Bilateral control with compliant force lock for safety enhancement

2017 IEEE 26th International Symposium on Industrial Electronics (ISIE) Pub Date : 2017-06-19 DOI:10.1109/ISIE.2017.8001546

R. Ruwanthika, A. Harsha, S. Abeykoon, S. Katsura

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引用次数: 2

Abstract

This paper proposes a force feedback compliance force lock for biltateral control based on sensor-less sensor Reaction Force Observer (RFOB). The force limit is defined by the operator in advance based on the experience. The force lock protects the object which is in contact with the slave actuator from excessive force imposed by the master operator in bilateral control. A small vibration has been introduced to notify the attainment of the force limit to the master operator. Furthermore, if master operator wishes to increase his applied force, he will experience spring effect. The equilibrium point of virtual spring controller which is continuously copied from the slave force locked position aligns master and slave positions at force lock mode. The loss of reaction force occurs at the transition from bilateral control to force lock and vice versa has been removed to regain system stability and to facilitate comfortable operation for the operator. Releasing logic of force lock can be determined by the operator. The proposed system is validated with experiments and results prove the concept of RFOB based force feedback compliance force lock for bilateral control.

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双向控制与顺应力锁，以提高安全性

提出了一种基于无传感器反力观测器(RFOB)的双侧控制力反馈顺应力锁。力限是由操作人员根据经验事先确定的。力锁保护与从执行机构接触的对象，使其免受主操作人员在双边控制中施加的过大力的影响。引入了一个小振动，以通知主操作员达到力限制。此外，如果主操作员希望增加他的施加力，他将经历弹簧效应。从力锁定位置连续复制的虚拟弹簧控制器的平衡点在力锁定模式下对主从位置进行对齐。反作用力的损失发生在从双侧控制到力锁定的过渡过程中，反之亦然，为了恢复系统的稳定性，并为操作人员提供舒适的操作，已经消除了反作用力的损失。力锁的释放逻辑可由操作者决定。实验验证了该系统的有效性，验证了基于RFOB的力反馈顺应力锁的概念。

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

2017 IEEE 26th International Symposium on Industrial Electronics (ISIE)

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