Development of A New Type of 2-DOF Piezo-Actuated Pseudo-Decoupled Compliant Mechanism for Elliptical Vibration Machining

Development of A New Type of 2-DOF Piezo-Actuated Pseudo-Decoupled Compliant Mechanism for Elliptical Vibration Machining

Currently, the elliptical vibration cutting/coining (EVC²) has been widely employed in fabricating various functional microstructure surfaces applied in many significant engineering fields. Therefore, for this study, a novel type of two-degree-of-freedom (2-DOF) piezoelectrically actuated pseudo-dec...

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Bibliographic Details
Published in:Micromachines (Basel) Vol. 10; no. 2; p. 122
Main Authors: Wang, Rongqi, Zhou, Xiaoqin, Meng, Guangwei
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 13-02-2019
MDPI
Subjects:
Accuracy
Aspect ratio
Bandwidths
Coining
Compliance
compliant mechanism
Critical angle
Cutting tools
Decoupling
Deformation
Degrees of freedom
elliptical trajectory
elliptical vibration machining
EVM) pseudo-decoupled
Finite element method
flexure hinges
Harmonic response
Machining
Mathematical models
Modal analysis
Modelling
Parameters
Resonant frequencies
System effectiveness
Tracking
tracking accuracy
Vibration
EVM) pseudo-decoupled
elliptical trajectory
elliptical vibration machining
flexure hinges
tracking accuracy
compliant mechanism
CM
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Summary:Currently, the elliptical vibration cutting/coining (EVC²) has been widely employed in fabricating various functional microstructure surfaces applied in many significant engineering fields. Therefore, for this study, a novel type of two-degree-of-freedom (2-DOF) piezoelectrically actuated pseudo-decoupled compliant mechanisms (PDCMs) with non-orthogonal decoupling structures, which can exactly generate the strict ellipse trajectories, was developed for improving the forming accuracies of the EVC² microstructures. First, the compliance matrices of 2-DOF PDCMs were theoretically modeled using the popular finite beam-based matrix modeling (FBMM) and the matrix-based compliance modeling (MCM) methods, then finite element analysis (FEA) was adopted to verify the effectiveness of the built compliance model for the 2-DOF PDCM with arbitrary structure parameters. Second, the static FEA method was employed to systematically reveal the dependencies of the tracking accuracies of the elliptical trajectories on the decoupling structures of 2-DOF PDCMs. Moreover, their main dynamic performances were also investigated through the FEA-based harmonic response analysis and modal analysis. On these bases, the critical angle of the decoupling structure was optimally set at 102.5° so that the PDCMs had minimum shape distortions of the ellipse trajectories. Thirdly, a series of experiments was conducted on this PDCM system for practically investigating its kinematic and dynamic performances. The actual aspect ratio between the major axis and minor axis of the ellipse trajectory was approximately 1.057, and the first-order and second-order resonant frequencies were 863 Hz and 1893 Hz, respectively. However, the obtained testing results demonstrated well the effectiveness and feasibility of 2-DOF PDCM systems in precisely tracking the ellipse trajectories with different geometric parameters. Several critical conclusions on this study are summarized in detail in the final section of this paper.
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ISSN:2072-666X
2072-666X
DOI:10.3390/mi10020122