Abstract
This paper presents several algorithms to detect the cable interferences for a general spatial Cable-Driven Parallel Robot (CDPR). Two types of cable interferences are considered. The first type is the collisions between cables and cables. The second type is the interferences between cables and the CDPR mobile platform. In each case, an algorithm is proposed to efficiently verify the cable interferences. The use of the proposed algorithms is then illustrated by a verification procedure of the collision free condition over a given Cartesian workspace and orientation workspace of a CDPR. These tools can be used in the design or planning phase of a general CDPR.
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References
Albus J, Bostelman R, Dagalakis N (1993) The NIST robocrane. J Robot Syst 10(5):709–724
Merlet J-P (2008) Kinematics of the wire-driven parallel robot marionet using linear actuators. Proceedings of IEEE international conference on robotics and automation. pp 3857–3862
Merlet J-P, Daney D (2010) A portable, modular parallel wire crane for rescue operations. In: Proceedings of IEEE international conference on robotics and automation (ICRA) , May 2010. pp 2834–2839
Lamaury J, Gouttefarde M (2013) A tension distribution method with improved computational efficiency. Cable-driven parallel robots, mechanisms and machine science, vol 12. Springer, Heidelberg, pp 71–85
Merlet J-P (2004) Analysis of the influence of wires interference on the workspace of wire robots. In: Advances in Robot Kinematics. Kluwer Academic Publishers, Dordrecht, pp 211–218
Maeda K, Tadokoro S, Takamori T, Hiller M, Verhoeven R (1999) On design of a redundant wire-driven parallel robot WARP manipulator. In: Proceedings of IEEE international conference on robotics and automation. pp 895–900
Otis M, Perreault S, Nguyen-Dang T-L, Lambert P, Gouttefarde M, Laurendeau D, Gosselin C (2009) Determination and management of cable interferences between two 6-DOF foot platforms in a cable-driven locomotion interface. IEEE Trans Syst Man Cybern Part A Syst Hum 39(3):528–544
Perreault S, Gosselin C (2008) Cable-driven parallel mechanisms: application to a locomotion interface. J Mech Des 130:10
Perreault S, Cardou P, Gosselin C, Otis MJ-D (2010) Geometric determination of the interference-free constant-orientation workspace of parallel cable-driven mechanisms. J Mech Robot 2:011012
Wischnitzer Y, Shvalb N, Shoham M (2008) Wire-driven parallel robot: permitting collisions between wires. Int J Robot Res 27(9):1007–1026
Ericson C (2005) Real-time collision detection. Morgan Kaufmann, San Fransisco
Meshlab. http://meshlab.sourceforge.net/
Acknowledgments
The research leading to these results has received funding from the European Community’s Seventh Framework Programme under grant agreement No. NMP2-SL-2011-285404 (CABLEBOT).
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Nguyen, D.Q., Gouttefarde, M. (2015). On the Improvement of Cable Collision Detection Algorithms. In: Pott, A., Bruckmann, T. (eds) Cable-Driven Parallel Robots. Mechanisms and Machine Science, vol 32. Springer, Cham. https://doi.org/10.1007/978-3-319-09489-2_3
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DOI: https://doi.org/10.1007/978-3-319-09489-2_3
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