Sage Journals: Discover world-class research

Abstract

Conventional robots are typically actuated by hard actuators, while biological entities consist mostly of soft muscles. Being soft imparts a functionality of compliance, thereby greatly enhancing the range of actuation and the degrees of freedom. Here, we demonstrate a soft electromechanically-active polymer capable of an electrically-induced linear strain beyond 500% that is continuously tunable by voltage. Previous experiments on the same material have demonstrated that by harnessing and bypassing electromechanical instability, soft electroactive polymers may bi-stably switch between an actuated state and an uncharged state of about 323% linear strain. In this paper, we use theory to inspire the possibility of suppressing electromechanical instability using pre-stretch by applying a non-isotropic pre-stretch onto the membrane, so as to achieve an ultra-large actuation strain that is continuously tunable by voltage. This geometry that enables such a large magnitude of actuation is simple and highly amenable to integration in robotic systems. With an electrically-induced strain of at least two orders of magnitude larger than conventional actuators, we expect our demonstration to expand the range of application for soft actuators.

Get full access to this article

View all access options for this article.

References

Ashley

. Artificial muscles. Sci Am, 2003; 289:52–59.

Pelrine

, Kombluh

, Pei

, et al. High-speed electrically actuated elastomers with strain greater than 100%. Science, 2000; 287:836–839.

Brochu

, Pei

. Advances in dielectric elastomers for actuators and artificial muscles. Macromol Rapid Commun, 2010; 31:10–36.

Bar-Cohen

. Electroactive polymers as artificial muscles-reality and challenges. 19th AIAA Applied Aerodynamics Conference, Anaheim, CA, 2001, p. 1492.

Pelrine

, Kornbluh

, Joseph

. Electrostriction of polymer dielectrics with compliant electrodes as a means of actuation. Sens Actuators A Phys, 1998; 64:77–85.

Pei

, Pelrine

, Stanford

, et al. Electroelastomer rolls and their application for biomimetic walking robots. Synth Met, 2003; 135–136:129–131.

Galler

, Ditlbacher

, Steinberger

, et al. Electrically actuated elastomers for electro-optical modulators. Appl Phys B Lasers Optics, 2006; 85:7–10.

Chakraborti

, Toprakci

, Yang

, et al. A compact dielectric elastomer tubular actuator for refreshable Braille displays. Sens Actuators A Phys, 2012; 179:151–157.

O'Brien

, Gisby

, Anderson

. Stretch sensors for human body motion. Proceedings of SPIE 9056, San Diego, CA, 2014, p. 905618.

10.

Kaltseis

, Keplinger

, Koh

SJA

, et al. Natural rubber for sustainable high-power electrical energy generation. RSC Adv, 2014; 4:27905–27913.

11.

Kovacs

, Lochmatter

, Wissler

. An arm wrestling robot driven by dielectric elastomer actuators. Smart Mater Struct, 2007; 16:S306–S317.

12.

TVK

, Mathew

, Koh

SJA

. Stackable configurations of artificial muscle modules that is continuously-tunable by voltage. Proceedings of SPIE 10163, Portland, OR, 2017, p. 101632K.

13.

Henke

, Schlatter

, Anderson

. Soft dielectric elastomer oscillators driving bioinspired robots. Soft Robotics, 2017; 4:353–366.

14.

Pelrine

, Kornbluh

, Joseph

, et al. High-field deformation of elastomeric dielectrics for actuators. Mater Sci Eng C, 2000; 11:89–100.

15.

Pelrine

, Kornbluh

, Joseph

, et al. Electrostriction of polymer films for microactuators. Proceedings IEEE, Micro Electro Mechanical Systems, Nagoya, Japan, 1997.

16.

Koh

SJA

, Li

, Zhou

, et al. Mechanisms of large actuation strain in dielectric elastomers. J Polym Sci Part B Polym Phys, 2011; 49:504–515.

17.

Zhao

, Suo

. Method to analyze electromechanical stability of dielectric elastomers. Appl Phys Lett, 2007; 91:061921.

18.

Zhao

, Suo

. Theory of dielectric elastomers capable of giant deformation of actuation. Phys Rev Lett, 2010; 104:178302.

19.

Keplinger

, Li

, Baumgartner

, et al. Harnessing snap-through instability in soft dielectrics to achieve giant voltage-triggered deformation. Soft Matter, 2012; 8:285–288.

20.

Kollosche

, Zhu

, Suo

, et al. Complex interplay of nonlinear processes in dielectric elastomers. Phys Rev E, 2012; 85:051801.

21.

Kornbluh

, Pelrine

, Pei

, et al. Electroelastomers: applications of dielectric elastomer transducers for actuation, generation, and smart structures. Proc SPIE 4698, San Diego, CA, 2002.

22.

Huang

, Li

, Foo

, et al. Giant, voltage-actuated deformation of a dielectric elastomer under dead load. Appl Phys Lett, 2012; 100:041911.

23.

Wang

, Chen

, Bai

, et al. Actuating dielectric elastomers in pure shear deformation by elastomeric conductors. Appl Phys Lett, 2014; 104:064101.

24.

Pharr

, Sun

, Suo

. Rupture of a highly stretchable acrylic dielectric elastomer. J Appl Phys, 2012; 111:104114.

25.

Kofod

. The static actuation of dielectric elastomer actuators: how does pre-stretch improve actuation?. J Phys D: Appl Phys, 2008; 41:215405.

26.

Rivlin

, Thomas

. Rupture of rubber. I. Characteristic energy for tearing. J Polym Sci, 1953; 10:291–318.

27.

Treloar

LRG

. Stress-strain data for vulcanised rubber under various types of deformation. Trans Faraday Soc, 1944; 40:59–70.

28.

Arruda

, Boyce

. A three-dimensional constitutive model for the large stretch behavior of rubber elastic materials. J Mech Phys Solids, 1993; 41:389–412.

29.

Suo

. Theory of dielectric elastomers. Acta Mech Solida Sinica. 2010; 23:549–578.

30.

Gent

. A new constitutive relation for rubber. Rubber Chem Technol, 1996; 69:59–61.

31.

Koh

SJA

, Keplinger

, Kaltseis

, et al. High-performance electromechanical transduction using laterally-constrained dielectric elastomers Part I: actuation processes. J Mech Phys Sol, 2017; 105:81–94.

32.

, Huang

, Jordi

, et al. Dielectric elastomer actuators under equal-biaxial forces, uniaxial forces, and uniaxial constraint of stiff fibers. Soft Matter, 2012; 8:6167–6173.

33.

Kofod

, Sommer-Larsen

, Kornbluh

, et al. Actuation response of polyacrylate dielectric elastomers. J Intell Mater Syst Struct, 2003; 14:787–793.

34.

Kornbluh

, Pelrine

, Pei

, et al. Ultrahigh strain response of field-actuated elastomeric polymers. 3987. Proceedings of SPIE—The International Society for Optical Engineering, Newport Beach, CA, 2000, pp. 51–64.

35.

Huang

, Shian

, Diebold

, et al. The thickness and stretch dependence of the electrical breakdown strength of an acrylic dielectric elastomer. Appl Phys Lett, 2012; 101:122905.

36.

Tröls

, Kogler

, Baumgartner

, et al. Stretch dependence of the electrical breakdown strength and dielectric constant of dielectric elastomers. Smart Mater Struct, 2013; 22:104012.

37.

, Rosset

, Shea

. Soft tunable diffractive optics with multifunctional transparent electrodes enabling integrated actuation. Appl Phys Lett, 2016; 109:191901.

38.

Madsen

, Yu

, Skov

. Self-healing, high-permittivity silicone dielectric elastomer. ACS Macro Lett, 2016; 5:1196–1200.

39.

Rosset

, Shea

. Small, fast, and tough: shrinking down integrated elastomer transducers. Appl Phys Rev, 2016; 3:031105.

40.

Poikelispää

, Shakun

, Das

, et al. High actuation performance offered by simple diene rubbers. Polym Adv Technol, 2017; 28:130–136.

41.

Yin

, Yang

, Song

, et al. dielectric elastomer generator with improved energy density and conversion efficiency based on polyurethane composites. ACS Appl Mater Interf, 2017; 9:5237–5243.

42.

Koh

SJA

, Keplinger

, Li

, et al. Dielectric elastomer generators: how much energy can be converted?. IEEE/ASME Trans Mech, 2011; 16:33–41.

43.

, Chen

, Qiang

, et al. Effect of mechanical pre-stretch on the stabilization of dielectric elastomer actuation. J Phys D Appl Phys, 2011; 44:155301.

44.

Zhao

, Koh

SJA

, Suo

. Nonequilibrium thermodynamics of dielectric elastomers. Int J Appl Mech, 2011; 3:203–217.

45.

McKay

, Calius

, Anderson

. The dielectric constant of 3 M VHB: a parameter in dispute. Proc SPIE, 7287, 2009; 72870P.

46.

Zhao

, Hong

, Suo

. Electromechanical hysteresis and coexistent states in dielectric elastomers. Phys Rev B, 2007; 76:134113.

47.

Huang

, Suo

. Electromechanical phase transition in dielectric elastomers. Proc R Soc London Ser A, 2012; 468:1014–1040.

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.

15.07 MB

0.00 MB

Electrically-Induced Actuation of Acrylic-Based Dielectric Elastomers in Excess of 500% Strain

Abstract

Abstract

Get full access to this article

References

Supplementary Material