Robotic control system for hydraulic telescopic handler

19th International Workshop on Robotics in Alpe-Adria-Danube Region (RAAD 2010) Pub Date : 2010-06-24 DOI:10.1109/RAAD.2010.5524596

J. Cinkelj, J. Cinkelj, R. Kamnik, Peter Cepon, Peter Čepon, M. Mihelj, M. Mihelj, M. Munih

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引用次数: 6

Abstract

Automation is supposed to improve working conditions and safety in construction industry, as it already did in manufacturing industries. This paper presents the development of a robotic control system for a commercially available hydraulic telescopic handler. The target application for the telescopic handler is semi-automated assembly of facade panels. The base handler was upgraded with two additional hydraulic axes, position sensors and closed-loop control system, while the original handler safety assurance mechanisms were preserved. The control approach is based on a PI controller with velocity feedforward and valve overlap compensation. The direct and inverse kinematic models of handler mechanism were developed to enable control of end-effector motion along a straight line in Cartesian coordinate system. The motion performances were evaluated following the ISO 9283 standard with payload of 2000 kg. Results show the repeatability of positioning bellow 7.0 mm and the straight line tracking error smaller than 63 mm.

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液压伸缩处理机器人控制系统

自动化应该改善建筑行业的工作条件和安全，正如它已经在制造业中所做的那样。本文介绍了一种商用液压伸缩搬运机器人控制系统的开发。伸缩手柄的目标应用是幕墙面板的半自动组装。在原有的安全保证机制保持不变的情况下，基础处理程序进行了升级，增加了两个液压轴、位置传感器和闭环控制系统。控制方法是基于速度前馈和阀重叠补偿的PI控制器。建立了处理机构的正运动学和逆运动学模型，实现了末端执行器在直角坐标系下的直线运动控制。运动性能按照ISO 9283标准进行评估，有效载荷为2000公斤。结果表明，定位精度在7.0 mm以下，直线跟踪误差小于63 mm。

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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19th International Workshop on Robotics in Alpe-Adria-Danube Region (RAAD 2010)

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