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ChevBot – An Untethered Microrobot Powered by Laser for Microfactory Applications

Ruoshi Zhang, Andriy Sherehiy, Yang Zhong, Danming Wei, C. K. Harnett, Dan O. Popa

Year
2019
Citations
19

Abstract

In this paper, we introduce a new class of submillimeter robot (ChevBot) for microfactory applications in dry environments, powered by a 532 nm laser beam. ChevBot is an untethered microrobot propelled by a thermal Micro Electro Mechanical (MEMS) actuator upon exposure to the laser light. Novel models for opto-thermal-mechanical energy conversion are proposed to describe the microrobot's locomotion mechanism. First, an opto-thermal simulation model is presented which is experimentally validated with static displacement measurements with microrobots tethered to the substrate. Then, stick and slip motion of the microrobot was predicted using a dynamic extension of our simulation model, and experiments were conducted to validate this model in one dimension. Promising microrobot designs were fabricated on a silicon on insulator (SOI) wafer with 20 μm device layer and a dimple was assembled at the bottom to initiate directional locomotion on a silicon substrate. Validation experiments demonstrate that exposure to laser power below 2W and repetition frequencies below 60 kHz can generate actuator displacements of a few microns, and 46 μm/s locomotion velocity.

Keywords

ActuatorMicroelectromechanical systemsWaferSilicon on insulatorLaserMaterials scienceSiliconThermalRobotMechanical engineering

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