A single-piece contact-aided compliant mechanism (CCM) deforms to use one or many contact interactions to deliver the prescribed intricate input–output functionality. We present an automated synthesis procedure to design CCMs to trace large, non-smooth paths. Such paths can be traced by rigid-body or partially compliant mechanisms as well but the complexity, bulkiness and the presence of hinges is a disadvantage in terms of increased friction, backlash, need for lubrication, noise, and vibrations. In designing CCMs, both curved frame and two-dimensional finite elements are employed to represent the continuum and simulate the formation of contact sites. A contact site is one that allows relative rotation/sliding of a deforming member with respect to the neighboring one it is in contact with. The proposed design algorithm uses commercial software for large displacement contact analysis. The overall procedure automatically determines the CCM topology, feature shapes and sizes, and therefore the number (e.g., single or multiple) and nature (e.g., stiction or sliding) of contact sites. It systematically favors the continuum designs with lower function values when the synthesis problem is posed using a minimization objective. Synthesis of CCMs is exemplified for path generation applications though the proposed method can be employed for any generic kinematic task.
Issue Section:
Research Papers
References
1.
Mankame
, N. D.
, and Ananthasuresh
, G. K.
, 2002, “Contact-Aided Compliant Mechanisms: Concept and Preliminaries
,” Proceedings of the ASME DETC2002
, Paper # MECH- 34211.2.
Mankame
, N. D.
, and Ananthasuresh
, G. K.
, 2004, “Topology Synthesis of Contact-Aided-Compliant Mechanisms With Small Deformations
,” Comput. Struct.
, 82
(15–16
), pp. 1267
–1290
.3.
Hunt
, K. H.
, 1978, Kinematic Geometry of Mechanisms
, Oxford University Press
, New York
.4.
Hrones
, J. A.
, and Nelson
, G. L.
, 1951, Analysis of the Four-Bar Linkage
, Technology Press of MIT and John Wiley and Sons
, New York
.5.
Kempe
, A. B.
, 1876, “On a General Method of Describing Planar Curves of the nth Degree by Linkwork
,” Proc. R. Soc. London
, 7
, pp. 213
–216
.6.
Gao
, X. S.
, Zhu
, C. C.
, Chou
, S. C.
, and Ge
, J. X.
, 2001, “Automated Generation of Kempe Linkages for Algebraic Curves and Surfaces
,” Mech. Mach. Theory
, 36
, pp. 1019
–1033
.7.
Artobolevskii
, I. I.
, 1964, Mechanisms for the Generation of Plane Curves
, Pergamon, New York
.8.
Winter
, S. J.
, and Shoup
, T. E.
, 1973, “The Displacement Analysis of Path-Generating Flexible-Link Mechanisms
,” Mech. Mach. Theory
, 7
, pp. 443
–451
.9.
Sriram
, B. R.
, and Mruthyunjaya
, T. S.
, 1995, “Synthesis of Path Generating Flexible-Link Mechanisms
,” Comput. Struct.
, 56
(4
), pp. 657
–666
.10.
Ramrakhyani
, D. S.
, Frecker
, M. I.
and Lesiutre
, G. A.
, 2006, “Hinged Beam Elements for the Topology Design of Compliant Mechanisms Using the Ground Structure Approach
,” Proceedings of ASME Design Engineering Technical Conferences
, DETC2006-99439.11.
Saxena
, A.
, and Ananthasuresh
, G. K.
, 2000, “On an Optimality Property of Compliant Topologies
,” Struct. Multidiscip. Optim.
, 19
, pp. 36
–49
.12.
Larsen
, V. D.
, Sigmund
, O.
, and Bouwstra
, S.
, 1996, “Design and Fabrication of Compliant Mechanisms and Structures With Negative Poisson’s Ratio
,” Workshop on Micro Electro Mechanical Systems
, MEMS-96, IEEE
, New York
.13.
Bruns
, T. E.
, and Tortorelli
, D. A.
, 2001, “Topology Optimization of Nonlinear Elastic Structures and Compliant Mechanisms
,” Comput. Methods Appl. Mech. Eng.
, 190
(26–27
), pp. 3443
–3459
.14.
Saxena
, A.
, and Ananthasuresh
, G. K.
, 2001, “Topology Synthesis of Compliant Mechanisms for Nonlinear Force-Deflection and Curved Output Path
,” ASME J. Mech. Des.
, 123
, pp. 33
–42
.15.
Pedersen
, C. B. W.
, Buhl
, T.
, and Sigmund
, O.
, 2001, “Topology Synthesis of Large Displacement Compliant Mechanisms
,” Int. J. Numer. Methods Eng.
, 50
(2
), pp. 2683
–2705
.16.
Ullah
, I.
, and Kota
, S.
, 1997, “Optimal Synthesis of Mechanisms for Path Generation Using Fourier Descriptors and Global Search Methods
,” ASME J. Mech. Des.
, 119
, pp. 504
–510
.17.
Mankame
, N.
, and Ananthasuresh
, G. K.
, 2007, “Synthesis of Contact-Aided Compliant Mechanisms for Non-Smooth Path Generation
,” Int. J. Numer. Methods Eng.
, 69
(12
), pp. 2564
–2605
.18.
Bendsøe
, M. P.
, 1995, Optimization of Structural Topology, Shape and Material
, Springer
, Berlin
.19.
Zhou
, M.
, and Rozvany
, G. I. N.
, 1991, “The COC Algorithm, Part II: Topological, Geometrical, and Generalized Shape Optimization
,” Comput. Methods Appl. Mech. Eng.
, 89
, pp. 309
–336
.20.
Borrvall
, T.
, and Petersson
, J.
, 2001, “Topology Optimization Using Regularized Intermediate Density Control
,” Comput. Methods Appl. Mech. Eng.
, 190
, pp. 4911
–4928
.21.
Goldberg
, D. E.
, 2002, Genetic Algorithms in Search, Optimization and Machine Learning, Addison Wesley Longman, Inc., Reading
, MA.22.
Chapman
, C. D.
, Saitou
, K.
, and Jakiela
, M. J.
, 1994, “Genetic Algorithms as an Approach to Configuration and Topology Design
,” ASME J. Mech. Des.
, 116
, pp. 1005
–1012
.23.
Kane
, C.
, and Schoenauer
, M.
, 1996, “Topological Optimum Design Using Genetic Algorithms
,” Contr. Cybernet.
, 25
(5
), pp. 1059
–1088
.24.
Jakiela
, M. J.
, Chapman
, C.
, Duda
, J.
, Adewuya
, A.
, and Saitou
, K.
, 2000, “Continuum Structural Topology Design With Genetic Algorithms
,” Comput. Methods Appl. Mech. Eng.
, 186
, pp. 339
–356
.25.
Tai
, K.
, Cui
, G. Y.
, and Ray
, T.
, 2002, “Design Synthesis of Path Generating Compliant Mechanisms by Evolutionary Optimization of Topology and Shape
,” ASME J. Mech. Des.
, 124
(3
), pp. 492
–500
.26.
Parsons
, R.
, and Canfield
, S. L.
, 2002, “Developing Genetic Programming Techniques for the Design of Compliant Mechanisms
,” Struct. Multidiscip. Optim.
, 24
, pp. 78
–86
.27.
Saxena
, A.
, 2005, “Synthesis of Compliant Mechanisms for Path Generation Using Genetic Algorithm
,” ASME J. Mech. Des.
, 127
, pp. 1
–8
.28.
Saxena
, A.
, 2005, “Topology Design of Large Displacement Compliant Mechanisms With Multiple Materials and Multiple Output Ports
,” Struct. Multidiscip. Optim.
, 30
(6
), pp. 477
–490
.29.
Zhou
, H.
, and Ting
, K. L.
, 2005, “Topological Synthesis of Compliant Mechanisms Using Spanning Tree Theory
,” ASME J. Mech. Des.
, 127
(4
), pp. 753
–759
.30.
Rai
, A. K.
, Saxena
, A.
, and Mankame
, N. D.
, 2007, “Synthesis of Path Generating Compliant Mechanisms using Initially Curved Frame Elements
,” ASME J. Mech. Des.
, 129
, pp. 1056
–1063
.31.
Mettlach
, G. A.
, 1996, “Analysis and Design of Compliant Mechanisms Using Analytical and Graphical Techniques,” Ph.D. thesis, Purdue University, West Lafayette, IN.32.
Rai
, A. K.
, Saxena
, A.
, and Mankame
, N. D.
, 2010, “Unified Synthesis of Compact Planar Path-Generating Linkages With Rigid and Deformable Members
,” Struct. Multidiscip. Optim.
, 41
, pp. 863
–879
.33.
Wriggers
, P.
, 2006, Computational Contact Mechanics
, 2nd ed., Springer
, New York
.34.
abaqus, 2009, “abaqus User’s Manual Ver. 6.9,” Daussault Systems Inc.
35.
Hull
, P. V.
, and Canfield
, S.
, 2006, “Optimal Synthesis of Compliant Mechanisms Using Subdivision and Commercial FEA
,” ASME J. Mech. Des.
, 128
, pp. 337
–348
.36.
Mehta
, V.
, Frecker
, M.
, and Lesieutre
, G. A.
, 2009, “Stress Relief in Contact-Aided Compliant Cellular Mechanisms
,” ASME J. Mech. Des.
, 131(9)
, 091009
.Copyright © 2012
by American Society of Mechanical Engineers
You do not currently have access to this content.
