Design of a Long Stroke Nanopositioning Stage With Self-Damping Actuator and Flexure Guide

Long stroke nanopositioning stages with high natural frequency and compact size are demanded in precision engineering. However, in previous researches, the natural frequency of the long stroke nanopositioning stage is normally below 50 Hz because the actuated force, moving mass, stiffness, motion ra...

Full description

Saved in:
Bibliographic Details
Published inIEEE transactions on industrial electronics (1982) Vol. 69; no. 10; pp. 10417 - 10427
Main Authors Zhang, Chi, Huang, Xiaolu, Yang, Miao, Chen, Silu, Yang, Guilin
Format Journal Article
LanguageEnglish
Published New York IEEE 01.10.2022
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Actuators
Dampers
Damping
Damping ratio
Eddy currents
Flexing
Flexure guide
Force
Magnetic resonance
Magnetomechanical effects
Metal plates
Nanopositioning
Resonant frequencies
Stators
Stiffness
Teeth
Tracking errors
voice coil actuator (VCA)
Online AccessGet full text

Cover

More Information
Summary:Long stroke nanopositioning stages with high natural frequency and compact size are demanded in precision engineering. However, in previous researches, the natural frequency of the long stroke nanopositioning stage is normally below 50 Hz because the actuated force, moving mass, stiffness, motion range, and damping ratio are not considered simultaneously and optimized thereafter. To solve this problem, a long stroke nanopositioning stage driven by the self-damping moving magnet actuator (SMMA) and supported by the flexure guide is integrated and designed in this article. The SMMA consists of two identical tooth-slot structure stators and one moving magnet which is embedded inside the flexure guide. Copper plates that functioned as eddy-current dampers are attached on the tooth surfaces to suppress the resonance peak at the natural frequency. An integrated dynamics model that consists of force, damping coefficient, and stiffness is established. The dimensional parameters of the proposed positioning stage are optimized to improve the system performances based on the developed model. Experimental results show that the natural frequency of the positioning stage reaches up to 71 Hz. The stage can achieve 20 nm positioning resolution within a motion range of <inline-formula><tex-math notation="LaTeX">\pm</tex-math></inline-formula>5 mm, and the root mean square tracking errors for 1 Hz sinusoidal and triangular commands are below 0.1% of the trajectory amplitudes.
ISSN:0278-0046
1557-9948
DOI:10.1109/TIE.2021.3126981