KINEMATICS MODELLING AND OPTIMIZATION DESIGN OF A 5-DOF HYBRID MANIPULATOR

Dongsheng Zhang, Yundou Xu, Jiantao Yao, and Yongsheng Zhao

References

  1. [1] B. Dasgupta and T. S. Mruthyunjaya, The Stewart platform manipulator: A review, Mechanism and Machine Theory, 35(1), 2000, 15–40.
  2. [2] Y. Cao, W. Ji, H. Zhou, and Q. Zhang, Position-singularity analysis of 6-3 Stewart-Gough parallel manipulators for special orientations, International Journal of Robotics and Automation, 26(2), 2011, 152–158.
  3. [3] Y. Zhao, H. Yu, J. Zhang, J. Yang, and T. Zhao, Kinematics, dynamics and control of a stabilized platform with a 6-RUS parallel mechanism, International Journal of Robotics and Automation, 32(3), 2017, 283–290.
  4. [4] J. Wu, X. Chen, and L. Wang, Design and dynamics of a novel solar tracker with parallel mechanism, IEEE/ASME Transactions on Mechatronics, 21(1), 2016, 88–97.
  5. [5] D. Zhang, Y. Xu, J. Yao, Y. Zhao, and B. Hu. Kinematics, dynamics and stiffness analysis of a novel 3-DOF kinematically/actuation redundant planar parallel mechanism, Mechanism and Machine Theory, 116, 2017, 203–219.
  6. [6] J. Wu, J. Wang, L. Wang, and T. Li, Dynamics and control of a planar 3-DOF parallel manipulator with actuation redundancy, Mechanism and Machine Theory, 44(4), 2009, 835–849.
  7. [7] Q. Li and J. Hervé, Type synthesis of 3-DOF RPR-equivalent parallel mechanisms, IEEE Transactions on Robotics, 30(6), 2014, 1333–1343.
  8. [8] J. Zhao, B. Huang, and D. Hua, A study of sharp increase phenomenon in constraint torque on the universal joint of 3-PUU parallel manipulator, International Journal of Robotics and Automation, 29(4), 2014, 378–386.
  9. [9] B. Hu, B. Mao, J. Yu, and Y. Lu, Unified stiffness model of lower mobility parallel manipulators with linear active legs, International Journal of Robotics and Automation, 29(1), 2014, 58–66.
  10. [10] J. Zhang, Y. Zhao, and Y. Jin, Elastodynamic modeling and analysis for an Exechon parallel kinematic machine, Journal of Manufacturing Science and Engineering, 138(3), 2016, 031011.
  11. [11] J. Shi, Y. Wang, G. Zhang, and H. Ding, Optimal design of 3-DOF PKM module for friction stir welding, International Journal of Advanced Manufacturing Technology, 66(9–12), 2013, 1879–1889.
  12. [12] Q. Li, Z. Chen, Q. Chen, C. Wu, and X. Hu, Parasitic motion comparison of 3-PRS parallel mechanism with different limb arrangements, Robotics and Computer-Integrated Manufacturing, 27(2), 2011, 389–396.
  13. [13] J. Shao, W. Chen, and X. Fu, Position, singularity and workspace analysis of 3-PSR-O spatial parallel manipulator, Chinese Journal of Mechanical Engineering, 28(03), 2015, 437–450.
  14. [14] L. Wang, H. Xu, L. Guan, and Z. Zhi, A novel 3-PUU parallel mechanism and its kinematic issues, Robotics and ComputerIntegrated Manufacturing, 42, 2016, 86–102.
  15. [15] Y. Xu, D. Zhang, J. Yao, and Y. Zhao, Type synthesis of the 2R1T parallel mechanism with two continuous rotational axes and study on the principle of its motion decoupling, Mechanism and Machine Theory, 108, 2017, 27–40.
  16. [16] Q. Li, Q. Chen, C. Wu, and Z. Huang, Geometrical distribution of rotational axes of 3-[P][S] parallel mechanisms, Mechanism and Machine Theory, 65, 2013, 46–57.
  17. [17] Y. Xu, S. Zhou, J. Yao, and Y. Zhao, Rotational axes analysis of the 2-RPU/SPR 2R1T parallel mechanism, in Marco Ceccarelli, Victor A. Glazunov (eds.) Advances on Theory and Practice of Robots and Manipulators (New York, Dordrecht London: Springer Cham Heidelberg, 2014), 113–121.
  18. [18] Q. Li, X. Chai, Q. Chen, and H. Zhen, Analysis of rotational axes of 2-UPR-SPR parallel mechanism, Chinese Journal of Mechanical Engineering, 49(21), 2013, 62–69.
  19. [19] Y. Song, B. Lian, T. Sun, G. Dong, and H. Gao, A novel five-degree-of-freedom parallel manipulator and its kinematic optimization, Journal of Mechanisms and Robotics, 6(4), 2014, 041008.
  20. [20] J. Wu, D. Wang, and L. Wang, A control strategy of a two degrees-of-freedom heavy duty parallel manipulator, Journal of Dynamic Systems, Measurement, and Control, 137(6), 2015, 061007.
  21. [21] H. Ghaffari, G. Payeganeh, and M. Arbabtafti, Kinematic design of a novel 4-DOF parallel mechanism for turbine blade machining, International Journal of Advanced Manufacturing Technology, 74(5–8), 2014, 729–739.
  22. [22] V. Poppeova, J. Uricek, and V. Bulej, The development of mechanism based on hybrid kinematic structure, Development, 2011, 228–229.
  23. [23] S. Lee and S. Kim, Efficient inverse kinematics for serial connections of serial and parallel manipulators, Proc. 1993 IEEE/RSJ Int. Conf. on Intelligent Robots and Systems’ 93, IROS’93, IEEE, Yokohama, Japan, 3, 1993, 1635–1641.
  24. [24] J. Gallardo-Alvarado, Kinematics of a hybrid manipulator by means of screw theory, Multibody System Dynamics, 14(3), 2005, 345–366.
  25. [25] G. Yang, I. Chen, and S. Yeo, Design and analysis of a modular hybrid parallel-serial manipulator for robotised deburring applications, in Lihui Wang, Jeff Xi (eds.) Smart devices and machines for advanced manufacturing (Springer, London), 2008, 167–188.
  26. [26] D. Zhang, Y. Xu, J. Yao, and Y. Zhao, Analysis and optimization of a spatial parallel mechanism for a new 5-DOF hybrid serial-parallel manipulator, Chinese Journal of Mechanical Engineering. DOI: 10.1186/s10033-018-0251-4.
  27. [27] C. Fan, H. Liu, and Y. Zhang, Type synthesis of 2T2R, 1T2R and 2R parallel mechanisms, Mechanism and Machine Theory, 61, 2013, 184–190.
  28. [28] F. Xie, X. Liu, Z. You, and J. Wang, Type synthesis of 2T1R-type parallel kinematic mechanisms and the application in manufacturing, Robotics and Computer-Integrated Manufacturing, 30(1), 2014, 1–10.
  29. [29] G. Wu, S. Caro, and J. Wang, Design and transmission analysis of an asymmetrical spherical parallel manipulator, Mechanism and Machine Theory, 94, 2015, 119–131.
  30. [30] B. He, L. Han, Y. Wang, S. Huang, and L. Liu, Kinematics analysis and numerical simulation of a manipulator based on virtual prototyping, International Journal of Advanced Manufacturing Technology, 71(5–8), 2014, 943–963.
  31. [31] M. Shahhosseini, R. Rastegari, and R. Abbasi, A new 6 DOF robotic arm with linkage motion mechanism and actuators placed in base, International Journal of Robotics and Automation, 5(1), 2016, 35–48.
  32. [32] Y. Lu, Y. Shi, and J. Yu, Kinematic analysis of limitedDOF parallel manipulators based on translational/rotational Jacobian and Hessian matrices, Robotica, 27(07), 2009, 971–980.
  33. [33] Y. Zhao, Dynamic optimum design of a three translational degrees of freedom parallel robot while considering anisotropic property, Robotics and Computer-Integrated Manufacturing, 29(4), 2013, 100–112.
  34. [34] X. Guo and Q. Geng, Analysis for acceleration performance indices of serial robots, Chinese Journal of Mechanical Engineering, 44(9), 2008, 56–60.
  35. [35] J. Wu, X. Chen, T. Li, and L. Wang, Optimal design of a 2-DOF parallel manipulator with actuation redundancy considering kinematics and natural frequency, Robotics and ComputerIntegrated Manufacturing, 29(1), 2013, 80–85.

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