Issue 7, 2023

Hybrid artificial muscle: enhanced actuation and load-bearing performance via an origami metamaterial endoskeleton

Abstract

Owing to their compliance, soft robots demonstrate enhanced compatibility with humans and the environment compared with traditional rigid robots. However, ensuring the working effectiveness of artificial muscles that actuate soft robots in confined spaces or under loaded conditions remains a challenge. Drawing inspiration from avian pneumatic bones, we propose the incorporation of a lightweight endoskeleton into artificial muscles to augment the mechanical integrity and tackle load-bearing environmental difficulties. We present a soft origami hybrid artificial muscle that features a hollow origami metamaterial interior with a rolled dielectric elastomer exterior. The programmable nonlinear origami metamaterial endoskeleton significantly improves the blocked force and load-bearing capability of the dielectric elastomer artificial muscle and an increased actuation strain. The origami hybrid artificial muscle demonstrates a maximum strain of 8.5% and a maximum actuating stress of 12.2 mN mm−2 at 30 V μm−1 while preserving its actuating ability, even under a 450 mN load, which is equivalent to 155 times its own weight. We further investigate the dynamic responses and demonstrate the potential use of the hybrid artificial muscle in flapping-wing actuation applications.

Graphical abstract: Hybrid artificial muscle: enhanced actuation and load-bearing performance via an origami metamaterial endoskeleton

Supplementary files

Article information

Article type
Communication
Submitted
12 Apr 2023
Accepted
05 Jun 2023
First published
06 Jun 2023

Mater. Horiz., 2023,10, 2398-2411

Hybrid artificial muscle: enhanced actuation and load-bearing performance via an origami metamaterial endoskeleton

B. Tian, Z. Yan, Q. Li, X. Hu and T. Tan, Mater. Horiz., 2023, 10, 2398 DOI: 10.1039/D3MH00551H

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