DYNAMIC PERFORMANCE EVALUATION OF A THREE TRANSLATIONAL DEGREES OF FREEDOM PARALLEL ROBOT

Yongjie Zhao

References

1. [1] Y. Lu, B. Hu, and J. Yu, Unification and simplification ofdynamics of limited-DOF parallel manipulators with linearactive legs, International Journal of Robotics and Automation,25 (25), 2010, 45–53.
2. [2] L.W. Tsai and S. Joshi, Kinematics and optimization of a spatial3-UPU parallel manipulator, ASME Journal of MechanicalDesign, 122 (4), 2000, 439–446.
3. [3] Y. Lu, CAD variation geometry and analytic approach for solv-ing kinematics of a novel 3-SPU/3-SPU parallel manipulator,ASME Journal of Mechanical Design, 128 (3), 2006, 574–580.
4. [4] B. Hu and Y. Lu, Analyses of kinematics, statics, and workspaceof a 3-RRPRR parallel manipulator and its three isomericmechanisms, Proceedings of the Institution of Mechanical En-gineers C, 222 (9), 2008, 1829–1837.
5. [5] M. Stock and K. Miller, Optimal kinematic design of spatialparallel manipulators: Application to linear delta robot, ASMEJournal of Mechanical Design, 125 (2), 2003, 292–301.
6. [6] K.S. Hsu, M. Karkoub, M.C. Tsai, and M.G. Her, Modellingand index analysis of a Delta-type mechanism, Proceedingsof the Institution of Mechanical Engineers K, 218 (3), 2004,121–132.
7. [7] K.S. Hsu, T.S. Lan, and M.G. Her, Modeling and indexanalysis of the hexaglide type mechanism, Proceedings ofIEEE International Conference on Multisensor Fusion andIntegration for Intelligent Systems, Japan, Tokyo, 2003, 32–37.
8. [8] I. Bonev, Delta parallel robot – The story of success, Newsletter,2001, http://www.parallelmic.org.
9. [9] R. Clavel, Delta, a fast robot with parallel geometry, The18th International Symposium on Industrial Robots (ISIR),Australia, Sydney, 1988, 91–100.
10. [10] S. Staicu, Recursive modelling in dynamics of Delta parallelrobot, Robotica, 27 (2), 2009, 199–207.
11. [11] A. Codourey, Dynamic modeling of parallel robots forcomputed-torque control implementation, The InternationalJournal of Robotics Research, 17 (2), 1998, 1325–1336.
12. [12] Y.J. Zhao, Z.Y. Yang, and T. Huang, Inverse dynamics of Deltarobot based on the principle of virtual work, Transactions ofTianjin University, 11 (4), 2005, 268–273.
13. [13] J. Hong and M. Yamamoto, A calculation method of thereaction force and moment for a Delta-type parallel link robotfixed with a frame, Robotica, 27 (4), 2009, 579–587.
14. [14] Y.M. Li and Q.S. Xu, Dynamics analysis of modified Deltaparallel robot for cardiopulmonary resuscitation, IEEE/RSJInternational Conference on Intelligent Robotics and Systems,Centre Edmont, Alberta, Canada, 2005, 3371–3376.
15. [15] A. Fumagalli and P. Masarati, Real-time inverse dynamics con-trol of parallel manipulators using general-purpose multibodysoftware, Multibody System Dynamics, 22 (1), 2009, 47–68.
16. [16] O. Ma and J. Angeles, The concept of dynamics isotropy andits applications to inverse kinematics and trajectory planning,Proceedings of the IEEE International Conference on Roboticsand Automation, Cincinnati, 1990, 481–486.
17. [17] O. Ma and J. Angeles, Optimum design of manipulators underdynamic isotropy conditions, Proceedings of the IEEE Interna-tional Conference on Robotics and Automation, Atlanta, 1993,470–475.
18. [18] H. Asada, A geometrical representation of manipulator dynam-ics and its application to arm design, ASME Journal DynamicSystems, Measurement, and Control, 105 (3), 1983, 131–135.
19. [19] H. Asada, Dynamic analysis and design of robot manipulatorsusing inertia ellipsoids, Proceedings of the IEEE InternationalConference on Robotics and Automation, Atlanta, 1984,94–102.
20. [20] T. Yoshikawa, Dynamic manipulability of robot manipulators,Journal of Robotic Systems, 2 (1), 1985, 113–124.
21. [21] P. Chiacchio and M. Concilio, The dynamics manipulabilityellipsoid for redundant manipulators, Proceedings of the IEEE39International Conference on Robotics and Automation, Leuven,Belgium, 1998, 95–100.
22. [22] P. Chiacchio, S. Chiaverini, and L. Sciavicco, Reformulationof dynamic manipulability ellipsoid for robotic manipulators,Proceedings of the IEEE International Conference on Roboticsand Automation, California, 1991, 2192–2197.
23. [23] F.C. Park and J.W. Kim, Manipulability of closed kinematicchains, ASME Journal of Mechanical Design, 120 (4), 1998,542–548.
24. [24] R.D. Gregorio and V. Parenti-Castelli, Dynamic perfor-mance characterization of three-DOF parallel manipulators,in J. Lenarcic, and F. Thomas (eds.), Advances in robotkinematics: Theory and applications (Netherlands: KluwerAcademic Publishers, 2002), 11–20.
25. [25] T. Huang, J.P. Mei, and Z.X. Li, A method for estimatingservomotor parameters of a parallel robot for rapid pick-and-place operations, ASME Journal of Mechanical Design, 127 (4),2005, 596–601.
26. [26] M. Li, T. Huang, and J.P. Mei, Dynamic formulation andperformance comparison of the 3-DOF modules of two recon-figurable PKMs – The TriVariant and the Tricept, ASMEJournal of Mechanical Design, 127 (6), 2005, 1129–1136.
27. [27] Y.J. Zhao and F. Gao, Dynamic formulation and performanceevaluation of the redundant parallel manipulator, Robotics andComputer-Integrated Manufacturing, 25 (4–5), 2009, 770–781.
28. [28] Y.J. Zhao and F. Gao, The joint velocity, torque and powercapability evaluation of a redundant parallel manipulator,Robotica, 29 (3), 2011, 483–493.
29. [29] Y.J. Zhao and F. Gao, Dynamic performance comparison of the8PSS redundant parallel manipulator and its non-redundantcounterpart – The 6PSS parallel manipulator, Mechanism andMachine Theory, 44 (5), 2009, 991–1008.
30. [30] Y.J. Zhao and F. Gao, Inverse dynamics of the 6-DOF out-parallel manipulator by means of the principle of virtual work,Robotica, 27 (2), 2009, 259–268.
31. [31] L.W. Tsai, Solving the inverse dynamics of a Stewart–Goughmanipulator by the principle of virtual work, ASME Journalof Mechanical Design, 122 (1), 2000, 3–9.

Important Links:

• Abstract
• DOI: 10.2316/Journal.206.2012.1.206-3581
• From Journal (206) International Journal of Robotics and Automation - 2012

Go Back