Design and Analysis of a Tensegrity Mechanism for a Bio-Inspired Robot

Volume 5A: 43rd Mechanisms and Robotics Conference Pub Date : 2019-08-18 DOI:10.1115/DETC2019-97544

Swaminath Venkateswaran, M. Furet, D. Chablat, P. Wenger

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引用次数: 7

Abstract

Piping inspection robots are of greater interests in industries such as nuclear, chemical and sewage. The design of such robots is highly challenging owing to factors such as locomotion inside pipes with varying diameters, cable management, and complex pipe bends (or) junctions. A rigid bio-inspired caterpillar type piping inspection robot was developed at LS2N, France. By introducing tensegrity mechanisms and four-bar wheel mechanisms, the design of this robot is modified into a reconfigurable system. The tensegrity mechanism employs a passive universal joint with three tension springs and three cables for actuation. The positioning of the end effector with respect to the base of the mechanism plays an important role in determining the maximum tilt angle (or) bending limit of the system. By workspace analysis of three case studies, the best solution is chosen which generates the maximum tilt. A static force analysis is then performed on the mechanism to determine its stability under the influences of preload. By the modification of design parameters, stable configurations are determined followed by which cable actuation of mechanism is analyzed for estimating applied forces.

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仿生机器人张拉整体机构的设计与分析

管道检测机器人在核能、化学和污水处理等行业更受关注。由于在不同直径的管道内移动、电缆管理和复杂的管道弯道(或)连接处等因素，这种机器人的设计极具挑战性。法国LS2N公司开发了一种刚性仿生履带式管道检测机器人。通过引入张拉整体机构和四杆轮机构，将该机器人的设计修改为可重构系统。张拉整体机构采用一个被动万向节，有三个张拉弹簧和三根电缆作为驱动。末端执行器相对于机构基座的定位在确定系统的最大倾斜角(或)弯曲极限方面起着重要作用。通过对三个案例的工作空间分析，选择了产生最大倾斜的最佳解决方案。然后对机构进行静力分析，以确定其在预紧力影响下的稳定性。通过对设计参数的修改，确定了机构的稳定构型，并对机构的索致动进行了分析，估算了机构的受力。

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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Volume 5A: 43rd Mechanisms and Robotics Conference

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