Self-Sustained Vibration of Optically Responsive Liquid Crystal Elastomer Cantilever Beams
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摘要: 研究了液晶弹性体(LCE)悬臂梁的光驱自持续弯曲振动现象,建立了光驱振动的动力学模型,利用振型叠加法得到其半解析公式,并利用MATLAB软件编程计算其动力学响应规律. 结果表明:在恒定光照作用下,可以实现LCE悬臂梁周期性自激振动响应;同时表明LCE梁弯曲振动的振幅可通过调节光强、阻尼系数和热弛豫时间来控制,而梁振动的频率主要取决于热弛豫时间. 研究结果在远程光驱驱动器、传感器、软微机器人和光能转换系统的设计等领域具有一定的指导意义.Abstract: The light-driven self-sustained bending vibration phenomenon of liquid crystal elastomer (LCE) cantilever beams was investigated, and the dynamics model for light-driven vibration was established, with the semi-analytical formula obtained with the method of vibration shape superposition, and the dynamic response laws calculated by the MATLAB software programming. The results show that, the periodic self-sustained vibration responses of the LCE cantilever beam can be realized under the action of constant light, which theoretically and reasonably explains previous experimental phenomena. Furthermore, the bending vibration amplitude of the LCE beam can be controlled through adjustment of the light intensity, the damping coefficient and the thermal relaxation time, and the beam vibration frequency mainly depends on the thermal relaxation time. This work is of significance in the engineering fields of remote light-driven actuators, sensors, soft micro-robots and light energy conversion systems.
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Key words:
- liquid crystal elastomer /
- self-sustained vibration /
- cantilever beam /
- light-driven
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表 1 材料特性和几何参数
Table 1. Material properties and geometrical parameters
symbol parameter value unit T0 thermal characteristic time 0.001~0.1 s ρ mass density 1 000 kg/m3 α damping coefficient 1 kg/(s·m2) l length 0.01 m h thickness 0.000 1 m d0 penetration depth 0.000 01 m E elastic modulus 1 000 Pa ν Poisson’s ratio 0.5 - 
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