Finite-Element Analysis of an Antagonistic Bistable Shape Memory Alloy Beam Actuator

IF 3.4 3区 材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Hamid Shahsavari, Xi Chen, Georgino Kaleng Tshikwand, Frank Wendler, Manfred Kohl
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Abstract

A finite-element (FE) analysis of the active bistability of an antagonistic shape memory alloy (SMA) beam actuator of TiNiCu is presented. The actuator comprises two coupled SMA beams that are clamped at both ends and coupled in their center by a spacer having different memory shapes being deflected in opposite out-of-plane directions. The actuator is characterized by two equilibrium positions. To determine bistable behavior as a function of geometrical parameters, a force criterion is defined by the coupling force of the beams in austenitic and martensitic states. Bistable behavior is achieved, if the coupling force does not change sign in the entire displacement range. This implies that the austenitic beam dominates the opposing martensitic beam. Thus, selective heating of the SMA beams results in a snap-through motion of the coupled SMA beams. Depending on which of the two beams is in austenitic state, either of the two equilibrium positions is reached without the need for an external force. It is demonstrated that geometrical parameters like initial predeflection and spacer length have a crucial effect on the bistable performance. Bistable regions as well as critical limits characterized by geometry-dependent stability ratios, beyond which the actuator's performance becomes monostable, are identified.

拮抗双稳态形状记忆合金梁致动器的有限元分析
本文对钛镍铜对立形状记忆合金(SMA)梁致动器的主动双稳态性进行了有限元(FE)分析。致动器由两根耦合 SMA 梁组成,这两根梁的两端被夹紧,中间则由一个具有不同记忆形状的隔板耦合,并向相反的平面外方向偏转。致动器有两个平衡位置。为了确定作为几何参数函数的双稳态行为,根据奥氏体和马氏体状态下梁的耦合力定义了力标准。如果耦合力在整个位移范围内不改变符号,则实现了双稳态行为。这意味着奥氏体梁支配着对立的马氏体梁。因此,对 SMA 梁进行选择性加热会导致耦合 SMA 梁的快速通过运动。根据两根梁中哪一根处于奥氏体状态,无需外力即可达到两个平衡位置中的任何一个。研究表明,初始预偏转和间隔长度等几何参数对双稳态性能有至关重要的影响。研究确定了双稳态区域以及临界极限,临界极限的特征是与几何形状相关的稳定比,超过这个临界极限,致动器的性能将变为单稳态。
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来源期刊
Advanced Engineering Materials
Advanced Engineering Materials 工程技术-材料科学:综合
CiteScore
5.70
自引率
5.60%
发文量
544
审稿时长
1.7 months
期刊介绍: Advanced Engineering Materials is the membership journal of three leading European Materials Societies - German Materials Society/DGM, - French Materials Society/SF2M, - Swiss Materials Federation/SVMT.
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