Optimal design of a piezo-actuated 2-DOF millimeter-range monolithic flexure mechanism with a pseudo-static model

•A hybrid rhombus-lever multistage displacement amplifier is proposed.•The millimeter-range XY mechanism has resonance frequency of 128 Hz.•The kinetotatics and dynamics are optimized by a pseudo-static model.•Kinetic/elastic energy calculation and the Lagrange’s equation are avoided. Flexure-based...

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Bibliographic Details
Published in:Mechanical systems and signal processing 2019-01, Vol.115, p.120-131
Main Authors: Ling, Mingxiang, Cao, Junyi, Jiang, Zhou, Zeng, Minghua, Li, Qisheng
Format: Article
Language:English
Subjects:
Amplifiers
Compliant mechanisms
Cross coupling
Decoupling
Design optimization
Displacement amplifier
Electricity
Error analysis
Flexing
Flexure hinge
Geometry
Kinetics
Lagrange multiplier
Mathematical models
Modulus of elasticity
Parameters
Performance prediction
Piezoelectric actuator
Piezoelectric actuators
Piezoelectricity
Precision positioning stage
Static models
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Summary:•A hybrid rhombus-lever multistage displacement amplifier is proposed.•The millimeter-range XY mechanism has resonance frequency of 128 Hz.•The kinetotatics and dynamics are optimized by a pseudo-static model.•Kinetic/elastic energy calculation and the Lagrange’s equation are avoided. Flexure-based displacement amplifiers are frequently used to magnify the small stroke of piezoelectric actuators. In this paper, a hybrid rhombus-lever multistage displacement amplifier with an improved boundary constraint is proposed to develop a parallel millimeter-range XY monolithic mechanism while retaining a relatively high dynamic frequency. A concise pseudo-static model developed by the authors is utilized to analyze the kinetostatic and dynamic performances of the designed flexure mechanism and then the geometric parameters are optimized in terms of both kinetostatics and dynamics. Different from the previous Lagrange-based dynamic methods for compliant mechanisms, cumbersome calculations of the kinetic and elastic energies as well as adopting Lagrange’s equation are all avoided. With the proposed pseudo-static model, the kinetostatics and dynamics of the flexure mechanism can be analyzed concurrently in a programmed statics-similar way, suggesting its superiority for fast performance prediction and parameter optimization during the early stage of design. Finally, a prototype of the XY monolithic mechanism is manufactured and experimentally tested for evaluating its performances. Experimental results show that the designed flexure mechanism has a motion range in excess of 1.2 mm × 1.2 mm with a resonance frequency of 128 Hz. The cross-coupling error is measured to be less than 2%, indicating an acceptable decoupling performance.
ISSN:0888-3270
1096-1216
DOI:10.1016/j.ymssp.2018.05.064