Analysis and design of 3D-printed flexure mechanism

Analysis and design of 3D-printed flexure mechanism

Compliant mechanisms (CM) are defined as monolithic, flexible structures that use elastic deformation to achieve desired motion. Such mechanisms are already being developed into myriads of micro- and nano-positioning applications all around us due to their ability to eliminate backlash and dry frict...

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Main Author: Teo, Jeriel Zhi Jun
Other Authors: Yeo Song Huat
Format: Final Year Project
Language:English
Published: 2018
Subjects:
DRNTU::Engineering::Mechanical engineering::Mechatronics
Online Access:http://hdl.handle.net/10356/75774
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-757742023-03-04T18:36:21Z Analysis and design of 3D-printed flexure mechanism Teo, Jeriel Zhi Jun Yeo Song Huat School of Mechanical and Aerospace Engineering Robotics Research Centre DRNTU::Engineering::Mechanical engineering::Mechatronics Compliant mechanisms (CM) are defined as monolithic, flexible structures that use elastic deformation to achieve desired motion. Such mechanisms are already being developed into myriads of micro- and nano-positioning applications all around us due to their ability to eliminate backlash and dry friction compared to their ball bearing or rigid-joint counterparts. CM are also preferred over traditional mechanisms for their high resolution, high repeatability in motion, hence use in precision and robotic applications, like micromanipulators in micro-electronic mechanism systems (MEMS). There are several characteristics of CMs that are desirable and can be harnessed, depending on their application. In some cases, the workspace needs to be maximised, while in other cases accuracy of motion is needed. This report presents a 3-DOF xyθz RRR compliant parallel mechanism designed for optimal stiffness performance- with exceptional translational and rotational stiffness ratios of 814 and 447 respectively and a large workspace of 3.5 by 3.5mm by 2.5o. The numerical solutions by Finite Element Analysis (FEA) were within ±8% of the analytical solutions as well. The mechanism was synthesised through a novel design approach combining the stiffness modelling based on the Pseudo-Rigid-Body Model (PRBM) and conducting optimisation for the optimal placement of the flexure notches for best stiffness performance. The model is then verified through FEA before a working prototype was manufactured to demonstrate the desired motion. Bachelor of Engineering (Mechanical Engineering) 2018-06-14T04:32:45Z 2018-06-14T04:32:45Z 2018 Final Year Project (FYP) http://hdl.handle.net/10356/75774 en Nanyang Technological University 89 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Engineering::Mechanical engineering::Mechatronics
spellingShingle DRNTU::Engineering::Mechanical engineering::Mechatronics
Teo, Jeriel Zhi Jun
Analysis and design of 3D-printed flexure mechanism
description Compliant mechanisms (CM) are defined as monolithic, flexible structures that use elastic deformation to achieve desired motion. Such mechanisms are already being developed into myriads of micro- and nano-positioning applications all around us due to their ability to eliminate backlash and dry friction compared to their ball bearing or rigid-joint counterparts. CM are also preferred over traditional mechanisms for their high resolution, high repeatability in motion, hence use in precision and robotic applications, like micromanipulators in micro-electronic mechanism systems (MEMS). There are several characteristics of CMs that are desirable and can be harnessed, depending on their application. In some cases, the workspace needs to be maximised, while in other cases accuracy of motion is needed. This report presents a 3-DOF xyθz RRR compliant parallel mechanism designed for optimal stiffness performance- with exceptional translational and rotational stiffness ratios of 814 and 447 respectively and a large workspace of 3.5 by 3.5mm by 2.5o. The numerical solutions by Finite Element Analysis (FEA) were within ±8% of the analytical solutions as well. The mechanism was synthesised through a novel design approach combining the stiffness modelling based on the Pseudo-Rigid-Body Model (PRBM) and conducting optimisation for the optimal placement of the flexure notches for best stiffness performance. The model is then verified through FEA before a working prototype was manufactured to demonstrate the desired motion.
author2 Yeo Song Huat
author_facet Yeo Song Huat
Teo, Jeriel Zhi Jun
format Final Year Project
author Teo, Jeriel Zhi Jun
author_sort Teo, Jeriel Zhi Jun
title Analysis and design of 3D-printed flexure mechanism
title_short Analysis and design of 3D-printed flexure mechanism
title_full Analysis and design of 3D-printed flexure mechanism
title_fullStr Analysis and design of 3D-printed flexure mechanism
title_full_unstemmed Analysis and design of 3D-printed flexure mechanism
title_sort analysis and design of 3d-printed flexure mechanism
publishDate 2018
url http://hdl.handle.net/10356/75774
_version_ 1759856449049067520

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