Ionic polymer-metal composite artificial muscles

Palmre V, Pugal D, Kim KJ, Leang KK, Asaka K, Aabloo A (2014) Nanothom electrodes for ionic polymer-metal composite artificial muscles. Sci Rep 4 6176... 

Chen Z, Shatara S, Tan X (2010) Modeling of biomimetic robotic fish propelled by an ionic polymer-metal composite caudd fin. lEEE/ASME Trans Mech 15(3) 448-459 Chen Z, Uma T, Bait-Smith H (2012) Bio-inspired robotic manta ray powered by ionic polymer-metal composite artificial muscles. Int J Smart Nano Mater 3(4) 296-308 Cheng J, Pedley T, Ahringham J (1998) A continuous dynamic beam model for swimming fish. Phil Trans R Soc B 353(1371) 981-997... 

Kim KJ, Shahinpoor M (2002) A novel method of manufacturing three-dimensional ionic polymer-metal composites (IPMCs) bomimetic sensors, actuators and artificial muscles. Polymer 43 797... 

Shahinpoor M, Kim KJ (2004) Ionic polymer-metal composites ID. modeling and simulation as biomimetic sensors, actuators, transducers and artificial muscles (review paper). Smart Mater Struct Int J 13(6) 1362-1388. doi 10.1088/0964-1726/13/6/009... 

Shahinpoor M, Bar-CohenY, Xue T, Harrison IS, Smith 1 (1999) Ionic polymer-metal composites as biomimetic sensors and actuators-artificial muscles. In Khan IM, Harrison JS (eds) Field responsive polymers. ACS Symp Series, Washington DC. doi 10.1021/bk-1999-0726.ch003... 

Throughout the chapters of this book we considered several types of electroactive materials in a view of using them as biomimetic artificial muscles. In particular, ionic polymer-metal composites, conjugated polymers, and dielectric elastomers were considered. 

Shahinpoor, M., Bar-Cohen, Y., Simpson, J. O. and Smith, J. (1998). Ionic polymer-metal composites (ipmcs) as biomimetic sensors, actuators and artificial muscles - a review. Smart Materials and Structures 7, 6, p. R15. 

Shahinpoor, M. and Kim, K. J. (2000). The effect of surface-electrode resistance on the performance of ionic polymer-metal composite (IPMC) artificial muscles, Smart Materials and Structures 9, pp. 543-551. 

Yamakita, M., Kamamichi, N., Kaneda, Y., et al. (2004) Development of an Artificial Muscle Linear Actuator Using Ionic Polymer-Metal Composites. Adv. Robotics, 18, 383-99. 

Therefore, based on the background technologies and their successes and failures in treating weak hearts, it is highly desirable to develop a soft heart compression device for patients with CHF problems. In this connection, ionic polymer-metal composites as soft biomimetic sensors, actuators and artificial muscles present a tremendous opportunity. 

Ionic Polymer-Metal Composites as Biomlmetic Sensors and Actuators-Artificial Muscles... 

Keywords Ionic Polymer-Metal Composite Sensor, Soft Actuator, Artificial Muscles, Biomimetic Sensor, Vibrations, Resonance. 

Rajagopalan M, Jeon JH, Oh IK (2010) Electric-stimuli-responsive bending actuator based on sulfonated polyetherimide. Sens Actuators B 151 198-204 Shahinpoor M (1992) Conceptual design, kinematics and dynamics of swimming robotic stmctures using ionic polymeric gel muscles. Smart Mater Stmct 1 91-94 Shahinpoor M, Kim KJ (2000) The effect of surface-electrode resistance on the performance of ionic polymer-metal composite (IPMC) artificial muscles. Smart Mater Stmct 9 543 551 Shahinpoor M, Kim KJ (2001) Ionic polymer-metal composites - I. Fundamentals. Smart Mater Struct 10 819-833... 

Fig. 7 Concept of integrated linear actuators (Reproduced from Development of an artificial muscle linear actuator using ionic polymer-metal composites. Yamakita M, Kamamichi N, Kaneda Y, Asaka K, Luo ZW, Advanced Robotics, 2004, Taylor Francis Ltd, reprinted by permission of the publisher Taylor Francis Ltd, www.tandfonline.com)...

Sareh S, Rossiter J, Conn A, Drescher K, Goldstein RE (2012) Swimming like algae biomimetic soft artificial cilia. J R Soc Interface 10 20120666 Shahinpoor M, Bar-Cohen Y, Simpson J, Smith J (1998) Ionic polymer-metal composites (IPMCs) as biomimetic sensors, actuators and artificial muscles - A review. Smart Mater Struct 7 R15-R30... 

Mojarrad have been experimenting with various chemically active as well as electrically active ionic polymers and their metal composites as artificial muscle actuators. 

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