Modeling Large Planar Deflections of Flexible Beams in Compliant Mechanisms Using Chained Beam-Constraint-Model1

Ma, Fengying; Chen, Guimin

doi:10.1115/1.4031028

Cited by 176 publications

(55 citation statements)

References 19 publications

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“…Future work includes the incorporation of kinematic and static synthesis of complaint mechanisms and modeling compliant members with analytical models that can provide strain energy calculation for the Eq. (10) such as Beam Constraint Model (Awtar and Sen, 2010) and Chained Beam Constraint Model (Ma and Chen, 2015). Also, the PRB models optimized by Venkiteswaran and Su (2014) were found to be inadequate for slender beams and a new PRB model with linear springs will be optimized to be employed in the software for analysis of slender beams.…”

Section: Discussionmentioning

confidence: 99%

DAS-2D: a concept design tool for compliant mechanisms

Turkkan¹,

Su²

2016

Mech. Sci.

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Abstract.Compliant mechanisms utilize the deformation of the elastic members to achieve the desired motion. Currently, design and analysis of compliant mechanisms rely on several commercial dynamics and finite element simulation tools. However, these tools do not implement the most recently developed theories in compliant mechanism research. In this article, we present DAS-2D (Design, Analysis and Synthesis), a conceptual design tool which integrates the recently developed pseudo-rigid-body models and kinetostatic analysis/synthesis theories for compliant mechanisms. Coded in Matlab, the software features a kinematic solver for general rigid-body mechanisms, a kinetostatic solver for compliant mechanisms and a fully interactive graphical user interface. The implementation details of all modules of the program are presented and demonstrated with four different case studies. This tool can be beneficial to classroom teaching as well as engineering practices in design of compliant mechanisms.

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Section: Discussionmentioning

confidence: 99%

DAS-2D: a concept design tool for compliant mechanisms

Turkkan¹,

Su²

2016

Mech. Sci.

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“…In PRBM, the flexible member of the mechanism is considered to be rigid links connected by a revolute joint or torsional spring, then the mechanism can be analyzed the same way with traditional mechanisms. Over the years, many new methods have been developed based on PRBM to improve the accuracy of the results (Ma & Chen, 2015), and finite element analysis has become a widely accepted way to analyze compliant members of the mechanisms (Lobontiu, 2002;Howell et al, 2013).…”

Section: Origami and Compliant Mechanismsmentioning

confidence: 99%

Design of Hinge-Line Geometry to Facilitate Non-Plastic Folding in Thin Metallic Origami-Inspired Devices

Zhang

Trease

2018

Volume 5B: 42nd Mechanisms and Robotics Conference

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Origami is the traditional art of paper folding, which yields objects that can be considered, in engineering terms, as mechanisms with relative motion between panels (paper) constrained by hinges (folds). Non-paper materials are often studied for origamiinspired applications in engineering. The proposed hinge material in this work is bulk metallic glass (BMG), chosen for its low stiffness, wear and corrosion resistance, biocompatibility, and extreme capacity for elastic deformation. Panel-spacing and geometry were examined to provide insight for the design of thin BMG folding membrane hinges to connect larger regions of thicker material (panels). Finite element analysis was performed to study the stress variation, distribution, and displacement along the hinge for several design variations, and several loading profiles are discussed to determine the necessity of modified rounded-edge panels. The results will directly aid in creating origami-inspired designs with membrane hinges, and applicable to the design of devices such as foldable electronics, optical systems, and deployable solar arrays.iv

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“…[20][21][22][23]. In this work, a novel two-stage lever-type amplifier is proposed, in which all the flexural hinges are loaded in tension and bending rather than compression and bending when deflected [24][25][26]. This type of amplifier, as illustrated in Fig.…”

Section: Introductionmentioning

confidence: 98%