Dynamics of Suspended Cable Driven Parallel Robots Using the Geometric Variable Strain Approach

2023 IEEE International Conference on Soft Robotics (RoboSoft) Pub Date : 2023-04-03 DOI:10.1109/RoboSoft55895.2023.10121928

A. Mathew, Ikhlas Mohamed Ben Hmida, Suad Alhaj Mustafa, Ahmed Nader Ahmed, R. Al-Rub, B. El-Khasawneh, F. Renda

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引用次数: 1

Abstract

Construction 3D printing technology has recently received significant attention as a method for creating construction components or printing entire buildings. The deployment of Cable Driven Parallel Robots (CDPRs) in large-scale 3D printing is being explored as a potential candidate due to their low cost, high speed, and design modularity. However, the cable's inertial and elastic properties may lead to sagging and vibration, making the system difficult to model. In this paper, we use the Geometric Variable Strain (GVS) model, a geometrically exact approach based on the Cosserat rod theory, to model the dynamics of a CDPR. The Cosserat rod theory accounts for deformation modes that are not considered in other models, while the geometric formulation ensures accurate and fast computation. We compare the dynamic simulation of a small-scale CDPR prototype at different speeds and with an experimental setup. We also study the dynamics of a large-scale system subject to step loading. We show that analyses of CDPR systems using the GVS approach can reveal new perspectives on their control, design, and development.

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基于几何变应变法的悬索驱动并联机器人动力学研究

建筑3D打印技术作为一种创建建筑构件或打印整个建筑物的方法，最近受到了极大的关注。由于其低成本、高速度和设计模块化，电缆驱动并联机器人(cdpr)在大规模3D打印中的应用正在被探索。然而，电缆的惯性和弹性特性可能导致下垂和振动，使系统难以建模。在本文中，我们使用几何变应变(GVS)模型，一种基于Cosserat棒理论的几何精确方法，来模拟CDPR的动力学。Cosserat杆理论考虑了其他模型没有考虑到的变形模式，而几何公式保证了计算的准确和快速。我们比较了一个小规模的CDPR原型在不同速度和实验装置下的动态模拟。我们还研究了受阶跃加载的大型系统的动力学。我们表明，使用GVS方法对CDPR系统进行分析可以揭示其控制、设计和开发的新视角。

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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2023 IEEE International Conference on Soft Robotics (RoboSoft)

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