STRUCTURAL SYNTHESIS OF A CLASS OF RECONFIGURABLE PARALLEL MANIPULATORS BASED ON OVER-CONSTRAINED MECHANISMS

Guanyu Huang, Dan Zhang, Sheng Guo, Haibo Qu

References

  1. [1] GOSSELIN C-M, ZHANG Dan. Stiffness Analysis of Parallel Mechanisms Using a LumpedModel[J]. International Journal of Robotics & Automation, 2002, 17(1): 17–27.
  2. [2] HUANG Guanyu, GUO Sheng, ZHANG Dan et al. Kinematic Analysis and Multi-ObjectiveOptimization of a New Reconfigurable Parallel Mechanism with High Stiffness[J]. Robotica,2018, 36(2): 187–203.
  3. [3] ZHANG Dan, BI Zhuming, LI Beizhi. Design and Kinetostatic Analysis of a New ParallelManipulator[J]. Robotics and Computer-Integrated Manufacturing, 2009, 25(4): 782–791.
  4. [4] ZHANG Dan, LANG Sherman-Y-T. Stiffness Modeling for a Class of Reconfigurable Pkms withThree to Five Degrees of Freedom[J]. Journal of Manufacturing Systems, 2004, 23(4): 316–327.
  5. [5] ZHANG Dan, GOSSELIN Clement-M. Kinetostatic Modeling of Parallel Mechanisms with aPassive Constraining Leg and Revolute Actuators[J]. Mechanism and Machine Theory, 2002,37(6): 599–617.
  6. [6] ZHANG Dan, GOSSELIN Clement-M. Kinetostatic Modeling of N-Dof Parallel Mechanismswith a Passive Constraining Leg and Prismatic Actuators[J]. Journal of Mechanical Design, 2000,123(3): 375–381.
  7. [7] COPPOLA Gianmarc, ZHANG Dan, LIU Kefu. A 6-Dof Reconfigurable Hybrid ParallelManipulator[J]. Robotics and Computer-Integrated Manufacturing, 2014, 30(2): 99–106.
  8. [8] ZHANG Ketao, DAI Jian-S, FANG Yuefa. Topology and Constraint Analysis of Phase Changein the Metamorphic Chain and its Evolved Mechanism[J]. Journal of Mechanical Design, 2010,132(12): 1–11.
  9. [9] DAI Jiansheng, WANG D, CUI L. Orientation and Workspace Analysis of the Multifingered(DOI: 10.2316/J.2019.206-5495)Metamorphic Hand-Metahand[J]. IEEE Transactions on Robotics, 2009, 25(4): 942–947.
  10. [10] ZHANG Liping, WANG Delun, DAI Jiansheng. Biological Modeling and Evolution BasedSynthesis of Metamorphic Mechanisms[J]. Journal of Mechanical Design, 2008, 130(7): 1–11.
  11. [11] ZHANG Liping, DAI Jian-S. Reconfiguration of Spatial Metamorphic Mechanisms[J]. Journal ofMechanisms and Robotics, 2008, 1(1): 1–8.
  12. [12] DAI Jian-S, WANG Delun. Geometric Analysis and Synthesis of the Metamorphic RoboticHand[J]. Journal of Mechanical Design, 2006, 129(11): 1191–1197.
  13. [13] GAN Dongming, DAI Jian-S, CALDWELL Darwin-G. Constraint-Based Limb Synthesis andMobility-Change-Aimed Mechanism Construction[J]. Journal of Mechanical Design, 2011,133(5): 1–9.
  14. [14] GAN Dongming, DAI Jian-S, LIAO Qizheng. Constraint Analysis On Mobility Change of aNovel Metamorphic Parallel Mechanism[J]. Mechanism and Machine Theory, 2010, 45(12):1864–1876.
  15. [15] GAN Dongming, DAI Jian-S, LIAO Qizheng. Mobility Change in Two Types of MetamorphicParallel Mechanisms[J]. Journal of Mechanisms and Robotics, 2009, 1(4): 1–9.
  16. [16] WOHLHART K. Kinematotropic Linkages[Z]. Lenar V C I V C J, Parenti-Castelli V. Dordrecht:Springer Netherlands, 1996359–368.
  17. [17] YE Wei, FANG Yuefa, ZHANG Ketao et al. Mobility Variation of a Family of MetamorphicParallel Mechanisms with Reconfigurable Hybrid Limbs[J]. Robotics and Computer-IntegratedManufacturing, 2016, 41: 145–162.
  18. [18] YE Wei, FANG Yuefa, GUO Sheng. Design and Analysis of a Reconfigurable ParallelMechanism for Multidirectional Additive Manufacturing[J]. Mechanism and Machine Theory,2016, 112: 307–326.
  19. [19] YE Wei, FANG Yuefa, ZHANG Ketao et al. A New Family of Reconfigurable ParallelMechanisms with Diamond Kinematotropic Chain[J]. Mechanism and Machine Theory, 2014, 74:1–9.
  20. [20] FANG Yuefa, TSAI Lung-Wen. Enumeration of a Class of Overconstrained Mechanisms Usingthe Theory of Reciprocal Screws[J]. Mechanism and Machine Theory, 2004, 39(11): 1175–1187.
  21. [21] CUI Lei, DAI Jiansheng. Axis Constraint Analysis and its Resultant 6R Double-CenteredOverconstrained Mechanisms[J]. Journal of Mechanisms and Robotics, 2011, 3(3): 1–9.
  22. [22] WEI Guowu, DAI Jiansheng. Origami-Inspired Integrated Planar-Spherical OverconstrainedMechanisms[J]. Journal of Mechanical Design, 2014, 136(5): 1–13.
  23. [23] KONG Xianwen. Type Synthesis of Single-Loop Overconstrained 6R Spatial Mechanisms forCircular Translation[J]. Journal of Mechanisms and Robotics, 2014, 6(4): 1–8.
  24. [24] HUANG Hailin, DENG Zongquan, QI Xiaozhi et al. Virtual Chain Approach for MobilityAnalysis of Multiloop Deployable Mechanisms[J]. Journal of Mechanical Design, 2013, 135(11):1–9.
  25. [25] DING Xilun, YANG Yi, DAI Jian-S. Design and Kinematic Analysis of a Novel PrismDeployable Mechanism[J]. Mechanism and Machine Theory, 2013, 63: 35–49.
  26. [26] HUANG Hailin, DENG Zongquan, LI Bing. Mobile Assemblies of Large DeployableMechanisms[J]. Journal of Space Engineering, 2012, 5(1): 1–14.
  27. [27] FANG Yuefa, TSAI Lung-Wen. Structure Synthesis of a Class of 4-Dof and 5-Dof ParallelManipulators with Identical Limb Structures[J]. The International Journal of Robotics Research,2002, 21(9): 799–810.(DOI: 10.2316/J.2019.206-5495)
  28. [28] HUANG Zheng, FANG Yuefa. Kinematic Characteristics Analysis of 3 Dof in-Parallel ActuatedPyramid Mechanism[J]. Mechanism and Machine Theory, 1996, 31(8): 1009–1018.
  29. [29] HU Bo, ZHUANG Shan, LU Yi et al. Kinematics, Statics and Stiffness Analysis of N(4-Sps+Sp)S-Pm[J]. International Journal of Robotics & Automation, 2012, 27(3): 287–297.
  30. [30] LI Dian, GUO Sheng, QU Haibo et al. Kinematic Analysis and Optimization of a Novel 6-DofMotion Simulator Mechanism[J]. International Journal of Robotics & Automation, 2017, 32(6):625–638.

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