Sage Journals: Discover world-class research

Abstract

Recent advances in soft robotics demonstrate the requirement of modular actuation to enable the rapid replacement of actuators for maintenance and functionality extension. There remain challenges to designing soft actuators capable of different motions with a consistent appearance for simplifying fabrication and modular connection. Origami structures reshaping along with their unique creases became a powerful tool to provide compact constraint layers for soft pneumatic actuators. Inspired by Waterbomb and Kresling origami, this article presents three types of vacuum-driven soft actuators with a cubic shape and different origami skins, featuring contraction, bending, and twisting-contraction combined motions, respectively. In addition, these modular actuators with diversified motion patterns can be directly fabricated by molding silicone shell and constraint layers together. Actuators with different geometrical parameters are characterized to optimize the structure and maximize output properties after establishing a theoretical model to predict the deformation. Owing to the shape consistency, our actuators can be further modularized to achieve modular actuation via mortise and tenon-based structures, promoting the possibility and efficiency of module connection for versatile tasks. Eventually, several types of modular soft robots are created to achieve fragile object manipulation and locomotion in various environments to show their potential applications.

Get full access to this article

View all access options for this article.

References

Wang

, Totaro

, Beccai

. Toward perceptive soft robots: Progress and challenges. Adv Sci, 2018; 5(9):1800541.

Majidi

. Soft-matter engineering for soft robotics. Adv Mater Technol, 2018; 4(2):1800477.

Aracri

, Giorgio-Serchi

, Suaria

, et al. Soft robots for ocean exploration and offshore operations: A perspective. Soft Robot, 2021; 8(6):625–639.

Zhang

, Zhu

, Lin

, et al. Fluid-driven artificial muscles: Bio-design, manufacturing, sensing, control, and applications. Bio Design Manuf, 2020; 4(1):123–145.

Jin

, Sun

, Li

, et al. Triboelectric nanogenerator sensors for soft robotics aiming at digital twin applications. Nat Commun, 2020; 11(1):5381.

, Wang

, Liu

, et al. Visual servoing pushing control of the soft robot with active pushing force regulation. Soft Robot, 2021; 9(4):690–704.

Liang

, Cheong

, Sun

, et al. Design, characterization, and implementation of a two-DOF fabric-based soft robotic arm. IEEE Robot Autom Lett, 2018; 3(3):2702–2709.

Perez-Guagnelli

, Nejus

, Yu

, et al. Axially and radially expandable modular helical soft actuator for robotic implantables. In: 2018 IEEE International Conference on Robotics and Automation (ICRA), Brisbane, QLD, Australia. IEEE; 2018; pp. 4297–4304.

, Vogt

, Rus

, et al. Fluid-driven origami-inspired artificial muscles. Proc Natl Acad Sci USA, 2017; 114(50):13132–13137.

10.

Schaffner

, Faber

, Pianegonda

, et al. 3D printing of robotic soft actuators with programmable bioinspired architectures. Nat Commun, 2018; 9(1):878.

11.

Manti

, Hassan

, Passetti

, et al. A bioinspired soft robotic gripper for adaptable and effective grasping. Soft Robot, 2015; 2(3):107–116.

12.

Renda

, Giorelli

, Member

, et al. Dynamic model of a multibending soft robot arm driven by cables. IEEE Trans Robot, 2014; 30(5):1109–1122.

13.

Sun

, Tighe

, Liu

, et al. Twisted-and-coiled actuators with free strokes enable soft robots with programmable motions. Soft Robot, 2021; 8(2):213–225.

14.

, Ma

, Zhang

, et al. Research on the mechanism of variable stiffness of the twisted and coiled polymer actuator during saturated contraction. Smart Mater Struct, 2020; 29(6):065014.

15.

, Chen

, Zhou

, et al. Self-powered soft robot in the Mariana Trench. Nature, 2021; 591(7848):66–71.

16.

Chu

, Hu

, Wang

, et al. Unipolar stroke, electroosmotic pump carbon nanotube yarn muscles. Science, 2021; 371(6528):494–498.

17.

Zou

, Feng

, Ding

, et al. Muscle-fiber array inspired, multiple-mode, pneumatic artificial muscles through planar design and one-step rolling fabrication. Natl Sci Rev, 2021; 8(10):nwab048.

18.

Luo

, Zou

, Gu

. Multimaterial pneumatic soft actuators and robots through a planar laser cutting and stacking approach. Adv Intell Syst, 2021; 3(10):2000257.

19.

Jin

, Li

, Wang

, et al. Origami-inspired soft actuators for stimulus perception and crawling robot applications. IEEE Trans Robot, 2022; 38(2):748–764.

20.

Huang

, Zhu

, Gu

. Kinematic modeling and characterization of soft parallel robots. IEEE Trans Robot, 2022; 38(6):3792–3806.

21.

Gong

, Fang

, Chen

, et al. A soft manipulator for efficient delicate grasping in shallow water: Modeling, control, and real-world experiments. Int J Rob Res, 2021; 40(1):449–469.

22.

Liu

, Duo

, Liu

, et al. Touchless interactive teaching of soft robots through flexible bimodal sensory interfaces. Nat Commun, 2022; 13(1):5030.

23.

Germann

, Maesani

, Pericet-Camara

, et al. Soft cells for programmable self-assembly of robotic modules. Soft Robot, 2014; 1(4):239–245.

24.

Zou

, Lin

, Ji

, et al. A reconfigurable omnidirectional soft robot based on caterpillar locomotion. Soft Robot, 2018; 5(2):164–174.

25.

Zhang

, Zhu

, Lin

, et al. Modular soft robotics: Modular units, connection mechanisms, and applications. Adv Intell Syst, 2020; 2(6):1900166.

26.

Subramaniam

, Jain

, Agarwal

, et al. Design and characterization of a hybrid soft gripper with active palm pose control. Int J Rob Res, 2020; 39(14):1668–1685.

27.

Jin

, Dong

, Xu

, et al. Soft and smart modular structures actuated by shape memory alloy (SMA) wires as tentacles of soft robots. Smart Mater Struct, 2016; 25(8):085026.

28.

Chen

, Zhao

, Zhang

, et al. C-Balls: A modular soft robot connected and driven via magnet forced. J Phys Conf Ser, 2019; 1207(1):012006.

29.

Kim

, Lee

, Ahn

, et al. Morphing origami block for lightweight reconfigurable system. IEEE Trans Robot, 2021; 37(2):494–505.

30.

Kwok

, Morin

, Mosadegh

, et al. Magnetic assembly of soft robots with hard components. Adv Funct Mater, 2014; 24(15):2180–2187.

31.

Jiao

, Zhang

, Ruan

, et al. Re-foldable origami-inspired bidirectional twisting of artificial muscles reproduces biological motion. Cell Reports Phys Sci, 2021; 2(5):100407.

32.

Jiao

, Zhang

, Wang

, et al. Advanced artificial muscle for flexible material-based reconfigurable soft robots. Adv Sci, 2019; 6(21):1901371.

33.

Lee

J-Y

, Eom

, Choi

W-Y

, et al. Soft LEGO: Bottom-up design platform for soft robotics. In: 2018 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). IEEE; 2018; pp. 7513–7520.

34.

Lee

, Kim

, Choi

, et al. Soft robotic blocks: Introducing SoBL, a fast-build modularized design block. IEEE Robot Autom Mag, 2016; 23(3):30–41.

35.

Robertson

, Paik

. New soft robots really suck: Vacuum-powered systems empower diverse capabilities. Sci Robot, 2017; 2(9):eaan6357.

36.

Lee

D-Y

, Kim

S-R

, Kim

J-S

, et al. Origami wheel transformer: A variable-diameter wheel drive robot using an origami structure. Soft Robot, 2017; 4(2):163–180.

37.

, Feng

, Chen

, et al. Folding of tubular waterbomb. Research, 2020; 2020:1735081.

38.

Kim

, Lee

, Jung

, et al. An origami-inspired, self-locking robotic arm that can be folded flat. Sci Robot, 2018; 3(16):eaar2915.

39.

, Stampfli

, Xu

, et al. A vacuum-driven origami “magic-ball” soft gripper. In: 2019 International Conference on Robotics and Automation (ICRA). IEEE; 2019; pp. 7401–7408.

40.

Lee

, Wang

, Zheng

. TWISTER hand: Underactuated robotic gripper inspired by origami twisted tower. IEEE Trans Robot, 2020; 36(2):488–500.

41.

Chen

, Shao

, Xie

, et al. Soft origami gripper with variable effective length. Adv Intell Syst, 2021; 3(10):2000251.

42.

Kim

, Byun

, Kim

, et al. Bioinspired dual-morphing stretchable origami. Sci Robot, 2019; 4(36):eaay3493.

43.

, Ze

, Dai

, et al. Stretchable origami robotic arm with omnidirectional bending and twisting. Proc Natl Acad Sci USA, 2021; 118(36):1–9.

44.

Novelino

, Ze

, Wu

, et al. Untethered control of functional origami microrobots with distributed actuation. Proc Natl Acad Sci USA, 2020; 117(39):24096–24101.

45.

Paez

, Agarwal

, Paik

. Design and analysis of a soft pneumatic actuator with origami shell reinforcement. Soft Robot, 2016; 3(3):109–119.

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.

0.04 MB

0.20 MB

0.19 MB

0.34 MB

0.10 MB

0.04 MB

0.10 MB

0.12 MB

0.50 MB

0.06 MB

7.37 MB

8.48 MB

7.51 MB

4.51 MB

12.87 MB

11.01 MB

7.09 MB

6.45 MB

6.69 MB

6.44 MB

0.00 MB

Modular Soft Robot with Origami Skin for Versatile Applications

Abstract

Get full access to this article

References

Supplementary Material