Traditionally, Cable-Driven Parallel Robots (CDPRs) require four cables and four actuators to encompass a rectangular workspace. However, our featured video unveils a breakthrough 2-DoF planar CDPR prototype, showcasing its remarkable ability to achieve coverage of a rectangular workspace using only three actuators.
Abstract:
In the realm of cable-driven parallel robots (CDPRs), the conventional notion entails that each cable is directly actuated by a corresponding actuator, implying a direct relationship between the number of cables and actuators. However, this paper introduces a paradigm shift by contending that the number of cables should be contingent upon the desired workspace, while the number of actuators should align with the robot's degrees of freedom (DoF). This novel perspective leads to an unconventional design methodology for CDPRs. Instead of commencing with the number of actuators and cables in mind, we propose an approach that begins with defining the required workspace shape and subsequently determines the requisite number of cables. Subsequently, an actuation scheme is established wherein multiple cables are driven by a single actuator. This process entails the formulation of a transmission matrix that captures the interplay between actuators and cables, followed by the mechanical implementation of the corresponding cable-pulley routing. To illustrate this approach, we present an example involving a two-degree-of-freedom CDPR aimed at covering a rectangular workspace. Notably, the resulting wrench-closure-workspaces and wrench-feasible-workspaces of the proposed designs exhibit favorable comparisons to existing CDPRs with a greater number of actuators.
Keywords: CDPR, Transmission System, Transmission matrix optimization, Wrench-Closure-Workspace, Wrench-Feasible-Workspace
