In-pipe wireless micro locomotive system

MHS'99. Proceedings of 1999 International Symposium on Micromechatronics and Human Science (Cat. No.99TH8478) Pub Date : 1999-11-23 DOI:10.1109/MHS.1999.819995

Hideaki Nishikawa, T. Sasaya, Takayuki Shibata, Takashi Kaneko, Naoki Mitumoto, S. Kawakita, N. Kawahara

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引用次数: 34

Abstract

We have developed an in-pipe micro locomotive system. This system is composed of an outside host and a microrobot. The outside host supplies energy and transmits commands to the robot by using microwaves. The microrobot is 9.5 mm in diameter and 60 mm in length. The microrobot moves in a pipe of 10 mm diameter without wire. The microrobot consists of a microwave (RF) module used for energy supply and communication, a control circuit and a locomotive mechanism using a piezoelectric bimorph actuator. The RF module consists of a compact antenna, power divider, rectifying circuits, filter and communication MMIC. The antenna receives two frequencies of microwaves: 22 GHz for energy supply and 24 GHz for communication. The rectifying circuits convert the microwave into DC. The demanded energy of 480 mW is supplied via microwave. The control circuit drives the locomotive device and other devices installed in the robot by outside commands. The direction and speed of the system are also controlled by commands. The condition of the system is communicated between the robot and the outside host. The locomotive mechanism using a piezoelectric bimorph actuator moves according to inertia drive method.

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管道内无线微机车系统

我们开发了一种管内微机车系统。该系统由外部主机和微型机器人组成。外部主机提供能量，并通过微波向机器人发送指令。这个微型机器人直径9.5毫米，长60毫米。微型机器人在直径10毫米的管道中移动，没有电线。该微型机器人由用于能量供应和通信的微波(RF)模块、控制电路和采用压电双晶片作动器的机车机构组成。射频模块由紧凑型天线、功率分配器、整流电路、滤波器和通信MMIC组成。天线接收两种频率的微波:22ghz用于能量供应和24ghz用于通信。整流电路把微波转换成直流电。所需的480兆瓦能量由微波提供。控制电路通过外部指令驱动安装在机器人上的机车装置和其他装置。系统的方向和速度也由指令控制。系统的状态在机器人和外部主机之间进行通信。采用压电双晶片作动器的机车机构采用惯性驱动方式运动。

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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MHS'99. Proceedings of 1999 International Symposium on Micromechatronics and Human Science (Cat. No.99TH8478)

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