An Agile Multimodal Microrobot with Architected Passively Morphing Wheels

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2024 Dec 18

PMID 39693445

Authors

Yuchen Lai

Chuanqi Zang

Guoquan Luo

Shiwei Xu

Renheng Bo

Jianzhong Zhao

Youzhou Yang

Tianqi Jin

Yu Lan

Yuejiao Wang

Li Wen

Wenbo Pang

Yihui Zhang

Affiliations

Soon will be listed here.

Abstract

Multimodal microrobots are of growing interest due to their capabilities to navigate diverse terrains, with promising applications in inspection, exploration, and biomedicine. Despite remarkable progress, it remains challenging to combine the attributes of excellent maneuverability, low power consumption, and high robustness in a single multimodal microrobot. We propose an architected design of a passively morphing wheel that can be stabilized at distinct geometric configurations, relying on asymmetric bending stiffness of bioinspired tentacle structures. By integrating such wheels with electromagnetic motors and a flexible body, we develop a highly compact, lightweight, multimodal microrobot (length ~32 mm and mass ~4.74 g) with three locomotion gaits. It has high motion speed (~21.2 BL/s), excellent agility (relative centripetal acceleration, ~206.9 BL/s), low power consumption (cost of transport, ~89), high robustness, and strong terrain adaptabilities. Integration of batteries and a wireless control module enables developments of an untethered microrobot that maintains high motion speed and excellent agility, with capabilities of traveling in hybrid terrains.

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