Instant Center Identification of Single-Loop Multi-DOF Planar Linkage Using Virtual Link

Instant center is an important kinematic characteristic which can be used for velocity and singularity analysis, configuration synthesis and dynamics modeling of multi-degree of freedom (multi-DOF) planar linkage. The Aronhold–Kennedy theorem is famous for locating instant centers of four-bar planar linkage, but for single-loop multi-DOF linkages, it fails. Increasing with the number of the links of single-loop multi-DOF planar linkages, the lack of link relationship makes the identification of instant center become a recognized difficulty. This paper proposes a virtual link method to identify instant centers of single-loop multi-DOF planar linkage. First, three types of instant centers are redefined and the instant center identification process graph is introduced. Then, based on coupled loop chain characteristic and definition of instant center, two criteria are presented to convert single-loop multi-DOF planar linkage into a two-loop virtual linkage by adding the virtual links. Subsequently, the unchanged instant centers are identified in the virtual linkage and used to acquire all the instant centers of original single-loop multi-DOF planar linkage. As a result, the instant centers of single-loop five-bar, six-bar planar linkage with several prismatic joints are systematically researched for the first time. Finally, the validity of the proposed method is demonstrated using loop equations. It is a graphical and straightforward method and the application is wide up to single-loop multi-DOF N-bar (N ≥ 5) planar linkage.

[1]  K. Ting,et al.  Invariant Link Rotatability of N-Bar Kinematic Chains , 1994 .

[2]  Rudi Penne,et al.  A general graphical procedure for finding motion centers of planar mechanisms , 2007, Adv. Appl. Math..

[3]  Ahmad Kalhor,et al.  Dynamic modeling and base inertial parameters determination of a 2-DOF spherical parallel mechanism , 2017 .

[4]  Raffaele Di Gregorio An Algorithm for Analytically Calculating the Positions of the Secondary Instant Centers of Indeterminate Linkages , 2008 .

[5]  Federico Thomas,et al.  The Forward Kinematics of 3-R$\underline{P}$R Planar Robots: A Review and a Distance-Based Formulation , 2011, IEEE Transactions on Robotics.

[6]  I. Her,et al.  A Virtual Cam Method for Locating Instant Centers of Kinematically Indeterminate Linkages , 2008 .

[7]  Jesus Maria Blanco,et al.  A general method for the optimal synthesis of mechanisms using prescribed instant center positions , 2016 .

[8]  Carlo Famoso,et al.  Control of imperfect dynamical systems , 2019, Nonlinear Dynamics.

[10]  Gordon R. Pennock,et al.  Graphical Methods to Locate the Secondary Instant Centers of Single-Degree-of-Freedom Indeterminate Linkages , 2005 .

[11]  Gordon R. Pennock,et al.  A Graphical Method to Find the Secondary Instantaneous Centers of Zero Velocity for the Double Butterfly Linkage , 2003 .

[12]  Gordon R. Pennock,et al.  A study of the instantaneous centers of velocity for the 3-dof planar six-bar linkage , 2011 .

[13]  Dan Zhang,et al.  A Review of Dynamic Balancing for Robotic Mechanisms , 2020, Robotica.

[14]  Xiulong Chen,et al.  Effects of Spherical Clearance Joint on Dynamics of Redundant Driving Spatial Parallel Mechanism , 2020 .

[15]  Nadim Diab A new graphical technique for acceleration analysis of four bar mechanisms using the instantaneous center of zero acceleration , 2021, SN Applied Sciences.

[16]  Ea Evert Dijksman Geometric determination of coordinated centers of curvature in network mechanisms through linkage reduction , 1984 .

[17]  Raffaele Di Gregorio A Novel Dynamic Model for Single Degree-of-Freedom Planar Mechanisms Based on Instant Centers , 2016 .

[18]  G. R. Pennock,et al.  A study of the instantaneous centers of velocity for two-degree-of-freedom planar linkages , 2010 .

[19]  Roger Boudreau,et al.  Wrench Capabilities of a Kinematically Redundant Planar Parallel Manipulator , 2021, Robotica.

[20]  J. Cervantes-Sánchez,et al.  A general method for the determination of the instantaneous screw axes of one-degree-of-freedom spatial mechanisms , 2020, Mechanical Sciences.

[21]  A screw theory approach to compute instantaneous rotation axes of indeterminate spherical linkages , 2020 .

[22]  S. Zarkandi GEOMETRICAL METHODS TO LOCATE SECONDARY INSTANTANEOUS POLES OF SINGLE-DOF INDETERMINATE SPHERICAL MECHANISMS , 2011 .