Sage Journals: Discover world-class research

Abstract

Soft actuators that operate with overpressure have been successfully implemented as soft robotic grippers. Naturally, as these pneumatic devices are prone to cuts, self-healing properties are attractive. Here, we prepared a gripper that operates based on the liquid-gas phase transition of ethanol within its hollow structure. The gripping surface of the device is coated with a self-healing polymer that heals with heat. This gripper also includes a stainless steel wire along the device that heats the entire structure through resistive heating. This design results in a soft robotic gripper that actuates and heals in parallel driven by the same practical stimulus, that is, electricity. Compared to other self-healing soft grippers, this approach has the advantage of being simple and having autonomous self-healing. However, there remain fundamental drawbacks that limit its implementation. The current work critically assesses this overpressure approach and concludes with a broad perspective regarding self-healing soft robotic grippers.

Get full access to this article

View all access options for this article.

References

Whitesides

GM.

Soft robotics. Angew Chemie, 2018; 57(16):4258–4273.

El-atab

, Mishra

, Al-modaf

, et al. Soft actuators for soft robotic applications: A review. Adv Intell Syst, 2020; 2(10):2000128.

Terryn

, Langenbach

, Roels

, et al. A review on self-healing polymers for soft robotics. Mater Today, 2021; 47:187–205.

Tolley

, Shepherd

, Mosadegh

, et al. A resilient, untethered soft robot. Soft Robot, 2014; 1(3):213–223.

Terryn

, Brancart

, Lefeber

, et al. Self-healing soft pneumatic robots. Sci Robot, 2017; 2(9):1–12.

Liu

, Zhao

, Geng

, et al. Soft humanoid hands with large grasping force aneabled by flexible hybrid pneumatic actuators. Soft Robot, 2020; 8(2):175–185.

Mosadegh

, Polygerinos

, Keplinger

, et al. Pneumatic networks for soft robotics that actuate rapidly. Adv Funct Mater, 2014; 24:2163–2170.

Terryn

, Roels

, Brancart

, et al. Self-healing and high interfacial strength in multi-material soft pneumatic robots via reversible Diels–Alder bonds. Actuators, 2020; 9(34):1–16.

Martinez

, Branch

, Fish

, et al. Robotic tentacles with three-dimensional mobility based on flexible elastomers. Adv Mater, 2012; 25(2):205–212.

10.

Galloway

, Becker

, Phillips

, et al. Soft robotic grippers for biological sampling on Deeo Reefs. Soft Robot, 2016; 3(1):23–33.

11.

Shen

The soft touch. Nature, 2016; 530:24–26.

12.

Drotman

, Jadhav

, Sharp

, et al. Electronics-free pneumatic circuits for controlling soft-legged robots. Sci Robot, 2021; 6(51):1–12.

13.

Miron

, Plante

J-S

. Design principles for improved fatigue life of high-strain pneumatic artificial muscles. Soft Robot, 2016; 3(4):177–185.

14.

Rich

, Wood

, Majidi

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

15.

Chellattoan

, Yudhanto

, Lubineau

. Low-voltage-driven large-amplitude soft actuators based on phase transition. Soft Robot, 2020; 7(6):688–699.

16.

Kang

, An

, Yarin

, et al. Programmable soft robotics based on nano-textured thermo-responsive actuators. R Soc Chem, 2019; 11:2065–2070.

17.

Miriyev

, Stack

, Lipson

. Soft material for soft actuators. Nat Commun, 2017; 8(1):1–8.

18.

Amend

, Cheng

, Fakhouri

. Soft robotics commercialization: Jamming grippers from research to product. Soft Robot, 2016; 3(4):213–222.

19.

, Xin

, Du

, et al. Additive manufacturing of self-healing elastomers. NPG Asia Mater, 2019; 11(7):1–11.

20.

Fan

, Rong

, Zhang

, et al. Repeated intrinsic self-healing of wider cracks in polymer via dynamic reversible covalent bonding molecularly combined with a two-way shape memory effect. ACS Appl Mater Interfaces, 2018; 10:38538–38546.

21.

Orozco

, Li

, Ezekiel

, et al. Diels–Alder-based thermo-reversibly crosslinked polymers: Interplay of crosslinking density, network mobility, kinetics and stereoisomerism. Eur Polym J, 2020; 135:109882.

22.

Hornat

, Urban

. Shape memory effects in self-healing polymers. Prog Polym Sci, 2020; 102:101208.

23.

Orozco

, Kaveh

, Santosa

, et al. Electroactive self-healing shape memory polymer composites based on Diels–Alder chemistry. ACS Appl Polymer Mater, 2021; 3(12):6147–6156.

24.

Orozco

, Salvatore

, Sakulmankongsuk

, et al. Electroactive performance and cost evaluation of carbon nanotubes and carbon black as conductive fillers in self-healing shape memory polymers and other composites. Polymers, 2022; 260:125365.

25.

Drent

, Keijsper

Polyketone Polymer Preparation with Tetra Alkyl Bis Phosphine Ligand and Hydrogen, USA Patent; 1993.

26.

Vaicekauskaite

, Mazurek

, Vudayagiri

, et al. Silicone elastomer map: Design the ideal elastomer. In: Proceedings of SPIE 2019; pp. 1–9.

27.

Zhang

, Broekhuis

, Picchioni

. Thermally self-healing polymeric materials: The next step to recycling thermoset polymers?. Macromolecules, 2009; 42:1906–1912.

28.

Toncelli

, De Reus

, Picchioni

, et al. Properties of reversible Diels–Alder Furan/Maleimide polymer networks as function of crosslink density. Macromol Chem Phys, 2012; 213:157–165.

29.

Araya-Hermosilla

, Lima

GMR

, Raffa

, et al. Intrinsic self-healing thermoset through covalent and hydrogen bonding interactions. Eur Polym J, 2016; 81:186–197.

30.

Orozco

, Niyazov

, Garnier

, et al. Maleimide self-reaction in Furan/Maleimide-based reversibly crosslinked polyketones: Processing limitation or potential advantage?. Molecules, 2021; 26(8):2230.

31.

Blume

, Schwering

PJF

, Mulder

, et al. Vapour sorption and permeation properties of poly (dimethylsiloxane) films. J Memb Sci, 1991; 61:85–97.

32.

Gandini

The Furan/Maleimide Diels–Alder reaction: A versatile click-unclick tool in macromolecular synthesis. Prog Polym Sci, 2013; 38(1):1–29.

33.

Ren

, Chen

, Li

, et al. High-efficiency dual-responsive shape memory assisted self-healing of carbon nanotubes enhanced polycaprolactone/thermoplastic polyurethane composites. Colloids Surfaces A Physicochem Eng Asp, 2019; 580:123731.

34.

Ren

, Chen

, Yang

, et al. Fast and Efficient Electric-Triggered Self-Healing Shape Memory of CNTs@rGO Enhanced PCLPLA Copolymer. Macromol Chem Phys, 2019; 220(21):2–9.

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.

19.65 MB

0.00 MB

Electroactive Thermo-Pneumatic Soft Actuator with Self-Healing Features: A Critical Evaluation

Abstract

Get full access to this article

References

Supplementary Material