A Supervisory Control Methodology for a New Pneumatic Cart-Seesaw System

2007 IEEE 22nd International Symposium on Intelligent Control Pub Date : 2007-10-01 DOI:10.1109/ISIC.2007.4450932

Jonqlan Lin, J. Zhan, Julian Chang

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引用次数: 1

Abstract

This paper describes mechanical configuration and control environment for a new cart-seesaw system. The system consists of a cart, which slides on the pneumatic rodless cylinder. The rodless cylinder is a double-acting one with carrier bracket on which a cart has been pinion mechanism to tracks. The task of the cart-seesaw system is to bring the cart to from any initial position to a desired position on the seesaw by applying an appropriate force to the cart and thereby changing the angle of the seesaw. The position of a cart represents the first degree of freedom, which is activated by a pneumatic proportional valve and the angle of the seesaw represents the second degree of freedom that is not actuated. Consequently, the proposed new pneumatic cart-seesaw system is simple to construct and direct to operate in different scenarios of performance. A state feedback controller is applied for stabilization of the equilibrium point of the system. Moreover, this work adds a supervisory controller that takes control action in extreme situations. Thus, the test results show excellent characteristics in control performance. Finally, the proposed product in this research can be extensively application in SAMS and pneumatic control for control laboratory.

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一种新型气动跷跷板系统的监督控制方法

本文介绍了一种新型小车跷跷板系统的机械结构和控制环境。该系统由一个小车组成，小车在气动无杆气缸上滑动。所述无杆气缸为双作用气缸，带有托架，在托架上装有小车的小齿轮机构。小车-跷跷板系统的任务是通过对小车施加适当的力，从而改变跷跷板的角度，使小车从跷跷板上的任何初始位置移动到期望的位置。小车的位置代表由气动比例阀驱动的第一自由度，跷跷板的角度代表未被驱动的第二自由度。因此，所提出的新型气动小车跷跷板系统结构简单，可直接用于不同的性能场景。采用状态反馈控制器实现系统平衡点的稳定。此外，这项工作增加了一个监督控制器，在极端情况下采取控制行动。因此，测试结果显示出良好的控制性能。最后，本研究提出的产品可以广泛应用于控制实验室的SAMS和气动控制。

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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来源期刊

2007 IEEE 22nd International Symposium on Intelligent Control

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