Cable robots
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Cable driven robots (called as cable-suspended robots and wire-driven robots as well) are a type of parallel manipulators in which flexible cables are used as actuators. One end of each cable is reeled around a rotor twisted by a motor, and the other end is connected to the end-effector. One famous example of cable robots is SKYCAM which is used to move a suspended camera in stadiums. Cables are much lighter than rigid linkages of a serial or parallel robot, and very long cables can be used without making the mechanism massive. As a result, the end-effector of a cable robot can achieve high accelerations and velocities and work in a very large workspace (e.g. a stadium). Numerous engineering articles have studied the kinematics and dynamics of cable robots (e.g. see [1] and [2]). Dynamic analysis of cable robots is different compared to other parallel robots because cables can only pull an object but they cannot push. Therefore, the manipulator is able to perform a task only if the tension in all cables are non-negative. Accordingly, the workspace of cable robots is defined as a region in space where the end-effector is able to exert the required wrench (force and moment vectors) to the surroundings while or cables are in tension (non-negative). Many research works have focused on workspace analysis and optimization of cable robots (e.g. see [3]). Workspace and controllability of cable robots can be enhanced by adding cables to structure of the robot. Consequently, redundancy plays a key role in design of cable robots. However, workspace analysis and obtaining positive tension in cables of a redundant cable robot can be complicated. In general, for a redundant robot, infinite solution may exist, but for a redundant cable robot a solution is acceptable only if all the elements of tension vector are non-negative. Finding such solution can be challenging, specially if the end-effector is working along a trajectory and a continuous and smooth distribution of tensions is desired in cables. In literature several methods have been presented to solve such problems( e.g. in [4] a computational method is introduced based on Particle Swarm Optimization method to find continuous smooth solutions along a trajectory for a general redundant cable robot). In addition to parallel cable robots, cables have been used as actuators in serial robots as well. By employing cables as actuators a mechanism can be designed much smaller and lighter (e.g. a human-like finger mechanism actuated by cables is presented in [5]).
References
- ^ O. Saber, S. Abyaneh, H. Zohoor (2010), “A Cable-Suspended Robot with a Novel Cable Based End Effector”, In Proceedings of the ASME 2010, 10th Biennial Conference on Engineering Systems Design and Analysis, ESDA2010, Istanbul, Turkey, vol. 3, pp. 799-808.
- ^ O. Saber (2014), “A Spatial Translational Cable Robot”. Journal of Mechanisms and Robotics (ASME), DOI: 10.1115/1.4028287.
- ^ O. Saber, H. Zohoor (2013), “Workspace Analysis of a Cable-Driven Robot with Active/Passive Cables”, In Proceedings of the 37th Mechanisms and Robotics Conference, ASME International Design Engineering Technical Conferences, (IDETC/CIE), August 4-7, Portland, OR, DETC2013-12646.
- ^ O. Saber, H. Zohoor (2013), “Workspace Analysis of a Cable-Driven Robot with Active/Passive Cables”, In Proceedings of the 37th Mechanisms and Robotics Conference, ASME International Design Engineering Technical Conferences, (IDETC/CIE), August 4-7, Portland, OR, DETC2013-12646.
- ^ S. Abyaneh, O. Saber, H. Zohoor (2013), “A Cable Driven Grasping Mechanism Using Lock/Unlock Constraints”, In Proceedings of the ASME International Design Engineering Technical Conferences and Computers and Information in Engineering Conference (IDETC/CIE), August 4-7, Portland, OR, DETC2013-13109.