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Large workspace robot

From Wikipedia, the free encyclopedia

A large workspace robot (LWR) is a robot that is defined by especially large workspaces compared to certain characteristics like weight (or mass), or bulk size of the robot itself.

Definition

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The size of the workspace of a robot is, in general, proportional to the mass of the robot, or to its size. This means that the notion of LWR can be defined only relative to some other feature of the system.

Weight-based

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For example, considering a robot of mass m and a workspace volume W the adimensional quantity β (from the Greek word for "weight", βάρος) can be defined as:

Upon preliminary examination of the panorama of industrial robots, it was shown[1] that a good threshold for this parameter is . Indeed, in the case where , the robot can be considered as a LWR. The vast majority of industrial serial and parallel manipulators fall into the category where .

Bulk-based

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A different approach in defining LWRs is through the bulk size of the robot. The adimensional quantity δ can be defined as:

The bulk-based definition is less general, and depends strongly on how it is implemented. Specifically, the definition of Dmax is non-obvious; for example, if a deployable robot is taken into consideration, Dmax can be thought of either the maximum dimension of the stored configuration of the robot, or as the maximum dimension of the deployed configuration.

Examples

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The most widely known example of Large Workspace Robot is called Cable Driven Parallel Manipulator (CDPR[2][3][4]), or Cable Direct Driven Manipulator (CDDR[5][6]). This kind of robots take advantage of cables, winded on computer-controlled winches, to maneuver the end-effector.

By keeping the cables taut either simply by exploiting the force of gravity, or using complex over-actuated systems, the robot can reach very large workspaces[7] while keeping its mass to modest values. Indeed, while it is true that in order to double the size of the workspace, the cables' length should double as well, the large part of the mass of the robot lies in the winches, pulleys and the end-effector; the influence of the cable length is only mildly influential to these components.

Another example of LWR is an uncrewed vehicle, a rover or the more general mobile robot. The workspace of this kind of robots can be considered unlimited, albeit only bi-dimensional and constrained by the ground shape. This means that, from Eq. 1, ; the same is true for the bulk-based parameter .

References

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  1. ^ S. Seriani, "Large Workspace Robots", Ph.D. dissertation (2016) University of Trieste
  2. ^ Pott, A (2010). "An Algorithm for Real-Time Forward Kinematics of Cable-Driven Parallel Robots". Advances in Robot Kinematics: Motion in Man and Machine. pp. 529–538. doi:10.1007/978-90-481-9262-5_57. ISBN 978-90-481-9261-8.
  3. ^ A. Pott; H. Mutherich; W. Kraus; V. Schmidt; P. Miermeister; T. Dietz; A. Verl (2013). "Cable-driven parallel robots for industrial applications: The IPANEMA system family". {{cite journal}}: Cite journal requires |journal= (help)
  4. ^ J. Pusey; A. Fattah; S. Agrawal; E. Messina (2004). "Design and workspace analysis of a 6-6 cable suspended parallel robot". Mechanisms and Machine Theory. 39 (7): 761–778. doi:10.1016/j.mechmachtheory.2004.02.010.
  5. ^ A. Trevisani; P. Gallina; R. L. Williams (2006). "Cable direct-driven robot (cddr) with passive SCARA support: theory and simulation". Journal of Intelligent and Robotic Systems. 46: 73–94. doi:10.1007/s10846-006-9043-7. S2CID 36229818.
  6. ^ Trevisani, A (2010). "Underconstrained planar cable-direct driven robots: A trajectory planning". Mechatronics. doi:10.1016/j.mechatronics.2009.09.011.
  7. ^ Cravotta, R (2003). "Flying over the action". EDN 48 (15) Pp. 30-34.