多层压电双晶片致动器

1997 International Symposium on Micromechanics and Human Science (Cat. No.97TH8311) Pub Date : 1997-10-05 DOI:10.1109/MHS.1997.768860

S. Kawakita, T. Isogai, N. Ohya, N. Kawahara

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引用次数: 33

摘要

我们研制了一种功耗低、位移大的多层双晶片驱动器。每一致动器层包括压电元件和弹性板。由于压电元件的体积是恒定的，执行器在施加电压的方向上膨胀，在垂直方向上收缩。这使弹性板弯曲，扩大位移。层数决定执行器力。利用所研制的作动器和传统的堆叠式压电作动器，研制了管内机车机构。对双作动机构的功耗和运动速度进行了研究。多层致动器的机构运动速度是传统致动器的2.5倍，功耗仅为传统致动器的1/80。

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Multi-layered piezoelectric bimorph actuator

We have developed a multi-layered bimorph actuator whose power consumption is low and whose displacement is large. Each actuator layer comprises a piezoelectric element and elastic plate. Because volume of the piezoelectric element is constant, the actuator expands in the direction of applied voltage, but contracts in the perpendicular direction. This bends the elastic plate, amplifying displacement. Layer number determines actuator force. We also developed in-pipe locomotive mechanism utilizing the developed actuator and conventional stack type piezoelectric actuator. The power consumption and moving speed of two-actuator mechanism were investigated. The mechanism of the multi-layered actuator moves 2.5 times faster compared with that of the conventional one, and consumes only 1/80 of electric power of the conventional one.

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来源期刊

1997 International Symposium on Micromechanics and Human Science (Cat. No.97TH8311)

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