Development of a New Compliant Remote Center of Motion (RCM) Mechanism for Vitreoretinal Surgery

2020 6th International Conference on Control, Automation and Robotics (ICCAR) Pub Date : 2020-04-01 DOI:10.1109/ICCAR49639.2020.9108005

Muhammed Gaafar, M. Magdy, Abdullah T. Elgammal, A. El-Betar, Ahmed M. Saeed

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引用次数: 2

Abstract

Minimally invasive surgery, especially vitreoretinal surgery, requires high precision micromanipulation for sensitive tissues. Robot-assisted surgery helps to reduce the imperfections of safety, stiffness, and ergonomics. Using Remote Center of Motion mechanism (RCM) in such surgeries ensures rigidity and stability for the manipulation and the safety for the patient. In this paper, a new planer compliant RCM mechanism is proposed. The performance of the proposed compliant mechanism is determined using finite element analysis by ANSYS software. Compliant mechanism with flexure joints achieves the required motion with acceptable rigidity and reduces the demerits of mechanical joints such as friction, backlash, and lubricant. Also, the pseudo-rigid-body method is utilized to model the compliant mechanism as a rigid body. Then, MS-ADAMS software is exploited for the dynamic modelling of the proposed mechanism. The co-simulation between MS-ADAMS and MATLAB is carried out to validate the motion of the mechanism using a PID controller. The results show improvements for the proposed design in terms of parasitic motions, RCM point drift and joint stiffening.

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用于玻璃体视网膜手术的新型柔性远程运动中心(RCM)机构的研制

微创手术，尤其是玻璃体视网膜手术，需要对敏感组织进行高精度的显微操作。机器人辅助手术有助于减少安全性，刚度和人体工程学的缺陷。在此类手术中使用遥控运动中心机构(RCM)可确保操作的刚性和稳定性以及患者的安全性。本文提出了一种新的平面柔性RCM机构。采用ANSYS软件对柔性机构进行有限元分析，确定了柔性机构的性能。具有柔性关节的柔性机构以可接受的刚度实现所需的运动，并减少机械关节的摩擦、间隙和润滑剂等缺点。同时，利用拟刚体方法将柔性机构建模为刚体。然后，利用MS-ADAMS软件对所提出的机构进行动态建模。采用MS-ADAMS和MATLAB联合仿真，采用PID控制器对机构的运动进行了验证。结果表明，该设计在寄生运动、RCM点漂移和关节加劲方面有所改进。

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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2020 6th International Conference on Control, Automation and Robotics (ICCAR)

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