A novel parallel-kinematic flexure mechanism that provides highly decoupled motions along the three translational directions (X, Y, and Z) and high stiffness along the three rotational directions (θx, θy, and θz) is presented. Geometric decoupling ensures large motion range along each translational direction and enables integration with large-stroke ground-mounted linear actuators or generators, depending on the application. The proposed design, which is based on a systematic arrangement of multiple rigid stages and parallelogram flexure modules, is analyzed via nonlinear finite elements analysis (FEA). A proof-of-concept prototype is fabricated to validate the predicted large range and decoupled motion capabilities. The analysis and the hardware prototype demonstrate an XYZ motion range of 10 mm × 10 mm × 10 mm. Over this motion range, the nonlinear FEA predicts cross-axis errors of less than 7.8%, parasitic rotations less than 10.8 mrad, less than 14.4% lost motion, actuator isolation better than 1.5%, and no perceptible motion direction stiffness variation.
Issue Section:
Design Innovation Papers
References
1.
Jones
, R. V.
, 1962
, “Some Uses of Elasticity in Instrument Design
,” J. Sci. Instrum.
, 39
, pp. 193
–203
.10.1088/0950-7671/39/5/3032.
Smith
, S. T.
, 2000
, Flexures: Elements of Elastic Mechanisms
, Gordon and Breach Science Publishers
, New York
.3.
Slocum
, A. H.
, 1992
, Precision Machine Design
, Society of Manufacturing Engineers
, Dearborn, MI
.4.
Awtar
, S.
, Ustick
, J.
, and Sen
, S.
, 2011
, “An XYZ Parallel Kinematic Flexure Mechanism With Geometrically Decoupled Degrees of Freedom
,” Proceedings of ASME IDETC/CIE
, Washington DC
, Paper No. 47713.5.
Fischer
, F. L.
, 1981
, “Symmetrical 3 DOF Compliance Structure
,” U.S. Patent No. 4,447,048.6.
Bednorz
, J. G.
, Hollis
, R. L.
, Jr., Lanz
, M.
, Pohl
, W. D.
, and Yeack-Scranton
, C. E.
, 1985
, “Piezoelectric XY Positioner
,” U.S. Patent No. 4,520,570.7.
Davies
, P. A.
, 2001
, “Positioning Mechanism
,” U.S. Patent No. 6,193,226.8.
Dagalakis
, N. G.
, and Amatucci
, E.
, 2001
, “Kinematic Modeling of a 6 Degree of Freedom Tri-Stage Micro-Positioner
,” Proceedings of ASPE 16th Annual Meeting
, Crystal City, VA
.9.
Yao
, Q.
, Dong
, J.
, and Ferreira
, P. M.
, 2008
, “A Novel Parallel-Kinematics Mechanisms for Integrated, Multi-Axis Nanopositioning—Part 1: Kinematics and Design for Fabrication
,” Precis. Eng.
, 32
(1
), pp. 7
–19
.10.1016/j.precisioneng.2007.03.00110.
Hicks
, T. R.
, and Atherton
, P. D.
, 1997
, The Nanopositioning Book
, Queensgate Instruments Ltd.
, Torquay, UK.11.
Devasia
, S.
, Eleftheriou
, E.
, and Moheimani
, S. O. R.
, 2007
, “A Survey of Control Issues in Nanopositioning
,” IEEE Trans. Control Syst. Technol.
, 15
(5)
, pp. 802
–823
.10.1109/TCST.2007.90334512.
Jordan
, S.
, and Lula
, B.
, 2005
, “Nanopositioning: The Technology and the Options
,” The 2005 Photonics Handbook
, Laurin Publications, Pittsfield, MA
.13.
Dai
, G.
, Pohlenz
, F.
, Danzebrink
, H.-U.
, Xu
, M.
, Hasche
, K.
, and Wilkening
, G.
, 2004
, “Metrological Large Range Scanning Probe Microscope
,” Rev. Sci. Instrum.
, 75
(4
), pp. 962
–969
.10.1063/1.165163814.
Sinno
, A.
, Ruaux
, P.
, Chassagne
, L.
, Topcu
, S.
, and Alayli
, Y.
, 2007
, “Enlarged Atomic Force Microscopy Scanning Scope: Novel Sample-Holder Device With Millimeter Range
,” Rev. Sci. Instrum.
, 78
(9
), pp. 1
–7
.10.1063/1.277362315.
Wouters
, D.
, and Schubert
, U. S.
, 2004
, “Nanolithography and Nanochemistry: Probe-Related Patterning Techniques and Chemical Modification for Nanometer-Sized Devices
,” Angew. Chem., Int. Ed.
, 43
(19
), pp. 2480
–2495
.10.1002/anie.20030060916.
Beeby
, S.
, Tudor
, M.
, and White
, N.
, 2006
, “Energy Harvesting Vibration Sources for Microsystems Applications
,” Meas. Sci. Technol.
, 12
, pp. R175
–R195
.10.1088/0957-0233/17/12/R0117.
Mitcheson
, P. D.
, Rao
, G. K.
, and Green
, T. C.
, 2008
, “Energy Harvesting From Human and Machine Motion for Wireless Electronic Devices
,” Proc. IEEE
, 96
(9
), pp. 1457
–1486
.10.1109/JPROC.2008.92749418.
Smith
, S. T.
, and Seugling
, R. M.
, 2006
, “Sensor and Actuator Considerations for Precision, Small Machines
,” Precis. Eng.
, 30
(3
), pp. 245
–264
.10.1016/j.precisioneng.2005.10.00319.
Awtar
, S.
, and Slocum
, A. H.
, 2007
, “Constraint-Based Design of Parallel Kinematic XY Flexure Mechanisms
,” ASME J. Mech. Des.
, 129
(8
), pp. 816
–830
.10.1115/1.273534220.
Blanding
, D. L.
, 1999
, Exact Constraint: Machine Design Using Kinematic Principles
, ASME Press
, New York
.21.
Hopkins
, J. B.
, and Culpepper
, M. L.
, 2010
, “Synthesis of Multi-Degree of Freedom, Parallel Flexure System Concepts via Freedom and Constraint Topology (FACT)—Part I: Principles
,” Precis. Eng.
, 34
(2
), pp. 259
–270
.10.1016/j.precisioneng.2009.06.00822.
Su
, H.-J.
, and Tari
, H.
, 2010
, “Realizing Orthogonal Motions With Wire Flexures Connected in Parallel
,” ASME J. Mech. Des.
, 132
(12
), p. 121002
.23.
Awtar
, S.
, Shimotsu
, K.
, and Sen
, S.
, 2010
, “Elastic Averaging in Flexure Mechanisms: A Three-Beam Parallelogram Flexure Case Study
,” J. Mech. Rob.
, 2
(4
), p. 041006
.24.
Culpepper
, M. L.
, and Anderson
, G.
, 2004
, “Design of a Low-Cost Nano-Manipulator Which Utilizes a Monolithic, Spatial Compliant Mechanism
,” Precis. Eng.
, 28
(4
), pp. 469
–482
.10.1016/j.precisioneng.2004.02.00325.
Yamakawa
, K.
, Furutani
, K.
, and Mohri
, N.
, 1999
, “XYZ-Stage for Scanning Probe Microscope by Using Parallel Mechanism
,” Proceedings of ASME DETC
.26.
Li
, Y.
, and Xu
, Q.
, 2005
, “Kinematic Design of a Novel 3-DOF Compliant Parallel Manipulator for Nanomanipulation
,” Proceedings of 2005 IEEE/ASME International Conference on Advanced Intelligent Mechatronics
, Monterey, CA
.27.
Arai
, T.
, Herve
, J. M.
, and Tanikawa
, T.
, 1996
, “Development of 3 DOF Micro Finger
,” Proceedings of Intelligent Robots and Systems '96
.28.
Tang
, X.
, and Chen
, I. M.
, 2006
, “A Large-Displacement and Decoupled XYZ Flexure Parallel Mechanism for Micromanipulation
,” Proceedings of IEEE International Conference on Automation Science and Engineering
.29.
Hao
, G.
, and Kong
, X.
, 2009
, “A 3-DOF Translational Compliant Parallel Manipulator Based on Flexure Motion
,” Proceedings of ASME IDETC
, Paper No. 49040.30.
Li
, F.
, Wu
, M. C.
, Choquette
, K. D.
, and Crawford
, M. H.
, 1997
, “Self-Assembled Microactuated XYZ Stages for Optical Scanning and Alignment
,” Proceedings of Transducers '97
, Chicago
.31.
Ando
, Y.
, 2004
, “Development of Three-Dimensional Electrostatic Stages for Scanning Probe Microscope
,” Sens. Actuators, A
, 114
(2–3
), pp. 285
–291
.10.1016/j.sna.2003.12.00432.
Mcneil
, A. C.
, Li
, G.
, and Koury
, D. N.
, 2005
, “Single Proof Mass 3 Axis MEMS Transducer
,” U.S. Patent No. 6,936,492.33.
Xinyu
, L.
, Kim
, K.
, and Sun
, Y.
, 2007
, “A MEMS Stage for 3-Axis Nanopositioning
,” J. Micromech. Microeng.
, 17
(9
), pp. 1796
–1802
.34.
Sarkar
, N.
, Geisberger
, A.
, and Ellis
, M. D.
, 2004
, “Fully Released MEMS XYZ Flexure Stage With Integrated Capacitive Feedback
,” U.S. Patent No. 6,806,991.35.
XYZ Flexure Demonstration Video
, http://www-personal.umich.edu/∼awtar/XYZ%20flexure%20video1.mp436.
Awtar
, S.
, Slocum
, A. H.
, and Sevincer
, E.
, 2007
, “Characteristics of Beam-Based Flexure Modules
,” ASME J. Mech. Des.
, 129
(6
), pp. 625
–639
.10.1115/1.271723137.
Awtar
, S.
, 2004
, “Synthesis and Analysis of Parallel Kinematic XY Flexure Mechanisms
,” Sc.D. thesis, Massachusetts Institute of Technology
, Cambridge, MA
.38.
Trahair
, N. S.
, 2011
, “Wagner's Beam Cycle
,” Research Report No. R916, School of Civil Engineering, University of Sydney
, NSW, Australia
.39.
Sen
, S.
, 2012
, “Closed Form Analytical Models for Design of Flexure Elements and Mechanisms
,” Ph.D. thesis, University of Michigan
, Ann Arbor, MI
.Copyright © 2013 by ASME
You do not currently have access to this content.
