Advanced Plasticized Electroactive Polymers Actuators for Active Optical Applications: Live Mirror

Thetpraphi, Kritsadi; Chaipo, Suphita; Kanlayakan, Waroot; Cottinet, Pierre‐Jean; Le, Minh‐Quyen; Petit, Lionel; Audigier, David; Kuhn, J. R.; Moretto, Gil; Capsal, Jean‐Fabien

doi:10.1002/adem.201901540

Cited by 8 publications

(2 citation statements)

References 42 publications

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“…Furthermore, the improved E m of our actuator was similar to or even higher than that of EAP actuators based on terpolymer that is well-known to have intrinsically high E m . [55,56] Generally EAP actuators have high E m require operating voltage lareger than 10 V. However, we found that the i-SPIDER(60/58) actuator could achieve high E m of 687 J/m 3 only at 10 mV, which confirms its high energy conversion characteristics, their common operating condition (more than 10 3 J/m 3 @ over 10 V/μm), highly indicating that the capability to utilize the electrical energy as mechanical energy is more efficient.…”

Section: I-spider Actuator Performancementioning

confidence: 99%

Ions‐Silica Percolated Ionic Dielectric Elastomer Actuator for Soft Robots

Choi,

Kim,

Kim

et al. 2023

Advanced Science

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Soft robotics systems are currently under development using ionic electroactive polymers (i‐EAP) as soft actuators for the human‐machine interface. However, this endeavor has been impeded by the dilemma of reconciling the competing demands of force and strain in i‐EAP actuators. Here, the authors present a novel design called “ions‐silica percolated ionic dielectric elastomer (i‐SPIDER)”, which exhibits ionic liquid‐confined silica microstructures that effectively resolve the chronic issue of conventional i‐EAP actuators. The i‐SPIDER actuator demonstrates remarkable electromechanical conversion capacity at low voltage, thanks to improved ion accumulation facilitated by interpreting electrode polarization at the electrolyte‐electrode interface. This approach concurrently enhances both strain (by approximately 1.52%) and force (by roughly 1.06 mN) even at low Young's modulus (merely 5.9 MPa). Additionally, by demonstrating arachnid‐inspired soft robots endowed with user‐desired tasks through control of various form factors, the development of soft robots using the i‐SPIDER that can concomitantly enhance strain and force holds promise as a compelling avenue for ushering in the next generation of miniaturized, low‐powered soft robotics.

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Section: I-spider Actuator Performancementioning

confidence: 99%

Ions‐Silica Percolated Ionic Dielectric Elastomer Actuator for Soft Robots

Choi,

Kim,

Kim

et al. 2023

Advanced Science

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“…Piezoelectric actuators use the inverse effect of piezoelectric materials to convert electrical energy into mechanical energy to track a desired trajectory. They have the advantages of small size, high accuracy, large driving force, fast response, low noise, and so forth, and have been widely used in scanning probe microscopes, 1 active optical components, 2 biomedical engineering 3 and other precision displacement positioning systems.…”

Section: Introductionmentioning

confidence: 99%

Third‐order integral sliding mode control of piezoelectric actuators based on rate‐amplitude‐dependent Prandtl‐Ishlinskii model

et al. 2023

Intl J Robust & Nonlinear

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Aiming at trajectory tracking control of piezoelectric actuators (PEAs), this article proposes a third-order integral sliding mode control (3-ISMC) based on rate-amplitude-dependent Prandtl-Ishlinskii (PI) inverse model feedforward (3-RAPI) scheme, which can achieve finite time convergence and avoid singular problems, while ensuring the continuity of the control signal. In this control scheme, a rate-amplitude-dependent PI (RAPI) model is proposed to describe the hysteresis characteristics of PEA, and the RAPI hysteresis inverse model is used to realize the feedforward control. The simulation results verify the improvement of the modeling accuracy of the RAPI model compared with the traditional PI model. In order to reduce the influence of modeling error and improve the robustness of the system, a 3-ISMC scheme based on integral non-singular fast terminal sliding mode surface is proposed. Simulation and experimental results demonstrate that the tracking performance of 3-ISMC is improved compared with the existing third-order integral terminal sliding model control (3-ITSMC). Finally, the composite control algorithm is realized by combining the RAPI hysteresis inverse model feedforward with the 3-ISMC algorithm. The experimental results further show that the control algorithm can track the input signal in a wide range of rate and amplitude.

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