基于光栅反馈的混合机器人在线误差补偿策略

Pengkun Cheng, Juliang Xiao, Wei Zhao, Yangyang Zhang, Haitao Liu, Xianlei Shan
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引用次数: 0

摘要

目的 本文旨在通过将移动平台视为串行机器人的第一个关节进行直接位置测量,并将外部光栅传感器与电机编码器集成以进行实时误差补偿,从而提高混合机器人的加工精度。该系统可直接获取混合机器人中移动平台的位置。随后,在粗插值阶段,利用外部光栅传感器和电机编码器的误差数据动态更新下一个插值点的电机指令。最后,应用模糊比例积分导数(PID)控制来保持补偿后机器人的稳定性。 研究结果在 TriMule-600 混合机器人上进行了实验。结果表明,补偿后五个光栅传感器的误差分别减少了 94%、93%、80%、75% 和 88%。以第四个驱动关节为例,验证了模糊自适应 PID 控制比传统 PID 控制效果更好。 实用意义所提出的在线误差补偿策略显著提高了机器人末端的位置精度,从而改善了工件的实际加工质量。社会意义该方法提出了一种实现混合机器人在线误差补偿的技术,促进了制造业的发展。原创性/价值本文提出了一种利用光栅传感器实现混合机器人在线误差补偿的经济实用的方法,有助于推动混合机器人技术的发展。
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An online error compensation strategy for hybrid robot based on grating feedback

Purpose

This paper aims to enhance the machining accuracy of hybrid robots by treating the moving platform as the first joint of a serial robot for direct position measurement and integrating external grating sensors with motor encoders for real-time error compensation.

Design/methodology/approach

Initially, a spherical coordinate system is established using one linear and two circular grating sensors. This system enables direct acquisition of the moving platform’s position in the hybrid robot. Subsequently, during the coarse interpolation stage, the motor command for the next interpolation point is dynamically updated using error data from external grating sensors and motor encoders. Finally, fuzzy proportional integral derivative (PID) control is applied to maintain robot stability post-compensation.

Findings

Experiments were conducted on the TriMule-600 hybrid robot. The results indicate that the following errors of the five grating sensors are reduced by 94%, 93%, 80%, 75% and 88% respectively, after compensation. Using the fourth drive joint as an example, it was verified that fuzzy adaptive PID control performs better than traditional PID control.

Practical implications

The proposed online error compensation strategy significantly enhances the positional accuracy of the robot end, thereby improving the actual processing quality of the workpiece.

Social implications

This method presents a technique for achieving online error compensation in hybrid robots, which promotes the advancement of the manufacturing industry.

Originality/value

This paper proposes a cost-effective and practical method for online error compensation in hybrid robots using grating sensors, which contributes to the advancement of hybrid robot technology.

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