In this paper we propose a sliding-mode antiswing control for overhead cranes. The objective of this study is to realize an antiswing trajectory control with high-speed load hoisting. A sliding-mode antiswing trajectory control scheme is designed based on the Lyapunov stability theorem, where a sliding surface, coupling the trolley motion with load swing, is adopted for a direct damping control of load swing. The proposed control guarantees asymptotic stability while keeping all internal signals bounded. In association with a new antiswing motion planning scheme, the proposed control realizes a typical antiswing trajectory control in practice, allowing high-speed load-hoisting motion and sufficient damping of load swing. The proposed control is simple for a real-time implementation with high-frequency sampling. The effectiveness of the proposed control has been confirmed by experiments.

Issue Section:
Technical Papers
Keywords:
variable structure systems, position control, cranes, hoists, loading, Lyapunov methods, trolleys, damping, vibration control, asymptotic stability, path planning
Topics:
Damping, Gantry cranes, Stability, Stress, Trajectories (Physics), Cranes, Path planning, Signals
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Copyright © 2006
 by American Society of Mechanical Engineers
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