Research on anti-swing control strategies for three-dimensional overhead cranes with non-stationary enhanced swing angle suppression

Dong Li, Tianhu Xie, Lu Zhang
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Abstract

In this paper, a non-stationary enhanced swing angle suppression control strategy is proposed to address the issue of excessive swinging angles during the transportation process of a three-dimensional overhead crane. Firstly, in response to the substantial non-stationary initial swing angle resulting from the abrupt increase in driving force during the startup of the overhead crane, we have devised a time-varying damping resistance model. This model is specifically designed to curtail the rapid force surge, subsequently diminishing the swing angle of the payload. Secondly, during the transport phase of the overhead crane, we have established an augmented coupling signal between the displacement tracking error and the payload swing angle tracking error. Drawing upon the principles of energy dissipation, we have devised a nonlinear sway controller. Next, the closed-loop stability of the control system is validated through the use of Lyapunov’s method and the LaSalle invariance principle. Finally, the proposed control strategy’s effectiveness has been substantiated through simulation analysis and physical experiments. This approach not only proves capable of effectively suppressing excessive payload swing angles during the transportation process of the overhead crane but also facilitates the rapid and precise positioning of the payload. This significantly enhances the efficiency of the overhead crane’s transport operations.
非稳态增强摆角抑制的三维桥式起重机防摆控制策略研究
本文针对三维桥式起重机在运输过程中摆角过大的问题,提出了一种非稳态增强摆角抑制控制策略。首先,针对桥式起重机启动过程中驱动力突然增加导致初始摆角大幅非稳态化的问题,我们设计了一个时变阻尼抗力模型。该模型专门用于抑制快速的力激增,从而减小有效载荷的回转角度。其次,在桥式起重机的运输阶段,我们在位移跟踪误差和有效载荷摆角跟踪误差之间建立了增强耦合信号。借鉴能量耗散原理,我们设计了一种非线性摇摆控制器。接着,通过使用 Lyapunov 方法和拉萨尔不变性原理,验证了控制系统的闭环稳定性。最后,通过仿真分析和物理实验证实了所提出的控制策略的有效性。事实证明,这种方法不仅能有效抑制桥式起重机在运输过程中有效载荷的过大摆角,还能促进有效载荷的快速精确定位。这大大提高了桥式起重机的运输效率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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