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contributor authorJ. A. Hetrick
contributor authorS. Kota
date accessioned2017-05-09T00:00:30Z
date available2017-05-09T00:00:30Z
date copyrightJune, 1999
date issued1999
identifier issn1050-0472
identifier otherJMDEDB-27661#229_1.pdf
identifier urihttp://yetl.yabesh.ir/yetl/handle/yetl/122603
description abstractCompliant mechanisms are jointless mechanical devices that take advantage of elastic deformation to achieve a force or motion transformation. An important step toward automated design of compliant mechanisms has been the development of topology optimization techniques. The next logical step is to incorporate size and shape optimization to perform dimensional synthesis of the mechanism while simultaneously considering practical design specifications such as kinematic and stress constraints. An improved objective formulation based on maximizing the energy throughput of a linear static compliant mechanism is developed considering specific force and displacement operational requirements. Parametric finite element beam models are used to perform the size and shape optimization. This technique allows stress constraints to limit the maximum stress in the mechanism. In addition, constraints which restrict the kinematics of the mechanism are successfully applied to the optimization problem. Resulting optimized mechanisms exhibit efficient mechanical transmission and meet kinematic and stress requirements. Several examples are given to demonstrate the effectiveness of the optimization procedure.
publisherThe American Society of Mechanical Engineers (ASME)
titleAn Energy Formulation for Parametric Size and Shape Optimization of Compliant Mechanisms
typeJournal Paper
journal volume121
journal issue2
journal titleJournal of Mechanical Design
identifier doi10.1115/1.2829448
journal fristpage229
journal lastpage234
identifier eissn1528-9001
keywordsOptimization
keywordsShapes
keywordsCompliant mechanisms
keywordsMechanisms
keywordsStress
keywordsDesign
keywordsForce
keywordsDeformation
keywordsMechanical drives
keywordsMotion
keywordsFinite element analysis
keywordsDisplacement
keywordsKinematics AND Topology
treeJournal of Mechanical Design:;1999:;volume( 121 ):;issue: 002
contenttypeFulltext


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