Posture Optimization in Robot Machining with Kinematic Redundancy for High-Precision Positioning

IF 0.9 Q4 AUTOMATION & CONTROL SYSTEMS
Shingo Tajima, Satoshi Iwamoto, Hayato Yoshioka
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引用次数: 0

Abstract

Vertically articulated industrial robots are suitable for machining purposes owing to their advantages over multi-axis machine tools, such as larger workspace, easier installation, and lower cost. However, the rigidity and positioning accuracy of industrial robots are inferior to those of machine tools, which renders it difficult to maintain the robot posture required for machining operations. This study focuses on improving the accuracy of robot machining based on posture optimization by exploiting the kinematic redundancy of a six-axis vertically articulated robot. To decrease positioning errors caused by static and dynamic external forces during machining, this study proposes a path generation method for a redundant joint that simultaneously considers the static and dynamic rigidity of the machining robot. The relationships between the static and dynamic mechanical characteristics of the machining robot and the redundant angle are illustrated using two maps: a static stiffness map and a natural frequency map. Using these two maps in the proposed path generation method, the redundant angle that can be selected for the robot posture with arbitrary mechanical characteristics is selected. Experimental results confirm that the proposed path generation method can control the priority of reducing static positioning error and vibration amplitude by changing the weight coefficients. In addition, the proposed method can improve positioning accuracy compared with conventional trajectory generation methods for redundant robots.
面向高精度定位的运动冗余机器人加工姿态优化
垂直关节式工业机器人相对于多轴机床具有工作空间大、安装方便、成本低等优点,适用于机械加工。然而,工业机器人的刚性和定位精度都不如机床,难以保持加工作业所需的机器人姿态。利用六轴垂直关节机器人的运动冗余度,研究了基于姿态优化的机器人加工精度。为了减小加工过程中静、动外力对定位的影响,提出了一种同时考虑加工机器人静、动刚度的冗余关节路径生成方法。利用静态刚度图和固有频率图说明了加工机器人的静态和动态力学特性与冗余角之间的关系。在本文提出的路径生成方法中,利用这两种映射选择具有任意机械特性的机器人姿态可以选择的冗余角。实验结果表明,所提出的路径生成方法可以通过改变权系数来控制减小静态定位误差和振动幅值的优先级。此外,与传统的冗余度机器人轨迹生成方法相比,该方法可以提高定位精度。
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来源期刊
International Journal of Automation Technology
International Journal of Automation Technology AUTOMATION & CONTROL SYSTEMS-
CiteScore
2.10
自引率
36.40%
发文量
96
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