M Banu Sundareswari, K Dhanalakshmi, A Vimala Starbino, G Then Mozhi
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引用次数: 0
Abstract
This study describes the design of a parallel spatial manipulator with four degrees of freedom actuated with shape memory alloy (SMA) wire to validate the use of SMA in complicated mechatronics systems. The manipulator has a closed kinematic structure, which includes a fixed base and a moving square platform (end effector). The four arms of the manipulator are SMA wires fastened between the fixed base and the end effector. SMA wire-based actuators replace bulky conventional revolute actuators. This work spotlights the development of an actuator model, dimensional analysis, and design of cascade control strategies of various PID and sliding mode controller in their integral and fractional order configurations. Experimental evaluation of the actuator is performed through trajectory tracking to quantify the different controller configurations. The experimental results indicate that the parallel manipulator associated with SMA wire actuators is the best alternative to conventional motion stages for highly precise micro-positioning and tracking applications in the fields of 3D printing, intricate surgical operations, the medical and pharmaceutical industries, and flight and gaming simulators.
本研究介绍了利用形状记忆合金(SMA)线材驱动的四自由度平行空间机械手的设计,以验证 SMA 在复杂机电一体化系统中的应用。该机械手采用封闭式运动结构,包括一个固定基座和一个移动方形平台(末端效应器)。机械手的四个臂是固定在固定基座和末端效应器之间的 SMA 线。基于 SMA 线的执行器取代了笨重的传统旋转执行器。本作品重点介绍了致动器模型的开发、尺寸分析以及各种 PID 和滑动模式控制器在积分阶和分数阶配置下的级联控制策略的设计。通过轨迹跟踪对致动器进行了实验评估,以量化不同的控制器配置。实验结果表明,在 3D 打印、复杂的外科手术、医疗和制药行业以及飞行和游戏模拟器等领域的高精度微定位和跟踪应用中,与 SMA 线执行器相关的并联机械手是传统运动平台的最佳替代品。
期刊介绍:
The Journal of Intelligent Materials Systems and Structures is an international peer-reviewed journal that publishes the highest quality original research reporting the results of experimental or theoretical work on any aspect of intelligent materials systems and/or structures research also called smart structure, smart materials, active materials, adaptive structures and adaptive materials.