The Effect of Different Scales on the Crawling Rate of Bionic Snake Robot *

2018 WRC Symposium on Advanced Robotics and Automation (WRC SARA) Pub Date : 2018-08-01 DOI:10.1109/WRC-SARA.2018.8584156

Nana Zhu, Hongbin Zang, Bing Liao, Dongsheng Liu, Jiangmin Tuo, Tao Zhou, Qian Wang

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引用次数: 3

Abstract

Inspired by the S winding movement of snakes in nature, and based on the analysis of the movement principle of snakes, the design of a kind of bionic snake robot driven by single motor is proposed. Its core mechanism consists of a spatial helix structure projected on the plane as a transverse wave and a series of articulated link clusters with touch feet (scale-like). The spiral motion of helical structure can be realized by single motor energy supply, and then the transverse wave motion of the link cluster is driven, and the snake's curve bionic motion is realized. Based on virtual prototyping technology, the motion simulation of different shaped touch feet structure is carried out. 3D printing technology is used to produce a prototype. A series of experiments are designed to compare the forward and backward motion of snake robot with different shaped touch feet. The experimental results show that the curved and oblique contact feet can make the bionic robot snake have high speed, verifying the feasibility and effectiveness of the design. This study aims to provide a new pattern of motion for the research of bionic snake robot.

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不同尺度对仿生蛇机器人爬行速度的影响*

受自然界蛇类S型缠绕运动的启发，在分析蛇类运动原理的基础上，提出了一种单电机驱动的仿生蛇类机器人的设计。其核心机构由平面上以横波形式投射的空间螺旋结构和一系列带有触脚(类似尺度)的铰接链接簇组成。通过单电机供电，实现螺旋结构的螺旋运动，再驱动连杆簇的横波运动，实现蛇的曲线仿生运动。基于虚拟样机技术，对不同形状的触脚结构进行了运动仿真。3D打印技术被用来制作原型。设计了一系列实验来比较不同形状的触脚蛇机器人的前后运动。实验结果表明，弯曲和倾斜的接触足可以使仿生蛇机器人具有较高的速度，验证了设计的可行性和有效性。本研究旨在为仿生蛇形机器人的研究提供一种新的运动模式。

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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2018 WRC Symposium on Advanced Robotics and Automation (WRC SARA)

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