Abstract
Redundantly actuated parallel manipulators with two rotations and one translation (2R1T RAPMs) have the potential for machining complex surfaces, where a large orientation workspace and high stiffness are required. Considering the advantages of an offset moving platform, such as an enlarged orientation workspace and improved stiffness, a novel 2R1T (2PRR)R-PRS-PSS RAPM with an offset moving platform is proposed in this paper, called M2. Compared with the existing 2R1T RAPM with an offset moving platform, the main advantage of the proposed RAPM is that the heavy motors of four limbs are mounted on the base to reduce the movable mass and improve dynamic response. The kinematical analysis is investigated, including mobility, inverse, forward kinematics, and singularity analysis. Meanwhile, comprehensive evaluations of the properties of the offset moving platform and actuation redundancy are carried out. Compared with M2 RAPM’s form without an offset in moving platform, i.e., no auxiliary platform, and M2 RAPM’s nonredundantly actuated form, the proposed M2 RAPM can achieve a larger orientation workspace and higher stiffness. Particularly, the maximum stiffness of the proposed M2 is 68.8% larger than its form without an auxiliary platform. Finally, the dimensional parameters of the proposed M2 are optimized to obtain an improved satisfactory workspace.
Issue Section:
Research Papers
References
1.
Chen
, Z.
, Li
, M.
, Kong
, X.
, and Zhao
, C.
, 2020
, “Kinematics Analysis of a Novel 2R1T 3-PUU Parallel Mechanism With Multiple Rotation Centers
,” Mech. Mach. Theory
, 152
, p. 103938
. 2.
Wang
, L.
, Fang
, Y.
, Qu
, H.
, and Li
, L.
, 2020
, “Design and Analysis of Novel 2R1T Generalized Parallel Mechanisms With Large Rotational Angles
,” Mech. Mach. Theory
, 150
, p. 103879
. 3.
Xu
, Y.
, Zhao
, Y.
, Yue
, Y.
, Xi
, F.
, Yao
, J.
, and Zhao
, Y.
, 2020
, “Type Synthesis of Overconstrained 2R1T Parallel Mechanisms With the Fewest Kinematic Joints Based on the Ultimate Constraint Wrenches
,” Mech. Mach. Theory
, 147
, p. 103766
. 4.
Xu
, L.
, Li
, Q.
, Zhang
, N.
, and Chen
, Q.
, 2017
, “Mobility, Kinematic Analysis, and Dimensional Optimization of New Three-Degrees-of-Freedom Parallel Manipulator With Actuation Redundancy
,” ASME J. Mech. Rob.
, 9
(4
), p. 041008
. 5.
Wahl
, J.
, 2000
, “Articulated Tool Head,” WIPO Patent No. WO/2000/025976.6.
Siciliano
, B.
, 1999
, “The Tricept Robot: Inverse Kinematics, Manipulability Analysis and Closed-Loop Direct Kinematics Algorithm
,” Robotica
, 17
(4
), pp. 437
–445
. 7.
Bi
, Z.
, and Jin
, Y.
, 2011
, “Kinematic Modeling of Exechon Parallel Kinematic Machine
,” Rob. Comput. Integr. Manuf.
, 27
(1
), pp. 186
–193
. 8.
Xu
, Y.
, Zhang
, D.
, Yao
, J.
, and Zhao
, Y.
, 2017
, “Type Synthesis of the 2R1T Parallel Mechanism With Two Continuous Rotational Axes and Study on the Principle of Its Motion Decoupling
,” Mech. Mach. Theory
, 108
, pp. 27
–40
. 9.
Li
, Q.
, and Hervé
, J. M.
, 2010
, “1T2R Parallel Mechanisms Without Parasitic Motion
,” IEEE Trans. Rob.
, 26
(3
), pp. 401
–410
. 10.
Hennes
, N.
, 2002
, “Ecospeed: An Innovative Machining Concept for High Performance 5-Axis-Machining of Large Structural Component in Aircraft Engineering
,” Proceedings of the Third Chemnitz Parallel Kinematics Seminar
, Chemnitz, Germany
, Apr. 23–25
, pp. 763
–774
.11.
Gosselin
, C.
, and Schreiber
, L.-T.
, 2018
, “Redundancy in Parallel Mechanisms: A Review
,” Appl. Mech. Rev.
, 70
(1
), p. 010802
. 12.
Saglia
, J. A.
, Dai
, J. S.
, and Caldwell
, D. G.
, 2008
, “Geometry and Kinematic Analysis of a Redundantly Actuated Parallel Mechanism That Eliminates Singularities and Improves Dexterity
,” ASME J. Mech. Des.
, 130
(12
), p. 124501
. 13.
Wang
, L.
, Yu
, G.
, and Wu
, J.
, 2017
, “A Comparison Study on the Stiffness and Natural Frequency of a Redundant Parallel Conveyor and Its Nonredundant Counterpart
,” Adv. Mech. Eng.
, 9
(11
), p. 1687814017733690
. 14.
Kumar
, V.
, and Gardner
, J.
, 1990
, “Kinematics of Redundantly Actuated Closed Chains
,” IEEE Trans. Rob. Autom.
, 6
(2
), pp. 269
–274
. 15.
Shen
, X.
, Xu
, L.
, and Li
, Q.
, 2021
, “Motion/Force Constraint Indices of Redundantly Actuated Parallel Manipulators With Over Constraints
,” Mech. Mach. Theory
, 165
, p. 104427
. 16.
Li
, Q.
, Zhang
, N.
, and Wang
, F.
, 2017
, “New Indices for Optimal Design of Redundantly Actuated Parallel Manipulators
,” ASME J. Mech. Rob.
, 9
(1
), p. 011007
. 17.
Fang
, H.
, Tang
, T.
, and Zhang
, J.
, 2019
, “Kinematic Analysis and Comparison of a 2R1T Redundantly Actuated Parallel Manipulator and Its Non-redundantly Actuated Forms
,” Mech. Mach. Theory
, 142
, p. 103587
. 18.
Wang
, Y.
, Belzile
, B.
, Angeles
, J.
, and Li
, Q.
, 2019
, “Kinematic Analysis and Optimum Design of a Novel 2PUR-2RPU Parallel Robot
,” Mech. Mach. Theory
, 139
, pp. 407
–423
. 19.
Li
, Q.
, and Hervé
, J. M.
, 2014
, “Type Synthesis of 3-DOF RPR-Equivalent Parallel Mechanisms
,” IEEE Trans. Rob.
, 30
(6
), pp. 1333
–1343
. 20.
Xu
, L.
, Chai
, X.
, Li
, Q.
, Zhang
, L.
, and Ye
, W.
, 2019
, “Design and Experimental Investigation of a New 2R1T Overconstrained Parallel Kinematic Machine With Actuation Redundancy
,” ASME J. Mech. Rob.
, 11
(3
), p. 031016
. 21.
Xu
, L.
, Li
, Q.
, Tong
, J.
, and Chen
, Q. C.
, 2018
, “Tex3: An 2R1T Parallel Manipulator With Minimum DoF of Joints and Fixed Linear Actuators
,” Int. J. Precis. Eng. Manuf.
, 19
(2
), pp. 227
–238
. 22.
Wang
, D.
, Fan
, R.
, and Chen
, W.
, 2014
, “Performance Enhancement of a Three-Degree-of-Freedom Parallel Tool Head Via Actuation Redundancy
,” Mech. Mach. Theory
, 71
, pp. 142
–162
. 23.
Xu
, L.
, Chai
, X.
, Lin
, Z.
, and Ding
, Y.
, 2022
, “Kinematic Analysis and Optimization of a New 2R1T Redundantly Actuated Parallel Manipulator With Two Moving Platforms
,” International Conference on Intelligent Robotics and Applications (ICIRA)
, Harbin, China
, Aug. 1–3
, pp. 47
–57
.24.
Huang
, Z.
, and Li
, Q.
, 2002
, “General Methodology for Type Synthesis of Symmetrical Lower-Mobility Parallel Manipulators and Several Novel Manipulators
,” Int. J. Rob. Res.
, 21
(2
), pp. 131
–145
. 25.
Huang
, Z.
, Liu
, J.
, and Zeng
, D.
, 2009
, “A general methodology for mobility analysis of mechanisms based on constraint screw theory
,” Sci. China Ser. E-Technol. Sci.
, 39
(1
), pp. 84
–93
. 26.
Merlet
, J.-P.
, 1993
, “Direct Kinematics of Parallel Manipulators
,” IEEE Trans. Rob. Autom.
, 9
(6
), pp. 842
–846
. 27.
Gosselin
, C.
, and Angeles
, J.
, 1990
, “Singularity Analysis of Closed-Loop Kinematic Chains
,” IEEE Trans. Rob. Autom.
, 6
(3
), pp. 281
–290
. 28.
Liu
, X.
, and Wang
, J.
, 2007
, “A New Methodology for Optimal Kinematic Design of Parallel Mechanisms
,” Mech. Mach. Theory
, 42
(9
), pp. 1210
–1224
. 29.
Karnam
, M. K.
, Baskar
, A.
, Srivatsan
, R. A.
, and Bandyopadhyay
, S.
, 2020
, “Computation of the Safe Working Zones of Planar and Spatial Parallel Manipulators
,” Robotica
, 38
(5
), pp. 861
–885
. 30.
Jin
, S.
, Kim
, J.
, and Seo
, T.
, 2015
, “Optimization of a Redundantly Actuated 5R Symmetrical Parallel Mechanism Based on Structural Stiffness
,” Robotica
, 33
(9
), pp. 1973
–1983
. 31.
Tian
, Q.
, Flores
, P.
, and Lankarani
, H. M.
, 2018
, “A Comprehensive Survey of the Analytical, Numerical and Experimental Methodologies for Dynamics of Multibody Mechanical Systems With Clearance or Imperfect Joints
,” Mech. Mach. Theory
, 122
, pp. 1
–57
. 32.
Joshi
, S.
, and Tsai
, L.-W.
, 2003
, “A Comparison Study of Two 3-DOF Parallel Manipulators: One With Three and the Other With Four Supporting Legs
,” IEEE Trans. Rob. Autom.
, 19
(2
), pp. 200
–209
. 33.
Wang
, C.
, Fang
, Y.
, Guo
, S.
, and Chen
, Y.
, 2013
, “Design and Kinematical Performance Analysis of a 3-RUS/RRR Redundantly Actuated Parallel Mechanism for Ankle Rehabilitation
,” ASME J. Mech. Rob.
, 5
(4
), p. 041003
. 34.
Gosselin
, C.
, 1990
, “Stiffness Mapping for Parallel Manipulators
,” IEEE Trans. Rob. Autom.
, 6
(3
), pp. 377
–382
. 35.
Wang
, J.
, Wu
, C.
, and Liu
, X.
, 2010
, “Performance Evaluation of Parallel Manipulators: Motion/Force Transmissibility and Its Index
,” Mech. Mach. Theory
, 45
(10
), pp. 1462
–1476
. 36.
Tao
, D. C.
, 1964
, Applied Linkage Synthesis
, Addison-Wesley
, Reading, MA
.Copyright © 2023 by ASME
You do not currently have access to this content.
