Sage Journals: Discover world-class research

Abstract

This article presents a versatile soft crawling robot capable of rapid and effective locomotion. The robot mainly consists of two vacuum-actuated spring actuators and two electrostatic actuators. By programming the actuation sequences of different actuators, the robot is able to achieve two basic modes of locomotion: linear motion and turning. Subsequently, we have developed analytical models to interpret the static actuation performance of the robot body, including linear and bending motions. Moreover, an empirical dynamic model is also developed to optimize the locomotion speed in terms of frequency and duty cycle of the actuation signal. Furthermore, with the help of the strong electroadhesion force and fast response of the deformable body, the soft robot achieves a turning speed of 15.09°/s, which is one of the fastest among existing soft crawling robots to the best of our knowledge. In addition to the rapid and effective locomotion, the soft crawling robot can also achieve multiple impressive functions, including obstacle navigation in confined spaces, climbing a vertical wall with a speed of 6.67 mm/s (0.049 body length/s), carrying a payload of 69 times its self-weight on a horizontal surface, crossing over a 2 cm (0.15 body length) gap, and kicking a ball.

Get full access to this article

View all access options for this article.

References

Rus

, Tolley

. Design, fabrication and control of soft robots. Nature, 2015; 521:467–475.

Shepherd

, Ilievski

, Choi

, et al. Multigait soft robot. Proc Natl Acad Sci U S A, 2011; 108:20400–20403.

Tolley

, Shepherd

, Mosadegh

, et al. A resilient, untethered soft robot. Soft Robot, 2014; 1:213–223.

Wehner

, Truby

, Fitzgerald

et al. An integrated design and fabrication strategy for entirely soft, autonomous robots. Nature, 2016; 536:451–455.

Ijspeert

. Biorobotics: using robots to emulate and investigate agile locomotion. Science, 2014; 346:196–203.

Laschi

, Cianchetti

, Mazzolai

, et al. Soft robot arm inspired by the octopus. Adv Robot, 2012; 26:709–727.

Chen

, Liang

, Wu

, et al. Pneumatically actuated soft robotic arm for adaptable grasping. Acta Mech Solida Sin, 2018; 31:608–622.

Lin

H-T

, Leisk

, Trimmer

. GoQBot: a caterpillar-inspired soft-bodied rolling robot. Bioinspir Biomim, 2011; 6:026007.

Zou

, Lin

, Ji

, et al. A reconfigurable omnidirectional soft robot based on caterpillar locomotion. Soft Robot, 2018; 5:164–174.

10.

Umedachi

, Vikas

, Trimmer

. Softworms: the design and control of non-pneumatic, 3D-printed, deformable robots. Bioinspir Biomim, 2016; 11:025001.

11.

Ning

, Ti

, Liu

. Inchworm inspired pneumatic soft robot based on friction hysteresis. J Robot Autom, 2017; 1:54–63.

12.

Moreira

, Abundis

, Aguirre

, et al. An inchworm-inspired robot based on modular body, electronics and passive friction pads performing the two-anchor crawl gait. J Bionic Eng, 2018; 15:820–826.

13.

Godaba

, Li

, Wang

, et al. A soft jellyfish robot driven by a dielectric elastomer actuator. IEEE Robot Autom Lett, 2016; 1:624–631.

14.

Villanueva

, Smith

, Priya

. A biomimetic robotic jellyfish (Robojelly) actuated by shape memory alloy composite actuators. Bioinspir Biomim, 2011; 6:36004.

15.

Shintake

, Shea

, Floreano

. Biomimetic underwater robots based on dielectric elastomer actuators. IEEE/RSJ Int Conf Intell Robot Syst, 2016; 2:4957–4962.

16.

Robertson

, Paik

. New soft robots really suck: vacuum-powered systems empower diverse capabilities. Sci Robot, 2017; 2:eaan6357.

17.

Wang

, Lee

J-Y

, Rodrigue

, et al. Locomotion of inchworm-inspired robot made of smart soft composite (SSC). Bioinspir Biomim, 2014; 9:046006.

18.

Koh

, Cho

. Omegabot: biomimetic inchworm robot using SMA coil actuator and smart composite microstructures (SCM). In: 2009 IEEE International Conference on Robotics and Biomimetics (ROBIO), Guilin, China, December 19–23, 2009, pp. 1154–1159.

19.

Chang

, Kim

. Aquatic ionic-polymer-metal-composite insectile robot with multi-DOF legs. IEEE/ASME Trans Mechatronics, 2013; 18:547–555.

20.

Must

, Kaasik

, Põldsalu

, et al. Ionic and capacitive artificial muscle for biomimetic soft robotics. Adv Eng Mater, 2015; 17:84–94.

21.

Qin

, Tang

, Gupta

, et al. A soft robot capable of 2D mobility and self-sensing for obstacle detection and avoidance. Smart Mater Struct, 2018; 27:45017.

22.

Cao

, Qin

, Liu

, et al. Untethered soft robot capable of stable locomotion using soft electrostatic actuators. Extrem Mech Lett, 2018; 21:9–16.

23.

, Zou

, Mao

, et al. Agile and resilient insect-scale robot. Soft Robot, 2018; 6:133–141.

24.

, Jimenez

TGD

, Qu

, et al. Regulating surface traction of a soft robot through electrostatic adhesion control. In: 2017 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Vancouver, BC, Canada, September 24–28, 2017, pp. 488–493.

25.

, Vogt

, Rus

, et al. Fluid-driven origami-inspired artificial muscles. Proc Natl Acad Sci U S A, 2017; 114:13132–13137.

26.

Longo

, Muscato

. The Alicia3 climbing robot. IEEE Robot Autom Mag, 2006; 13:42–50.

27.

Spenko

, Haynes

, Saunders

et al. Biologically inspired climbing with a hexapedal robot. J F Robot, 2008; 25:223–242.

28.

Kim

, Spenko

, Trujillo

, et al. Smooth vertical surface climbing with directional adhesion. IEEE Trans Robot, 2008; 24:65–74.

29.

Unver

, Sitti

. Flat dry elastomer adhesives as attachment materials for climbing robots. IEEE Trans Robot, 2010; 26:131–141.

30.

Breckwoldt

, Daltorio

, Heepe

, et al. Walking inverted on ceilings with wheel-legs and micro-structured adhesives. In: 2015 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Hamburg, Germany, September 28–October 2, 2015, pp. 3308–3313.

31.

Graule

, Chirarattananon

, Fuller

et al. Perching and takeoff of a robotic insect on overhangs using switchable electrostatic adhesion. Science, 2016; 352:978–982.

32.

Prahlad

, Pelrine

, Stanford

, et al. Electroadhesive robots—wall climbing robots enabled by a novel, robust, and electrically controllable adhesion technology. In: 2008 IEEE International Conference on Robotics and Automation, Pasadena, CA, May 19–23, 2008, pp. 3028–3033.

33.

Keller

, Gordon

. Equivalent stress and strain distribution in helical compression springs subjected to bending. J Strain Anal Eng Des, 2011; 46:405–415.

34.

Seok

, Onal

, Cho

, et al. Meshworm: a peristaltic soft robot with antagonistic nickel titanium coil actuators. IEEE/ASME Trans Mechatronics, 2012; 18:1–13.

35.

Cheng

, Ishigami

, Hawthorne

, et al. Design and analysis of a soft mobile robot composed of multiple thermally activated joints driven by a single actuator. In: 2010 IEEE International Conference on Robotics and Automation (ICRA), Anchorage, AK, May 3–7, 2010, pp. 5207–5212.

36.

Kandhari

, Huang

, Daltorio

et al. Body stiffness in orthogonal directions oppositely affects worm-like robot turning and straight-line locomotion. Bioinspir Biomim, 2018; 13:26003.

37.

Malley

, Rubenstein

, Nagpal

. Flippy: a soft, autonomous climber with simple sensing and control. In: 2017 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Vancouver, BC, Canada, September 24–28, 2017, pp. 6533–6540.

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.

18.17 MB

12.83 MB

40.04 MB

3.84 MB

2.20 MB

2.86 MB

1.98 MB

0.02 MB

0.07 MB

0.10 MB

0.12 MB

0.04 MB

0.15 MB

0.02 MB

0.00 MB

A Versatile Soft Crawling Robot with Rapid Locomotion

Abstract

Abstract

Get full access to this article

References

Supplementary Material