Sage Journals: Discover world-class research

Abstract

Ionic polymer metal composites with a flexible large deformation have been used as biomimetic actuators and sensors in various fields. This work mainly focuses on the validation of the proposed theoretical prediction for various ionic polymer metal composite applications, such as a field needing a large resultant force, large tip deflection, or high response frequency. Such properties can be controlled by the number of layers and the thickness ratio of a multilayered ionic polymer metal composite actuator. Thus, we considered major design factors such as the number of layers and the thickness ratio in analysis of the proposed theoretical model and performed experiments to verify the static and dynamic electromechanical responses of multilayered (multimorph) ionic polymer metal composite structures acting as actuators. The relation between the polymer (Nafion) and electrode or substrate is represented by β. From this theoretical analysis, three properties were analyzed and predicted based on the Euler–Bernoulli beam theory, considering the dynamics of the ionic polymer metal composite, electrode, and bonding layers (substrate layers). The predicted results of a symmetric ionic polymer metal composite multimorph were compared with results of finite element analysis and experiments using ionic polymer metal composite multimorphs with one to five layers. Finally, this work examined how the number of layers and thickness affect the dynamic properties. This can contribute to predicting and optimally designing a multilayered ionic polymer metal composite actuator for satisfying a specific requirement.

Keywords

Smart material ionic polymer actuator multilayered

Get full access to this article

View all access options for this article.

References

Asada

Oguro

Nishimura

et al . (1995) Bending of polyelectrolyte membrane platinum composites by electric stimuli. I: response characteristics to various waveformsPolymer 27: 436–440.

Balakrisnan

Nacev

Smela

(2015) Design of bending multilayer electroactive polymer actuators. Smart Materials and Structures 24(4): 045032.

Bennett

Leo

(2004) Ionic liquids as stable solvents for ionic polymer transducers. Sensors and Actuators A: Physical 115(1): 79–90.

Bhandari

Lee

Ahn

(2012) A review on IPMC material as actuators and sensors: fabrications, characteristics and applications. International Journal of Precision Engineering and Manufacturing 31(1): 141–163.

Cha

Verotti

Walcott

et al . (2013) Energy harvesting from the tail beating of a carangiform swimmer using ionic polymer-metal composites. Bioinspiration and Biomimetics 8(3): 036003.

Choi

Yang

Lee

(2009) Theoretical modeling and experimental verification for a multilayered IPMC actuator. In: Proceedings of the Korean society of mechanical engineers fall annual meeting, Pyeongchang, Korea, 4–6 November 2009, pp. 2763–2768.

Cilingir

Papila

(2010) Equivalent electromechanical coefficient for IPMC actuator design based on equivalent bimorph beam theory. Experimental Mechanics 50: 1157–1168.

Gonzales

Lumia

(2015) An IPMC microgripper with integrated actuator and sensing for constant finger-tip displacement. Smart Materials and Structures 24(5): 055011.

Hummers

Offeman

(1958) Preparation of graphitic oxide. Journal of the American Chemical Society 80(6): 1339.

10.

Pugal

et al . (2013) Recent advances in ionic polymer metal composite actuators and their modeling and applications. Progress in Polymer Science 38(7): 1037–1066.

11.

Kim

Lee

et al . (2006) Performance improvement of an ionic polymer-metal composite actuator by parylene thin film coating. Smart Materials and Structures 15(6): 1540.

12.

Kovtyukhova

Gorchinskiy

(1999) Layer-by-layer assembly of ultrathin composite films from micron-sized graphite oxide sheets and polycations. Chemistry of Materials 11(3): 771–778.

13.

Lee

Yang

(2005) Theoretical modeling, experiments and optimization of piezoelectric multimorph. Smart Materials and Structures 14(6): 1343.

14.

Muller

Gilje

et al . (2008) Processable aqueous dispersions of graphene nanosheets. Nature Nanotechnology 3(2): 101–105.

15.

McDaid

Haemmerle

et al . (2010) A conclusive scalable model for the complete actuation response for IPMC transducers. Smart Materials and Structures 19(7): 075011.

16.

Millet

Pineri

Durand

(1989) New solid polymer electrolyte composites for water electrolysis. Journal of Applied Electrochemistry 19: 162.

17.

Nguyen

Goo

Nguyen

et al . (2008) Design, fabrication. and experimental characterization of a flap valve IPMC micropump with a flexibly supported diaphragmSensors and Actuators A: Physical 141(2): 640–648.

18.

Oguro

Asaka

Takenaka

(1993a) Actuator element. US Patent 5 268082.

19.

Oguro

Asaka

Takenaka

(1993b) Polymer film actuator driven by a low voltage. In: Proceedings of the 4th international symposium on micro machine and human science, Nagoya, Japan, 13–15 October 1993, pp. 39–40.

20.

Oguro

Fujiwara

Asaka

et al . (1999, May). Polymer electrolyte actuator with gold electrodes. In: Proceedings of the SPIE, smart structures and materials: electroactive polymer actuators and devices, Vol. 3669, pp. 64–71.

21.

O’Halloran

O’Malley

McHugh

(1994) A review on dielectric elastomer actuators, technology, applications and challenges. Journal of Applied Physics 104(7): 9.

22.

Porfiri

(2008) Charge dynamics in ionic polymer metal composites. Journal of Applied Physics 104(10): 104915.

23.

Pugal

Kim

Punning

et al . (2008) A self-oscillating ionic polymer-metal composite bending actuator. Journal of Applied Physics 103(8): 084908.

24.

Ruiz

Mead

Palmre

et al . (2014) A cylindrical ionic polymer-metal composite-based robotic catheter platform: modeling, design and control. Smart Materials and Structures 24(1): 015007.

25.

Safari

Najii

Baker

et al . (2015) The enhancement effect of lithium ions on actuation performance of ionic liquid-based soft actuators. Polymer 76: 140–149.

26.

Shahinpoor

(1992) Conceptual design, kinematics and dynamics of swimming robotic structures using ionic polymeric gel muscles. Smart Materials and Structures 1: 91.

27.

Shahinpoor

Adolf

Witkowski

(1993) Electrically controlled polymeric gel actuators. US Patent 5 250167.

28.

Shahinpoor

Kim

(2001a) A novel physically-loaded and interlocked electrode developed for ionic polymer metal composites (IPMCs). Sensors and Actuators A: Physical 96: 125–132.

29.

Shahinpoor

Kim

(2001b) Ionic polymer-metal composites: I. Fundamentals. Smart Materials and Structures 10(4): 819.

30.

Shahinpoor

Kim

(2001c) Ionic polymer-metal composites: III. Modeling and simulation as biomimetic sensors, actuators, transducers, and artificial muscles. Smart Materials and Structures 13(6): 1362.

31.

Shahinpoor

Kim

(2005) Ionic polymer metal composites. IV: industrial and medical applications. Smart Materials and Structures 14: 197–214.

32.

Shahinpoor

Mojarrad

(2000) Soft actuators and artificial muscles. US Patent 6 109852.

33.

Shahinpoor

Bar Cohen

Xue

et al . (1999) Ionic polymer-metal composites as biomimetic sensors and actuators-artificial muscles. Smart Materials and Structures 13: 1362–1388.

34.

Tadmor

Kosa

(2003) Electromechanical coupling correction for piezoelectric layered beams. Journal of Microelectromechanical Systems 12(6): 899–906.

35.

Takenaka

Torikai

Kawami

et al . (1982) Solid polymer electrolyte water electrolysis. International Journal of Hydrogen Energy 7: 397.

36.

Wang

Sato

et al . (2009) Bioinspired design of tactile sensors based on Flemion. Journal of Applied Physics 105(8): 083515.

37.

Yang

Choi

et al . (2012) Carbon nanotube–graphene composite for ionic polymer actuators. Smart Materials and Structures 21(5): 055012.

38.

Yeom

(2009) A biomimetic jellyfish robot based on ionic polymer metal composite actuators. Smart Materials and Structures 18(8): 085002.

Theoretical analysis and design for a multilayered ionic polymer metal composite actuator

Abstract

Keywords

Get full access to this article

References