Design and analysis of symmetric and compact 2R1T (in-plane 3-DOC) flexure parallel mechanisms

Guangbo Hao

doi:10.5194/ms-8-1-2017

Design and analysis of symmetric and compact 2R1T (in-plane 3-DOC) flexure parallel mechanisms

Guangbo Hao

School of Engineering and Architecture

Research output: Contribution to journal › Article › peer-review

Abstract

Symmetry is very necessary in flexure mechanisms, which can eliminate parasitic motions, avoid buckling, and minimize thermal and manufacturing sensitivity. This paper proposes two symmetric and compact flexure designs, in-plane 3-DOC (degree of constraint) mechanisms, which are composed of 4 and 6 identical wire beams, respectively. Compared to traditional leaf-beam-based designs, the two present designs have lower stiffness in the primary motion directions, and have smaller stiffness reduction in the parasitic directions. Analytical modelling is conducted to derive the symbolic compliance equations, enabling quick analysis and comparisons of compliances of the two mechanisms. A prototype has been tested statically to compare with analytical models.

Original language	English
Pages (from-to)	1-9
Number of pages	9
Journal	Mechanical Sciences
Volume	8
Issue number	1
DOIs	https://doi.org/10.5194/ms-8-1-2017
Publication status	Published - 10 Jan 2017

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https://hdl.handle.net/10468/3475Licence: CC BY

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abstract = "Symmetry is very necessary in flexure mechanisms, which can eliminate parasitic motions, avoid buckling, and minimize thermal and manufacturing sensitivity. This paper proposes two symmetric and compact flexure designs, in-plane 3-DOC (degree of constraint) mechanisms, which are composed of 4 and 6 identical wire beams, respectively. Compared to traditional leaf-beam-based designs, the two present designs have lower stiffness in the primary motion directions, and have smaller stiffness reduction in the parasitic directions. Analytical modelling is conducted to derive the symbolic compliance equations, enabling quick analysis and comparisons of compliances of the two mechanisms. A prototype has been tested statically to compare with analytical models.",

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Design and analysis of symmetric and compact 2R1T (in-plane 3-DOC) flexure parallel mechanisms

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