Sage Journals: Discover world-class research

Abstract

Soft climbing robots have attracted much attention of researchers for their potential applications on the wall or inside the tube. However, making a soft robot climb on the outer surface of a rod or tube by agile and efficient motion has long been a challenge. Inspired by the winding climbing locomotion of arboreal snakes, a tethered pneumatic-actuated winding-styled soft rod-climbing robot that consists of two winding actuators and a telescopic actuator is proposed in this work. Based on constant curvature assumption, we develop a theoretical model to analyze the linear and bending motion of the actuators. We demonstrate that our robot can perform climbing locomotion similar to snakes, including turning around a corner along a rod, climbing a vertical rod with a maximum speed of 30.85 mm/s (0.193 body length/s), and carrying a larger payload (weight, 500 g, more than 25 times its self-weight) than existing soft climbing robots do on a vertical surface. In addition, the experimental tests exhibit the potential applications of the robot in special environments such as high-voltage cables, nuclear power plants, and underwater sites.

Get full access to this article

View all access options for this article.

References

Tur

JMM

, Garthwaite

. Robotic devices for water main in-pipe inspection: a survey. J. Field Robot, 2010; 27:491–508.

Chu

, Jung

, Han

, et al. A survey of climbing robots: locomotion and adhesion. Int J Precis Eng Manuf, 2010; 11:633–647.

Schmidt

, Berns

. Climbing robots for maintenance and inspections of vertical structures: a survey of design aspects and technologies. Robot Auton Syst, 2013; 61:1288–1305.

Lam

, Xu

. Biologically inspired tree-climbing robot with continuum maneuvering mechanism. J Field Robot, 2006; 23:245–267.

Laschi

, Mazzolai

, Cianchetti

. Soft robotics: technologies and systems pushing the boundaries of robot abilities. Sci Robot, 2016; 1:eaah3690.

Rus

, Tolley

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

Majidi

. Soft robotics: a perspective—current trends and prospects for the future. Soft Robot, 2014; 1:5–11.

Kim

, Laschi

, Trimmer

. Soft robotics: a bioinspired evolution in robotics. Trends Biotechnol, 2013; 31:287–294.

Shepherd

, Ilievski

, Choi

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

10.

Tolley

, Shepherd

, Mosadegh

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

11.

Wang

, Sim

, Chen

, et al. Soft ultrathin electronics innervated adaptive fully soft robots. Adv Mater, 2018; 30:1706695.

12.

Umedachi

, Vikas

, Trimmer

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

13.

Rafsanjani

, Zhang

, Liu

, et al. Kirigami skins make a simple soft actuator crawl. Sci Robot, 2018; 3:eaar7555.

14.

Cao

, Qin

, Liu

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

15.

Wang

, Lee

, Rodrigue

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

16.

Must

, Kaasik

, Po˜ldsalu

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

17.

, Zou

, Mao

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

18.

, Zhang

, Yang

, et al. A bioinspired multilegged soft millirobot that functions in both dry and wet conditions. Nat Commun, 2018; 9:3944.

19.

Rogóż

, Zeng

, Xuan

, et al. Light-driven soft robot mimics caterpillar locomotion in natural scale. Adv Opt Mater, 2016; 4:1689–1694.

20.

Kim

, Spenko

, Trujillo

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

21.

Robertson

, Paik

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

22.

Verma

, Ainla

, Yang

, et al. A soft tube-climbing robot. Soft Robot, 2018; 5:133–137.

23.

Tang

, Zhang

, Lin

, et al. Switchable adhesion actuator for amphibious climbing soft robot. Soft Robot, 2018; 5:1–9.

24.

, Zou

, Zhao

, et al. Soft wall-climbing robots. Sci Robot, 2018; 3:eaat2874.

25.

Qin

, Liang

, Huang

, et al. A versatile soft crawling robot with rapid locomotion. Soft Robot, 2019; 6:455–467.

26.

Kanada

, Giardina

, Howison

, et al. Reachability improvement of a climbing robot based on large deformations induced by tri-tube soft actuators. Soft Robot, 2019; 6:483–494.

27.

Zhang

, Fan

, Yang

, et al. Worm-like soft robot for complicated tubular environments. Soft Robot, 2019; 6:399–413.

28.

Lin

, Leisk

, Trimmer

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

29.

Bartlett

, Tolley

, Overvelde

JTB

, et al. A 3D printed, functionally graded soft robot powered by combustion. Science, 2015; 349:161–165.

30.

Shepherd

, Stokes

, Freake

, et al. Using explosions to power a soft robot. Angew Chem Int Ed Engl, 2013; 52:2892–2896.

31.

Christianson

, Goldberg

, Deheyn

, et al. Translucent soft robots driven by frameless fluid electrode dielectric elastomer actuators. Sci Robot, 2018; 3:eaat1893.

32.

Wang

, Yang

, Chen

, et al. A biorobotic adhesive disc for underwater hitchhiking inspired by the remora suckerfish. Sci Robot, 2017; 2:eaan8072.

33.

, Li

, Liang

, et al. Fast-moving soft electronic fish. Sci Adv, 2017; 3:e1602045.

34.

Wen

, Ren

, Santo

, et al. Understanding fish linear acceleration using an undulatory biorobotic model with soft fluidic elastomer actuated morphing median fins. Soft Robot, 2018; 5:375–388.

35.

Marchese

, Onal

, Rus

. Autonomous soft robotic fish capable of escape maneuvers using fluidic elastomer actuators. Soft Robot, 2014; 1:75–87.

36.

Hawkes

, Blumenschein

, Greer

, et al. A soft robot that navigates its environment through growth. Sci Robot, 2017; 2:eaan3028.

37.

Greer

, Morimoto

, Okamura

, et al. A soft, steerable continuum robot that grows via tip extension. Soft Robot, 2018; 6:95–108.

38.

Kaplan

When snakes fall from trees. Nature, 2008. DOI: 10.1038/news.2008.641.

39.

Berthé

, Westhoff

, Bleckmann

, et al. Surface structure and frictional properties of the skin of the Amazon tree boa Corallus hortulanus (Squamata, Boidae). J Comp Physiol A, 2009; 195:311–318.

40.

Byrnes

, Jayne

. Gripping during climbing of arboreal snakes may be safe but not economical. Biol Lett, 2014; 10:1–4.

41.

Rich

, Wood

, Majidi

. Untethered soft robotics. Nat Electron, 2018; 1:102–112.

42.

Cacucciolo

, Shintake

, Kuwajima

, et al. Stretchable pumps for soft machines. Nature, 2019; 572:516–519.

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.

18.56 MB

3.01 MB

6.11 MB

3.89 MB

7.38 MB

3.93 MB

5.01 MB

1.66 MB

4.59 MB

16.08 MB

4.54 MB

0.00 MB

Soft Rod-Climbing Robot Inspired by Winding Locomotion of Snake

Abstract

Get full access to this article

References

Supplementary Material