A novel compliant XY micro-positioning stage using bridge-type displacement amplifier embedded with Scott-Russell mechanism

In some areas such as micro-mechanical, ultra-precision machining, nanotechnology, the high-precision positioning and very fine vertical scanning motion are needed urgently. Therefore, the Z-axis micro-displacement driving control technology has become the key technology in these areas. The piezoelectric ceramics actuator and stepper motor were integrated into hybrid linear actuator in Z-axis nanopositioning stage, and this can simplify the structure of the drive system. By calculating the gravity center of the vertical scanning system, and using single counterweight, a new one-arm bridge type structure was built. Appropriate tension and current sensors were also equipped in order to real-time monitor the drive status. It is feasible to balance the weight with this simplified system structure, and also guarantee the driving control accuracy of nanopositioning stage. Besides, in the structural design, the Abbe error can be reduced greatly by placing the stage center, grating ruler and displacement measurement centerline on the same line with grating reading head. The driving travel of nanopositioning stage is 150mm, and driving resolution is 1nm. The designing method introduced gives a scientific method and practical reference for the development of z-axis driving control system.

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Design, Modeling, and Testing of a Novel XY Piezo-Actuated Compliant Micro-Positioning Stage

Micromachines ◽

10.3390/mi10090581 ◽

2019 ◽

Vol 10 (9) ◽

pp. 581 ◽

Cited By ~ 3

Author(s):

Quan Zhang ◽

Jianguo Zhao ◽

Xin Shen ◽

Qing Xiao ◽

Jun Huang ◽

...

Keyword(s):

Modal Analysis ◽

Cross Coupling ◽

Maximum Error ◽

Analytical Models ◽

Amplification Ratio ◽

Proposed Model ◽

Positioning Stage ◽

Bridge Type ◽

Amplification Mechanism ◽

Coupling Error

A novel decoupled XY compliant micro-positioning stage, based on a bridge-type amplification mechanism and parallelogram mechanisms, is designed in this paper. Analytical models of the bridge-type amplification mechanism and parallelogram mechanisms are developed by Castigliano’s second theorem and a Beam constrained model. The amplification ratio, input stiffness, and output stiffness of the stage are further derived, based on the proposed model. In order to verify the theoretical analysis, the finite element method (FEM) is used for simulation and modal analysis, and the simulation results indicate that the errors of the amplification ratio, input stiffness, and output stiffness of the stage between the proposed model and the FEM results are 2.34%, 3.87%, and 2.66%, respectively. Modal analysis results show that the fundamental natural frequency is 44 Hz, and the maximum error between the theoretical model and the FEM is less than 4%, which further validates the proposed modeling method. Finally, the prototype is fabricated to test the amplification ratio, cross-coupling error, and workspace. The experimental results demonstrate that the stage has a relatively large workspace, of 346.1 μm × 357.2 μm, with corresponding amplification ratios of 5.39 in the X-axis and 5.51 in the Y-axis, while the cross-coupling error is less than 1.5%.

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Analysis of Bridge-Type Nano-Positioning Stage

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.44-47.3828 ◽

2010 ◽

Vol 44-47 ◽

pp. 3828-3832

Author(s):

Li Ma ◽

Zheng Feng He ◽

Hang Kong Ouyang

Keyword(s):

Natural Frequency ◽

Tilt Angle ◽

Elastic Beam ◽

Beam Theory ◽

Theory Analysis ◽

Frequency Model ◽

Amplification Ratio ◽

Positioning Stage ◽

Bridge Type ◽

The Ideal

A piezoelectric nanostage using bridge-type flexure hinge mechanisms is developed. Elastic beam theory was used to analyze the ideal and theoretic displacement amplification ratio and find that their value is mainly influenced by the length of the tilt rod and tilt angle of bridge-type. A multilayer S-type hinge is designed as the prismatic of moving platform. Stiffness and natural frequency model of the whole stage is built and find out that their value is mainly relevant to hinge thickness, tilt angle of bridge-type hinge and length of S-type hinge. Finally, finite element method (FEM) is used to verify the drived model. The errors of the total stiffness and the natural frequency of the stage between FEM and theory analysis are 3.8% and 6.6% respectively, which confirm the predictions of theory analysis.

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Configuration Synthesis of Micro/Nano-Positioning Stage Based on Graph Theory

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.323.3 ◽

2011 ◽

Vol 323 ◽

pp. 3-7

Author(s):

Chao Lin ◽

Xin Hui Cui ◽

Kai Cheng ◽

Song Song Yu

Keyword(s):

Graph Theory ◽

Structural Design ◽

Spanning Tree ◽

Design Method ◽

Structural Characteristics ◽

Tree Graph ◽

Positioning Stage ◽

Bridge Type ◽

Configuration Synthesis

The purpose of this paper was to generate several possible configurations of micro/nano-positioning stage with bridge-type mechanism based on graph theory. The structural characteristics of stage were discussed first. Then, these modules made up of micro/nano-positioning stage were abstracted. Thus the stage could be described with a tree-graph. According to the spanning tree theory, several possible configurations of stage are enumerated correspondingly. Subsequently, the configuration synthesis of six bridge-type mechanisms was investigated and 720 results were obtained. Rules for generating structures with symmetry are established. On the basis of this, several innovative structures are presented. Furthermore, the result of this paper provides a practicable approach for the structural design of stage and the design method based on graph theory is effective.

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