Motion optimisation for improved cycle time and reduced vibration in robotic assembly of electronic components

Q3 Engineering
M. Cooper, C. Griffiths, K. Andrzejewski, C. Giannetti
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引用次数: 6

Abstract

Traditionally, six axis robots have not been used in electronic surface mount assembly. However, the need for more flexible production systems that can be used for low to medium production builds, means that these robots can be used due to their high degrees of flexibility. This research investigated the application of an articulated robot to assemble a multi component PCB for an electronic product. To increase the potential of using this method of automation, a genetic algorithm was used to improve cycle time and condition monitoring was performed to assess the vibrations within the robot structure, during operation. By also studying the motion types the robot movements can be optimized in order to minimize the cycle time and maximize the production throughput with reduced vibrations to improve the accuracy of the assembly process. The study utilised a robotics assembly cell and a robot programmed with different velocities. Vibrations were present throughout out the assembly cycle and by analysing when these large vibrations occur and for which types of motion, an optimal selection could be made. The point-to-point motion type running at 50% speed had a faster assembly time and significantly lower accelerations and oscillations than the other motion types. The spline-linear motion type running at around 30% speed was best for the component insertion due to its linear nature and improved repetition accuracy.
运动优化改善周期时间和减少振动的机器人组装的电子元件
传统上,六轴机器人在电子表面贴装装配中并不常用。然而,需要更灵活的生产系统,可以用于中低生产构建,这意味着这些机器人可以使用,因为它们的高度灵活性。本研究探讨了关节机器人在电子产品多元件PCB组装中的应用。为了提高这种自动化方法的潜力,研究人员使用了遗传算法来缩短周期时间,并进行了状态监测,以评估机器人结构在运行过程中的振动。通过研究运动类型,可以优化机器人的运动,以减少周期时间,最大限度地提高生产吞吐量,减少振动,提高装配过程的精度。这项研究利用了一个机器人装配单元和一个设定了不同速度的机器人。整个装配周期都存在振动,通过分析这些大振动发生的时间和运动类型,可以做出最佳选择。以50%速度运行的点对点运动类型装配时间更快,加速度和振荡明显低于其他运动类型。以30%左右的速度运行的样条直线运动类型由于其线性性质和提高重复精度而最适合组件插入。
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
AIMS Electronics and Electrical Engineering
AIMS Electronics and Electrical Engineering Engineering-Control and Systems Engineering
CiteScore
2.40
自引率
0.00%
发文量
19
审稿时长
8 weeks
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