Multi-Objective Optimization of a Three Degree-of-Freedom Translational Parallel Kinematic Machine with Coplanar Rails

Joy Sukumar Patnala, A. B. K. Rao, Sanjay K Darvekar
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Abstract

Several advancements in the field of parallel manipulators have taken place in recent days as they offer many advantages over serial manipulators in terms of accuracy, agility, stiffness, speed, etc. The Parallel Kinematic Machines (PKMs) with lower Degree of Freedom (DoF) joints are being explored for a variety of industrial applications and, in particular, machining applications as these offer more accuracy, high machining capability, and more stiffness. This research work focuses on the modeling, kinematics, workspace and dexterity analyses of a 3DoF Translational PKM having coplanar rails along the Cartesian axes: -X, +X, +Y. Actuation of sliders, independently along the respective rails, offer the tool platform pure translational motion. Fixed length links are used to connect the sliders and tool platform. The PKM under study is modeled in CATIA. Inverse kinematics and workspace analysis are carried out using the performance indices, namely, Workspace Volume Index (WVI) and Global Condition Index (GCI). Attempts are also made to find the optimal dimensions of the PKM through multi-objective optimization using Genetic Algorithms in MATLAB. The methodology presented is helpful to predict the PKM's performance capability while the results obtained are helpful for the development of a physical prototype necessary for further experimental investigations.
带共面导轨的三自由度平移并联运动机械的多目标优化
并联机械手在精度、灵活性、刚度、速度等方面比串联机械手具有许多优势,因此近年来在并联机械手领域取得了一些进展。具有较低自由度(DoF)关节的并联机械手(PKM)正被用于各种工业应用,特别是机械加工应用,因为这些机械手具有更高的精度、更强的加工能力和更大的刚度。这项研究工作的重点是对沿笛卡尔轴(-X、+X、+Y)共面导轨的 3DoF 横向 PKM 进行建模、运动学、工作空间和灵巧性分析。滑块沿各自的轨道独立驱动,为工具平台提供纯平移运动。滑块和工具平台之间采用固定长度的链接连接。所研究的 PKM 在 CATIA 中建模。使用性能指数,即工作空间体积指数(WVI)和全局状态指数(GCI),进行了逆运动学和工作空间分析。此外,还尝试使用 MATLAB 中的遗传算法,通过多目标优化找到 PKM 的最佳尺寸。所提出的方法有助于预测 PKM 的性能能力,而获得的结果则有助于开发进一步实验研究所需的物理原型。
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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