稳态电路下液晶弹性体机械超材料中的电热诱导可控自致振荡

IF 2.2 3区 工程技术 Q2 MECHANICS
Xiaodong Liang, Bin Hu
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引用次数: 0

摘要

自驱动振荡系统具有从周围环境中提取能量以自主维持振荡的独特能力,因此非常适合应用于软机器人、主动致动器和智能设备。与传统材料相比,机械超材料以其负泊松比和体积膨胀特性而著称,可以提高自驱动系统的功能和性能。本理论研究提出了液晶弹性体(LCE)机械超材料在稳态电路下的电热诱导自驱动振荡系统,并研究了其自驱动机制和行为。外部电路产生的电热效应可使 LCE 纤维做净正功。当 LCE 纤维所做的净正功正好补偿了系统的阻尼耗散时,就能触发并维持自致振荡。结果表明,自激振荡可以通过系统参数进行调制和控制。该程序可为设计有源微型机械、能量收集器、医疗设备和监测传感器铺平道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Electrothermally-induced controllable self-actuated oscillation in liquid crystal elastomer mechanical metamaterials under steady-state circuits

Self-actuated oscillation systems possess the unique ability to extract energy from their surroundings to sustain oscillation autonomously, which makes them ideal for applications in soft robotics, active actuators and smart devices. In contrast to conventional materials, mechanical metamaterials, known for their negative Poisson's ratio and volume expansion properties, can boost the functionality and performance of self-actuated systems. This theoretical study proposes an electrothermally-induced self-actuated oscillation system in liquid crystal elasomter (LCE) mechanical metamaterials under steady-state circuits and investigates its self-actuated mechanism and behavior. The electrothermal effect caused by the external electrical circuit enables LCE fibers to do net positive work. When the net positive work done by LCE fibers exactly compensates for the damping dissipation of the system, self-actuated oscillation can be triggered and maintained. The results indicate that self-actuated oscillation can be modulated and controlled by system parameters. The procedure can pave the path for designing active micromachine, energy harvester, medical devices and monitoring sensors.

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来源期刊
CiteScore
4.40
自引率
10.70%
发文量
234
审稿时长
4-8 weeks
期刊介绍: Archive of Applied Mechanics serves as a platform to communicate original research of scholarly value in all branches of theoretical and applied mechanics, i.e., in solid and fluid mechanics, dynamics and vibrations. It focuses on continuum mechanics in general, structural mechanics, biomechanics, micro- and nano-mechanics as well as hydrodynamics. In particular, the following topics are emphasised: thermodynamics of materials, material modeling, multi-physics, mechanical properties of materials, homogenisation, phase transitions, fracture and damage mechanics, vibration, wave propagation experimental mechanics as well as machine learning techniques in the context of applied mechanics.
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