A New Type of Flapping-Wing Robot Based on the Stephenson II Six-Bar Mechanism

2018 IEEE International Conference on Mechatronics, Robotics and Automation (ICMRA) Pub Date : 2018-05-01 DOI:10.1109/ICMRA.2018.8490557

Zheng Guo, Zhongfeng Guo, Liang Zhao, Shaoyun Zhou, Wen-xiu Chen

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Abstract

This paper proposes a new type of flapping-wing robot based on the Stephenson II six-bar mechanism, which can reduce the vulnerability of large energy consumption, inconveniences, limited range of activities and so on in flapping-wing air vehicles. We use the biomimetic robot to simulate the flight and running patterns of a real bird, and then use the metamorphic mechanism to enable them to switch freely in two modes. For flapping-wing flight mechanism, we choose the joint planar crank rocker mechanism, which is very suitable for simulating the movement characteristics of the flying of a bird. As for the leg mechanism, the Stephenson II six-bar mechanism is selected as its structure and the optimization is based on the position and length of the crank mechanism on the motion characteristics of the robot. The presented method starts from the design of the structure, as well as modeling on work space, and finally to achievement on size synthesis. Then the simulation of the bionic legs shows that they have excellent stability. In the end, the physical model of the whole flapping-wing robot is tested and the results show that the robot can accurately switch between running and flying modes and its gait has a good bionic effect.

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基于Stephenson II型六杆机构的新型扑翼机器人

本文提出了一种基于Stephenson II型六杆机构的新型扑翼机器人，该机器人可以减少扑翼飞行器耗能大、操作不便、活动范围有限等缺点。我们利用仿生机器人模拟真鸟的飞行和奔跑模式，然后利用变形机构使它们在两种模式下自由切换。对于扑翼飞行机构，我们选择了联合平面曲柄摇杆机构，该机构非常适合模拟鸟类飞行的运动特性。对于腿机构，选择Stephenson II型六杆机构作为其结构，并根据机器人运动特性对曲柄机构的位置和长度进行优化。该方法从结构的设计，工作空间的建模，到尺寸的综合。仿真结果表明，仿生腿具有良好的稳定性。最后，对整个扑翼机器人的物理模型进行了测试，结果表明，该扑翼机器人能够准确地在奔跑和飞行模式之间切换，其步态具有良好的仿生效果。

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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来源期刊

2018 IEEE International Conference on Mechatronics, Robotics and Automation (ICMRA)

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