Sage Journals: Discover world-class research

Abstract

Small-scale soft robots, despite their potential for adaptability in unknown environments, often encounter performance constraints due to inherent limitations within soft actuators and compact bodies. To address this problem, we proposed a fast-moving soft robot driven by electroactive materials. The robot combines the advantages of dielectric elastomer actuators (DEAs) and shape memory alloy (SMA) spring actuators, enabling its high-performance multi-modal locomotion in a small and lightweight design. Theoretical models were constructed for both DEAs and SMA spring actuators to analyze the performance of the designed robot. The robot’s design parameters were optimized based on these models to improve its running and jumping performance. The designed robot has a size of 40 × 45 × 25 mm and a weight of 3.5 g. The robot can achieve a running speed of 91 mm/s, ascend a 9° slope, and execute turning motions via an asymmetrical actuation of SMA spring actuators. The robot also demonstrates high-performance jumping motions with a maximum jumping height of 80 mm and the ability to jump over a 40 mm high obstacle. This work introduces a novel approach to designing small-scale soft terrestrial robots, enhancing their agility and mobility in obstacle-laden environments.

Get full access to this article

View all access options for this article.

References

Chen

, Liang

, Miao

, et al. Elevation control of a soft jumping robot. In: 2021 IEEE International Conference on Robotics and Automation (ICRA), Xi’an, China; 2021, pp. 11843–11849.

Wharton

, You

, Jenkinson

, et al. Tetraflex: A multigait soft robot for object transportation in confined environments. IEEE Robot Autom Lett, 2023; 8(8):5007–5014.

Talas

, Baydere

, Altinsoy

, et al. Design and development of a growing pneumatic soft robot. Soft Robot, 2020; 7(4):521–533.

Tang

, Du

, Jiang

, et al. A pipeline inspection robot for navigating tubular environments in the sub-centimeter scale. Sci Robot, 2022; 7(66):eabm8597.

Adams

, Sridar

, Thalman

, et al. Water pipe robot utilizing soft inflatable actuators. In: 2018 IEEE International Conference on Soft Robotics (RoboSoft), Livorno, Italy; 2018, pp.321–326.

Lin

, Xu

, Juang

. Single-Actuator soft robot for in-pipe crawling. Soft Robot, 2023; 10(1):174–186.

, Lum

, Mastrangeli

, et al. Small-scale soft-bodied robot with multimodal locomotion. Nature, 2018; 554(7690):81–85.

Zhao

, Dai

, Yao

. Liquid-Metal magnetic soft robot with reprogrammable magnetization and stiffness. IEEE Robot Autom Lett, 2022; 7(2):4535–4541.

Han

, Guo

, Chen

, et al. Submillimeter-scale multimaterial terrestrial robots. Sci Robot, 2022; 7(66):eabn0602.

10.

, Wu

, Nishikawa

, et al. Soft robotic origami crawler. Sci Adv, 2022; 8(13):eabm7834.

11.

, Liu

, Cacucciolo

, et al. An autonomous untethered fast soft robotic insect driven by low-voltage dielectric elastomer actuators. Sci Robot, 2019; 4(37):eaaz6451.

12.

Drotman

, Jadhav

, Karimi

, et al. 3D printed soft actuators for a legged robot capable of navigating unstructured terrain. In: 2017 IEEE International Conference on Robotics and Automation (ICRA), Singapore; 2017, pp. 5532–5538.

13.

Matia

, Kaiser

, Shepherd

, et al. Harnessing nonuniform pressure distributions in soft robotic actuators. Adv Intell Syst, 2023; 5(2):2200330.

14.

Chen

, Yuan

, Guo

, et al. Legless soft robots capable of rapid, continuous, and steered jumping. Nat Commun, 2021; 12(1):7028.

15.

Lin

, Leisk

, Trimmer

. GoQBot: A caterpillar-inspired soft-bodied rolling robot. Bioinspir Biomim, 2011; 6(2):26007.

16.

Tang

, Chi

, Sun

, et al. Leveraging elastic instabilities for amplified performance: Spine-inspired high-speed and high-force soft robots. Sci Adv, 2020; 6(19):eaaz6912.

17.

Mao

, Schiller

, Danninger

, et al. Ultrafast small-scale soft electromagnetic robots. Nat Commun, 2022; 13(1):4456.

18.

Zhao

, Zhang

, McCoul

, et al. Soft and fast hopping-running robot with speed of six times its body length per second. Soft Robot, 2019; 6(6):713–721.

19.

Duduta

, Berlinger

, Nagpal

, et al. Tunable multi-modal locomotion in soft dielectric elastomer robots. IEEE Robot Autom Lett, 2020; 5(3):3868–3875.

20.

Liang

, Wu

, Yim

, et al. Electrostatic footpads enable agile insect-scale soft robots with trajectory control. Sci Robot, 2021; 6(55):eabe7906.

21.

Ahn

, Liang

, Cai

. Bioinspired design of light-powered crawling, squeezing, and jumping untethered soft robot. Adv Mater Technol, 2019; 4(7):1900185.

22.

Baek

, Yim

, Chae

, et al. Ladybird beetle–inspired compliant origami. Sci Robot, 2020; 5(41):eaaz6262.

23.

Chen

, Tao

, Cao

, et al. A soft, lightweight flipping robot with versatile motion capabilities for wall-climbing applications. IEEE Trans Robot, 2023; 39(5):3960–3976.

24.

Tang

, Zhang

, Lin

, et al. Switchable adhesion actuator for amphibious climbing soft robot. Soft Robot, 2018; 5(5):592–600.

25.

Zhang

, Yang

, Yan

, et al. Inchworm Inspired Multimodal Soft Robots With Crawling, Climbing, and Transitioning Locomotion. IEEE Trans Robot, 2022; 38(3):1806–1819.

26.

Zhakypov

, Mori

, Hosoda

, et al. Designing minimal and scalable insect-inspired multi-locomotion millirobots. Nature, 2019; 571(7765):381–386.

27.

Patel

, Huang

, Luo

, et al. Highly dynamic bistable soft actuator for reconfigurable multimodal soft robots. Adv Mater Technol, 2022; 8(2):2201259.

28.

Yun

, Liu

, Leng

, et al. A millimeter-scale multilocomotion microrobot capable of controlled crawling and jumping. Soft Robot, 2024; 11(2):361–370.

29.

Misu

, Yoshii

, Mochiyama

. A compact wheeled robot that can jump while rolling. In: 2018 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). Madrid, Spain; pp. 7507–7512.

30.

Spiegel

, Sun

, Zhao

. A shape-changing wheeling and jumping robot using tensegrity wheels and bistable mechanism. IEEE/ASME Trans Mechatron, 2023; 28(4):2073–2082.

31.

Chiang Foo

, Cai

, Jin Adrian Koh

, et al. Model of dissipative dielectric elastomers. J Appl Phys, 2012; 111(3):34102.

32.

, Ryu

, Cho

, et al. Engineering design framework for a shape memory alloy coil spring actuator using a static two-state model. Smart Mater Struct, 2012; 21(5):55009.

33.

Plante

, Dubowsky

. Large-scale failure modes of dielectric elastomer actuators. Int J Solids Struct, 2006; 43(25–26):7727–7751.

34.

Zhao

, Suo

. Method to analyze programmable deformation of dielectric elastomer layers. Appl Phys Lett, 2008; 93(25):251902.

35.

Mitchell

, Martin

, Keplinger

. A pocket-sized ten-channel high voltage power supply for soft electrostatic actuators. Adv Mater Technol, 2022; 7(8):2101469.

36.

Nishikawa

, Arai

, Niiyama

, et al. Coordinated use of structure-integrated bistable actuation modules for agile locomotion. IEEE Robot Autom Lett, 2018; 3(2):1018–1024.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

Small-Scale Soft Terrestrial Robot with Electrically Driven Multi-Modal Locomotion Capability

Abstract

Get full access to this article

References

Supplementary Material