DocumentCode
843227
Title
Self-Latched Micromachined Mechanism With Large Displacement Ratio
Author
Liu, A.Q. ; Li, J. ; Liu, Z. ; Lu, C. ; Zhang, X.M. ; Wang, Michael Y.
Author_Institution
Sch. of Electr. & Electron. Eng., Nanyang Technol. Univ., Singapore
Volume
15
Issue
6
fYear
2006
Firstpage
1576
Lastpage
1585
Abstract
A self-latched micromachined mechanism with large displacement ratio is presented in this paper. The large output displacement is obtained by amplifying the small input motion through the elastic deformation of the compliant configuration, which realizes the self-latched output by local bifurcation effect. The design theory and synthesis of compliant microstructures are analyzed. The numerical and analytical simulations are implemented to the linear amplification, which shows that as high as >50 times displacement magnification can be obtained. Self-latching is realized by bifurcation effect to maintain fixed output displacement even though the input goes further as indicated by the large displacement simulation. This micromachined mechanism along with a comb-drive actuator is fabricated by deep-reactive ion-etching (DRIE) process. In experiment, it measures an output displacement of 52.0 mum at an input displacement of only 0.96 mum, obtaining a displacement ratio of 54.2. For further input displacement, the output displacement remains unchanged, proving the self-latching effect
Keywords
amplification; bifurcation; elastic deformation; micromachining; micromechanical devices; numerical analysis; sputter etching; DRIE; comb-drive actuator; deep-reactive ion-etching; elastic deformation; large displacement ratio; large displacement simulation; local bifurcation effect; micromachined mechanism; self-latching; Actuators; Analytical models; Bifurcation; Displacement measurement; Fingers; Micromechanical devices; Microstructure; Numerical simulation; Piezoelectric materials; Shape memory alloys; Bifurcation effect; large displacement ratio; micromachined mechanism; self-latching;
fLanguage
English
Journal_Title
Microelectromechanical Systems, Journal of
Publisher
ieee
ISSN
1057-7157
Type
jour
DOI
10.1109/JMEMS.2006.883574
Filename
4020277
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