Modal Control for Active Vibration Damping of Cable-Driven Parallel Robots

Abstract Cable-driven parallel robots are well suited for applications that require a very large workspace. Thanks to their lightweight moving parts, they can achieve high dynamics while remaining pretty safe for nearby human workers. Furthermore, their size depends only on the length of the cables; thus, their scale is almost totally decoupled from their cost. However, due to the cables, the stiffness is very low with respect to rigid link robots, inducing slowly damped oscillations of the end effector. Previous works have shown that those vibrations can be effectively damped by the winch actuators thanks to active vibration damping techniques. In this paper, a gain scheduling approach is proposed based on a linearized model of the robot dynamics. This model is projected in the modal space yielding six decoupled transfer functions for six degrees-of-freedom (DoFs) of a cable-driven parallel robot using thin cables. The stability of the proposed control law is analyzed for a static and a moving end effector. The proposed control algorithm is validated experimentally on an eight-cable suspended robot prototype.

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DeltaBot: A New Cable-Based Ultra High Speed Robot

Dynamic Systems and Control, Volumes 1 and 2 ◽

10.1115/imece2003-41470 ◽

2003 ◽

Cited By ~ 3

Author(s):

Saeed Behzadipour ◽

Robert Dekker ◽

Amir Khajepour ◽

Edmon Chan

Keyword(s):

High Speed ◽

Degrees Of Freedom ◽

Manufacturing Industry ◽

Design Procedure ◽

Parallel Manipulators ◽

Parallel Robot ◽

Parallel Robots ◽

Manufacturing Cost ◽

End Effector ◽

Serial Manipulators

The growing needs for high speed positioning devices in the automated manufacturing industry have been challenged by robotic science for more than two decades. Parallel manipulators have been widely used for this purpose due to their advantage of lower moving inertia over the conventional serial manipulators. Cable actuated parallel robots were introduced in 1980’s to reduce the moving inertia even further. In this work, a new cable-based parallel robot is introduced. For this robot, the cables are used not only to actuate the end-effector but also to apply the necessary kinematic constraints to provide three pure translational degrees of freedom. In order to maintain tension in the cables, a passive air cylinder is used to push the end-effector against the stationary platform. In addition to low moving inertia, the new design benefits from simplicity and low manufacturing cost by eliminating joints from the robot’s mechanism. The design procedure and the results of experiments will be discussed in the following.

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The QuadroG Robot, a Parallel Robot With a Configurable Platform for Haptic Applications

Volume 5C: 39th Mechanisms and Robotics Conference ◽

10.1115/detc2015-46841 ◽

2015 ◽

Cited By ~ 1

Author(s):

Salua Hamaza ◽

Patrice Lambert ◽

Marco Carricato ◽

Just Herder

Keyword(s):

Kinematic Analysis ◽

Degrees Of Freedom ◽

Closed Loop ◽

Parallel Robot ◽

Parallel Robots ◽

End Effector ◽

Contact Points ◽

Loop Chain ◽

End Effectors ◽

4 Degrees Of Freedom

This paper explores the fundamentals of parallel robots with configurable platforms (PRCP), as well as the design and the kinematic analysis of those. The concept behind PRCP is that the rigid (non-configurable) end-effector is replaced by a closed-loop chain, the configurable platform. The use of a closed-loop chain allows the robot to interact with the environment from multiple contact points on the platform, which reflects the presence of multiple end-effectors. This results in a robot that successfully combines motion and grasping capabilities into a structure that provides an inherent high stiffness. This paper aims to introduce the QuadroG robot, a 4 degrees of freedom PRCP which finely merges planar motion together with grasping capabilities.

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Modeling and Control of a Cable-Suspended Sling-Like Parallel Robot for Throwing Operations

Applied Sciences ◽

10.3390/app10249067 ◽

2020 ◽

Vol 10 (24) ◽

pp. 9067

Author(s):

Deng Lin ◽

Giovanni Mottola ◽

Marco Carricato ◽

Xiaoling Jiang

Keyword(s):

Mathematical Models ◽

Degrees Of Freedom ◽

Parallel Robot ◽

Parallel Robots ◽

Target Point ◽

Inertial Effects ◽

End Effector ◽

Modeling And Control ◽

And Control ◽

Three Degrees Of Freedom

Cable-driven parallel robots can provide interesting advantages over conventional robots with rigid links; in particular, robots with a cable-suspended architecture can have very large workspaces. Recent research has shown that dynamic trajectories allow the robot to further increase its workspace by taking advantage of inertial effects. In our work, we consider a three-degrees-of-freedom parallel robot suspended by three cables, with a point-mass end-effector. This model was considered in previous works to analyze the conditions for dynamical feasibility of a trajectory. Here, we enhance the robot’s capabilities by using it as a sling, that is, by throwing a mass at a suitable time. The mass is carried at the end-effector by a gripper, which releases the mass so that it can reach a given target point. Mathematical models are presented that provide guidelines for planning the trajectory. Moreover, results are shown from simulations that include the effect of cable elasticity. Finally, suggestions are offered regarding how such a trajectory can be optimized.

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Rotational Workspace Expansion of a Planar CDPR with a Circular End-Effector Mechanism Allowing Passive Reconfiguration

Robotics ◽

10.3390/robotics8030057 ◽

2019 ◽

Vol 8 (3) ◽

pp. 57 ◽

Cited By ~ 1

Author(s):

Marco Carpio Alemán ◽

Roque Saltaren ◽

Alejandro Rodriguez ◽

Gerardo Portilla ◽

Juan Placencia

Keyword(s):

Degrees Of Freedom ◽

Parallel Robot ◽

Parallel Robots ◽

End Effector ◽

Effector Mechanism ◽

Circular Structure ◽

Adams Software ◽

Anchor Points ◽

Orientation Workspace ◽

Three Degrees Of Freedom

Cable-Driven Parallel Robots (CDPR) operate over a large positional workspace and a relatively large orientation workspace. In the present work, the expansion of the orientation Wrench Feasible Workspace (WFW) in a planar four-cable passive reconfigurable parallel robot with three degrees of freedom was determined. To this end, we proposed a circular-geometry effector mechanism, whose structure allows automatic mobility of the two anchor points of the cables supporting the End Effector (EE). The WFW of the proposed circular structure robot was compared with that of a traditional robot with a rectangular geometry and fixed anchor points. Considering the feasible geometric and tension forces on the cables, the generated workspace volume of the robot was demonstrated in an analysis-by-intervals. The results were validated by simulating the orientation movements of the robot in ADAMS software and a real experimental test was developed for a hypothetical case. The proposed design significantly expanded the orientation workspace of the robot. The remaining limitation is the segment of the travel space in which the mobile connection points can slide. Overcoming this limitation would enable the maximum rotation of the EE.

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Design and implementation of a multi-degrees-of-freedom cable-driven parallel robot with gripper

International Journal of Advanced Robotic Systems ◽

10.1177/1729881418803845 ◽

2018 ◽

Vol 15 (5) ◽

pp. 172988141880384 ◽

Cited By ~ 3

Author(s):

Jonqlan Lin ◽

Chi Ying Wu ◽

Julian Chang

Keyword(s):

Degrees Of Freedom ◽

Load Capacity ◽

Kinematic Model ◽

Weight Ratio ◽

Parallel Robot ◽

Parallel Robots ◽

Control Mode ◽

Level Control ◽

End Effector ◽

Upper Level

Cable-driven parallel robots comprise driven actuators that allow controlled cables to act in parallel on an end-effector. Such a robotic system has a potentially large reachable workspace, large load capacity, high payload-to-weight ratio, high reconfigurability, and low inertia, relative to rigid link serial and parallel robots. In this work, a multi-degrees-of-freedom cable-suspended robot that can carry out pick-and-place tasks in large workspaces with heavy loads is designed. The proposed cable-driven parallel robot is composed of a rigid frame and an end-effector that is suspended from eight cables—four upper cables and four lower cables. The lengths of the cables are computed from the given positions of the suspended end-effector using a kinematic model. However, most multi-cable-driven robots suffer from interference among the cables, requiring a complex control methodology to find a target goal. Owing to this issue with cable-driven parallel robots, the whole control structure decomposes positioning control missions and allocates them into upper level and lower level. The upper level control is responsible for tracking the suspended end-effector to the target region. The lower level control makes fine positional modifications. Experimental results reveal that the hybrid control mode notably improves positioning performance. The wide variety of issues that are considered in this work apply to aerostats, towing cranes, locomotion interfaces, and large-scale manufacturing that require cable-driven parallel robots.

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Oscillation Reduction and Frequency Analysis of Under-Constrained Cable-Driven Parallel Robot with Three Cables

Robotica ◽

10.1017/s0263574719000687 ◽

2019 ◽

Vol 38 (3) ◽

pp. 375-395 ◽

Cited By ~ 1

Author(s):

Sung Wook Hwang ◽

Jeong-Hyeon Bak ◽

Jonghyun Yoon ◽

Jong Hyeon Park

Keyword(s):

Frequency Analysis ◽

Degrees Of Freedom ◽

Natural Frequencies ◽

Vibration Suppression ◽

Parallel Manipulators ◽

Parallel Robot ◽

Parallel Robots ◽

Input Shaping ◽

End Effector ◽

Multi Mode

SummaryCable-driven parallel robots (CDPRs) possess a lot of advantages over conventional parallel manipulators and link-based robot manipulators in terms of acceleration due to their low inertia. This paper deals with under-constrained CDPRs, which manipulate the end-effector to carrying the payload by using a number of cables less than six, often used preferably owing to their simple structures. Since a smaller number of cables than six are used, the end-effector of CDPR has uncontrollable degrees of freedom and that causes swaying motion and oscillations. In this paper, a scheme to curb on the unwanted oscillation of the end-effector of the CDPR with three cables is proposed based on multimode input shaping. The precise dynamic model of the under-constrained CDPR is obtained to find natural frequencies, which depends on the position of the end-effector. The advantage of the proposed method is that it is practicable to generate the trajectories for vibration suppression based on multi-mode input-shaping scheme in spite of the complexity in the dynamics and the difficulty in computing the natural frequencies of the CDPR, which are required in any input-shaping scheme. To prove the effectiveness of the proposed method, computer simulations and experiments were carried out by using 3-D motion for CDPR with three cables.

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Dynamic and Wrench-Feasible Workspace Analysis of a Cable-Driven Parallel Robot Considering a Nonlinear Cable Tension Model

Applied Sciences ◽

10.3390/app12010244 ◽

2021 ◽

Vol 12 (1) ◽

pp. 244

Author(s):

Vu N. D. Kieu ◽

Shyh-Chour Huang

Keyword(s):

Parallel Robot ◽

Mechanical Analysis ◽

Industrial Applications ◽

Parallel Robots ◽

Kinematic Equation ◽

Cable Tension ◽

End Effector ◽

Tension Distribution ◽

Workspace Analysis ◽

High Dynamics

Cable-driven parallel robots (CDPRs) have several advantages and have been widely used in many industrial fields, especially industrial applications that require high dynamics, high payload capacity, and a large workspace. In this study, a design model for a CDPR system was proposed, and kinematic and dynamic modeling of the system was performed. Experiments were carried out to identify the dynamic modulus of elastic cables based on the dynamic mechanical analysis (DMA) method. A modified kinematic equation considering cable nonlinear tension was developed to determine the optimal cable tension at each position of the end-effector, and the wrench-feasible workspace was analyzed at various motion accelerations. The simulation results show that the proposed CDPR system obtains a large workspace, and the overall workspace is satisfactory and unrestricted for moving ranges in directions limited by the X-axis and the Y-axis from −0.3 to 0.3 m and by the Z-axis from 0.1 to 0.7 m. The overall workspace was found to depend on the condition of acceleration as well as the moving ranges limited by the end-effector. With an increase in external acceleration, the cable tension distribution increased and reached a maximum in the case of 100 m/s2.

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Cable-Driven Parallel Robot with Reconfigurable End Effector Controlled with a Compliant Actuator

Sensors ◽

10.3390/s18092765 ◽

2018 ◽

Vol 18 (9) ◽

pp. 2765 ◽

Cited By ~ 8

Author(s):

Alejandro Rodriguez-Barroso ◽

Roque Saltaren ◽

Gerardo A. Portilla ◽

Juan S. Cely ◽

Marco Carpio

Keyword(s):

Degrees Of Freedom ◽

Parallel Robot ◽

Parallel Robots ◽

Degree Of Freedom ◽

Elastic Model ◽

Dynamic Simulations ◽

End Effector ◽

High Tension ◽

Compliant Actuator ◽

The Relationship

Redundancy in cable-driven parallel robots provides additional degrees of freedom that can be used to achieve different objectives. In this robot, this degree of freedom is used to act on a reconfigurable end effector with one degree of freedom. A compliant actuator actuated by one motor exerts force on both bodies of the platform. Due to the high tension that appears in this cable in comparison with the rest of the cables, an elastic model was developed for solving the kinestostatic and wrench analysis. A linear sensor was used in one branch of this cable mechanism to provide the needed intermediate values. The position of one link of the platform was fixed in order to focus this analysis on the relationship between the cables and the platform’s internal movement. Position values of the reconfigurable end effector were calculated and measured as well as the tension at different regions of the compliant actuator. The theoretical values were compared with dynamic simulations and real prototype results.

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