Iterative Feedforward Control for Bearing-Free Multibody Systems

IF 0.9 Q4 ROBOTICS

Journal of Robotics and Mechatronics Pub Date : 2021-01-01 DOI:10.3844/jmrsp.2021.33.46

N. Bailey, C. Lusty, P. Keogh

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引用次数: 0

Abstract

Corresponding Author: Nicola Yvonne Bailey Department of Mechanical Engineering, University of Bath, United Kingdom E-mail: n.y.bailey@bath.ac.uk Abstract: Automated machinery and robotics are commonly conventional multibody systems containing bearing components, which exhibit uncertain, discontinuous and complex tribological characteristics. These generate wear and fundamentally limit the precision of small scale motion due to the tribological effects being difficult to compensate for using model-based active control. However, they can be eliminated through the replacement of traditional bearing joints with flexure couplings, which offers a potential increase in the performance envelope. Initially a plain flexure coupling capable of large deformation is investigated, with a representative mathematical model derived based on large deformation Euler-Bernoulli theory which is validated using a bespoke experimental facility; proof of concept for the design of empirical controllers utilising experimental data is presented. Various designs of novel compound flexure couplings are conceived, comprising of multiple sections of spring steel. The presented compound flexure couplings are then characterised experimentally. A focused study of a two-compound flexure coupling-rigid body system is presented and the feasibility of generating open-loop feedfoward controllers from identified models is demonstrated in terms of accurate large displacement control. Including path correction in the presented control methodology reduces tracking errors by at least 62% and 71% in (x, y) directions, respectively, for the cases considered.

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无轴承多体系统的迭代前馈控制

摘要:自动化机械和机器人通常是包含轴承部件的传统多体系统，其摩擦学特性具有不确定性、不连续性和复杂性。这些产生磨损，并从根本上限制了小尺度运动的精度，因为使用基于模型的主动控制难以补偿摩擦效应。然而，它们可以通过用柔性联轴器替换传统的轴承接头来消除，这提供了性能范围的潜在增加。首先研究了具有大变形能力的平面弯曲耦合，并基于大变形欧拉-伯努利理论推导了具有代表性的数学模型，并使用定制的实验设备进行了验证;提出了利用实验数据设计经验控制器的概念证明。提出了由多段弹簧钢组成的新型复合式挠性联轴器的设计方案。然后对所提出的复合柔性联轴器进行了实验表征。重点研究了两复合柔性耦合刚体系统，并从精确大位移控制的角度证明了从已识别模型生成开环前馈控制器的可行性。在所考虑的情况下，在所提出的控制方法中包括路径校正，分别在(x, y)方向上减少至少62%和71%的跟踪误差。

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来源期刊

Journal of Robotics and Mechatronics ROBOTICS-

CiteScore

2.20

自引率

36.40%

发文量

134

期刊介绍： First published in 1989, the Journal of Robotics and Mechatronics (JRM) has the longest publication history in the world in this field, publishing a total of over 2,000 works exclusively on robotics and mechatronics from the first number. The Journal publishes academic papers, development reports, reviews, letters, notes, and discussions. The JRM is a peer-reviewed journal in fields such as robotics, mechatronics, automation, and system integration. Its editorial board includes wellestablished researchers and engineers in the field from the world over. The scope of the journal includes any and all topics on robotics and mechatronics. As a key technology in robotics and mechatronics, it includes actuator design, motion control, sensor design, sensor fusion, sensor networks, robot vision, audition, mechanism design, robot kinematics and dynamics, mobile robot, path planning, navigation, SLAM, robot hand, manipulator, nano/micro robot, humanoid, service and home robots, universal design, middleware, human-robot interaction, human interface, networked robotics, telerobotics, ubiquitous robot, learning, and intelligence. The scope also includes applications of robotics and automation, and system integrations in the fields of manufacturing, construction, underwater, space, agriculture, sustainability, energy conservation, ecology, rescue, hazardous environments, safety and security, dependability, medical, and welfare.