Harnessing the Power of Vibration Motors to Develop Miniature Untethered Robotic Fishes

TL;DR

This paper introduces a miniature untethered robotic fish powered by vibration motors and bio-inspired fins, demonstrating effective propulsion and maneuverability for deep-sea exploration in confined spaces.

Contribution

It presents a novel design using ERM vibration motors for propulsion, enabling miniaturization and improved maneuverability of underwater robots.

Findings

Maximum speed of 1.36 body lengths per second

Minimum turning radius of 0.6 body lengths

Effective propulsion using bio-inspired fins and vibration motors

Abstract

Miniature underwater robots play a crucial role in the exploration and development of marine resources, particularly in confined spaces and high-pressure deep-sea environments. This study presents the design, optimization, and performance of a miniature robotic fish, powered by the oscillation of bio-inspired fins. These fins feature a rigid-flexible hybrid structure and use an eccentric rotating mass (ERM) vibration motor as the excitation source to generate high-frequency unidirectional oscillations that induce acoustic streaming for propulsion. The drive mechanism, powered by miniature ERM vibration motors, eliminates the need for complex mechanical drive systems, enabling complete isolation of the entire drive system from the external environment and facilitating the miniaturization of the robotic fish. A compact, untethered robotic fish, measuring 85*60*45 mm^3, is equipped with three bio-inspired fins located at the pectoral and caudal positions. Experimental results demonstrate that the robotic fish achieves a maximum forward swimming speed of 1.36 body lengths (BL) per second powered by all fins and minimum turning radius of 0.6 BL when powered by a single fin. These results underscore the significance of employing the ERM vibration motor in advancing the development of highly maneuverable, miniature untethered underwater robots for various marine exploration tasks.