改变模拟镍钛弹簧执行器的尺寸和环境温度来完成的。通过增加外加应力,研究了可逆马氏体相变的磁滞回线。线圈半径、弹簧高度和导线半径影响弹簧的受力和变形。同样,这些参数影响应变和应力点值。这些变化通过马氏体和奥氏体的起始值和结束值表现出来。NiTi滞回线随着环境温度或初始弹簧高度的增加而变窄。在较高的温度下,对于相同的变形,提供给执行机构的力必须较小;因此,较高的环境温度为形状记忆器件提供了更高的效率,并为执行器提供了更长的寿命。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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