A Millimeter-Stroke Piezoelectric Hybrid Actuator using Hydraulic Displacement Amplification Mechanism

Hwan-Sik Yoon, G. Washington, P. Eyabi, M. Radhamohan, S. Woodard, R. Dayton
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引用次数: 23

Abstract

Although piezoceramic actuators can generate extremely large forces, they normally exhibit small strokes in the range of tens of micrometers. A typical method to amplify these small strokes without sacrificing bandwidth has been to utilize a flexure-based leverage mechanism, where a piezo stack actuator deforms a specially cut metal block. In this paper, a new high-stroke piezoelectric actuator is presented, that employs a hydraulic amplification mechanism with a cylindrically shaped fluid chamber having a small opening at one side and a large opening at the other. When the piston in the larger opening is pushed by a piezo-stack actuator, the fluid is pressurized and pushes a shaft in the small opening through a longer distance. The stroke is determined by the area ratio of the two openings. Experiments showed that this new type of actuator could generate a longer stroke in the range of a few millimeters with a force of a few Newtons
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基于液压位移放大机构的毫米行程压电混合驱动器
虽然压电陶瓷致动器可以产生非常大的力,但它们通常表现出几十微米范围内的小冲程。放大这些小冲程而不牺牲带宽的典型方法是利用基于挠度的杠杆机构,其中压电堆叠执行器使特殊切割的金属块变形。提出了一种新型的高行程压电致动器,该致动器采用一边开口小,另一边开口大的圆柱形流体腔的液压放大机构。当较大开口的活塞被压电堆驱动器推动时,流体被加压并推动小开口中的轴通过更长的距离。行程由两个开口的面积比决定。实验表明,这种新型驱动器可以在几牛顿的力下产生几毫米范围内的更长的行程
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