Abstract
In robotics, the origami-based design methodology uses straightforward fabrication and assembly processes to create small-scale parallel mechanisms. Delta mechanisms are among the well-known parallel mechanisms used mostly in pick-and-place operations due to their capability to reach high speeds and accelerations. In this work, we present a novel Delta mechanism based on origami-inspired designs and two-dimensional layer-by-layer fabrication methods, reducing the time and errors in manufacturing. We developed a new flat parallelogram providing translations in X–Y–Z directions, respecting the Delta mechanism’s conventional kinematic models. The fabrication and assembly processes include laser machining and lamination, eliminating manual-folding and bonding steps. The mechanism operates in a 20 × 20 × 20 mm3 workspace and a 17.5 cm diameter circular footprint when it is entirely flat. The kinematic performance of the mechanism is analyzed using a six degrees-of-freedom position sensor on the end effector. The experiments are conducted to follow circular trajectories with varying radii at different heights. Despite having no feedback control from the end effector, the mechanism follows the given trajectories with 1.5 mm root-mean-square (RMS) precision. We also present the effects of the elasticity of flexible materials at different regions of the mechanism on the performance of the Delta robot.
Issue Section:
Research Papers
References
1.
Zhakypov
, Z.
, and Paik
, J.
, 2018
, “Design Methodology for Constructing Multimaterial Origami Robots and Machines
,” IEEE Trans. Rob.
, 34
(1
), pp. 151
–165
. 10.1109/TRO.2017.27756552.
Doshi
, N.
, Goldberg
, B.
, Sahai
, R.
, Jafferis
, N.
, Aukes
, D.
, Wood
, R. J.
, and Paulson
, J. A.
, 2015
, “Model Driven Design for Flexure-Based Microrobots
,” 2015 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)
, Hamburg, Germany
, Dec.
, pp. 4119
–4126
.3.
Salerno
, M.
, Firouzeh
, A.
, and Paik
, J.
, 2017
, “A Low Profile Electromagnetic Actuator Design and Model for an Origami Parallel Platform
,” ASME J. Mech. Robot.
, 9
(4
), p. 041005
. 10.1115/1.40364254.
Whitney
, J. P.
, Sreetharan
, P. S.
, Ma
, K. Y.
, and Wood
, R. J.
, 2011
, “Pop-Up Book MEMS
,” J. Micromech. Microeng.
, 21
(11
), p. 115021
. 10.1088/0960-1317/21/11/1150215.
Onal
, C. D.
, Wood
, R. J.
, and Rus
, D.
, 2011
, “Towards Printable Robotics: Origami-Inspired Planar Fabrication of Three-Dimensional Mechanisms
,” 2011 IEEE International Conference on Robotics and Automation
, Shanghai, China
, May 9–13
, pp. 4608
–4613
.6.
Aukes
, D. M.
, Goldberg
, B.
, Cutkosky
, M. R.
, and Wood
, R. J.
, 2014
, “An Analytic Framework for Developing Inherently-Manufacturable Pop-Up Laminate Devices
,” Smart Mater. Struct.
, 23
(9
), p. 094013
. 10.1088/0964-1726/23/9/0940137.
Baisch
, A. T.
, Ozcan
, O.
, Goldberg
, B.
, Ithier
, D.
, and Wood
, R. J.
, 2014
, “High Speed Locomotion for a Quadrupedal Microrobot
,” Int. J. Rob. Res.
, 33
(8
), pp. 1063
–1082
. 10.1177/02783649145214738.
Birkmeyer
, P.
, Peterson
, K.
, and Fearing
, R. S.
, 2009
, “DASH: A Dynamic 16g Hexapedal Robot
,” 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)
, St. Louis, MO
, Oct. 10–15
, pp. 2683
–2689
.9.
Koh
, J. S.
, Yang
, E.
, Jung
, G.-P.
, Jung
, S.-P.
, Son
, J. H.
, Lee
, S.-I.
, Jablonski
, P. G.
, Wood
, R. J.
, Kim
, H.-Y.
, and Cho
, K.-J.
, 2015
, “Jumping on Water: Surface Tension-Dominated Jumping of Water Striders and Robotic Insects
,” Science
, 349
(6247
), pp. 517
–521
. 10.1126/science.aab163710.
Wood
, R. J.
, 2008
, “The First Takeoff of a Biologically Inspired At-Scale Robotic Insect
,” IEEE Trans. Rob.
, 24
(2
), pp. 341
–347
. 10.1109/TRO.2008.91699711.
Wood
, R. J.
, Avadhanula
, S.
, Sahai
, R.
, Steltz
, E.
, and Fearing
, R. S.
, 2008
, “Microrobot Design Using Fiber Reinforced Composites
,” ASME J. Mech. Des.
, 130
(5
), p. 052304
. 10.1115/1.288550912.
Wood
, R. J.
, Finio
, B.
, Karpelson
, M.
, Ma
, K.
, Pérez-Arancibia
, N. O.
, Sreetharan
, P. S.
, Tanaka
, H.
, and Whitney
, J. P.
, 2012
, “Progress on ‘Pico’ Air Vehicles
,” Int. J. Rob. Res.
, 31
(11
), pp. 1292
–1302
. 10.1177/027836491245507313.
Salerno
, M.
, Zhang
, K.
, Menciassi
, A.
, and Dai
, J. S.
, 2014
, “A Novel 4-DOFs Origami Enabled, SMA Actuated, Robotic End-Effector for Minimally Invasive Surgery
,” 2014 IEEE International Conference on Robotics and Automation (ICRA)
, Hong Kong, China
, May 31–June 7
, pp. 2844
–2849
.14.
Gafford
, J.
, Ranzani
, T.
, Russo
, S.
, Aihara
, H.
, Thompson
, C.
, Wood
, R.
, and Walsh
, C.
, 2016
, “Snap-On Robotic Wrist Module for Enhanced Dexterity in Endoscopic Surgery
,” 2016 IEEE International Conference on Robotics and Automation (ICRA)
, Stockholm, Sweden
, June
, pp. 4398
–4405
.15.
Russo
, S.
, Ranzani
, T.
, Gafford
, J.
, Walsh
, C. J.
, and Wood
, R. J.
, 2016
, “Soft Pop-Up Mechanisms for Micro Surgical Tools: Design and Characterization of Compliant Millimeter-Scale Articulated Structures
,” 2016 IEEE International Conference on Robotics and Automation (ICRA)
, Stockholm, Sweden
, June
, pp. 750
–757
.16.
Felton
, S.
, Tolley
, M.
, Demaine
, E.
, Rus
, D.
, and Wood
, R.
, 2014
, “A Method for Building Self-Folding Machines
,” Science
, 345
(6197
), pp. 644
–646
. 10.1126/science.125261017.
Zhakypov
, Z.
, Mete
, M.
, Fiorentino
, J.
, and Paik
, J.
, 2019
, “Programmable Fluidic Networks Design for Robotic Origami Sequential Self-Folding
,” 2019 2nd IEEE International Conference on Soft Robotics (RoboSoft)
, Seoul, South Korea
, Apr. 14–18
, pp. 814
–820
.18.
Zhang
, K.
, and Dai
, J. S.
, 2013
, “Classification of Origami-Enabled Foldable Linkages and Emerging Applications
,” Volume 6B: 37th Mechanisms and Robotics Conference
, Portland, OR
, Aug.
, pp. 1
–9
.19.
Rodriguez Leal
, E.
, and Dai
, J. S.
, 2007
, “From Origami to a New Class of Centralized 3-DOF Parallel Mechanisms
,” Volume 8: 31st Mechanisms and Robotics Conference, Parts A and B
, Las Vegas, NV
, Jan.
, pp. 1183
–1193
.20.
Demaurex
, M.-O.
, 1999
, “The Delta Robot Within the Industry,” Parallel Kinematic Machines
, C. R.
Boër
, L.
Molinari-Tosatti
, and K. S.
Smith
, eds., Springer
, London
, pp. 395
–399
.21.
López
, M.
, Castillo
, E.
, García
, G.
, and Bashir
, A.
, 2006
, “Delta Robot: Inverse, Direct, and Intermediate Jacobians
,” Proc. Inst. Mech. Eng. Part C J. Mech. Eng. Sci.
, 220
(1
), pp. 103
–109
. 10.1243/095440606X7826322.
Tanikawa
, T.
, Ukiana
, M.
, Morita
, K.
, Koseki
, Y.
, Ohba
, K.
, Fujii
, K.
, and Arai
, T.
, 2002
, “Design of 3DOF Parallel Mechanism With Thin Plate for Micro Finger Module in Micro Manipulation
,” IEEE/RSJ International Conference on Intelligent Robots and Systems
, Lausanne, Switzerland
, Oct.
, Vol. 2
, pp. 1778
–1783
.23.
Rey
, L.
, and Clavel
, R.
, 1999
, “The Delta Parallel Robot,” Parallel Kinematic Machines
, Vol. 53
, 9, C. R.
Boër
, L.
Molinari-Tosatti
, and K. S.
Smith
, eds., Springer
, London
, pp. 401
–417
.24.
Correa
, J. E.
, Toombs
, J.
, Toombs
, N.
, and Ferreira
, P. M.
, 2016
, “Laminated Micro-Machine: Design and Fabrication of a Flexure-Based Delta Robot
,” J. Manuf. Process.
, 24
(Part 2
), pp. 370
–375
. 10.1016/j.jmapro.2016.06.01625.
McClintock
, H.
, Temel
, F. Z.
, Doshi
, N.
, Koh
, J. S.
, and Wood
, R. J.
, 2018
, “The MilliDelta: A High-Bandwidth, High-Precision, Millimeter-Scale Delta Robot
,” Sci. Robot.
, 3
(14
), p. eaar3018
. 10.1126/scirobotics.aar301826.
Kosinska
, A.
, Galicki
, M.
, and Kedzior
, K.
, 2003
, “Designing and Optimization of Parameters of Delta-4 Parallel Manipulator for a Given Workspace
,” J. Robot. Syst.
, 20
(9
), pp. 539
–548
. 10.1002/rob.1010427.
Jian
, S.
, and Lou
, Y.
, 2017
, “Application of Motion Control System for Delta Parallel Robot
,” 2017 IEEE International Conference on Information and Automation (ICIA)
, Macau, China
, July
, pp. 732
–736
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