An Integrated Design and Fabrication Strategy for Planar Soft Dielectric Elastomer Actuators

Dielectric elastomers (DEs) are promising soft actuators for use in soft material robots, due to their considerable voltage-induced strain. The actuator's behavior is highly nonlinear due to the complex interplay between the DE, the support structure, and the input electric field, making it a b...

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Bibliographic Details
Published inIEEE/ASME transactions on mechatronics Vol. 26; no. 5; pp. 2629 - 2640
Main Authors Chen, Feifei, Liu, Kun, Pan, Qi, Chen, Shitong, Zhu, Xiangyang
Format Journal Article
LanguageEnglish
Published New York IEEE 01.10.2021
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
3-D printing
Actuation
Actuators
Dielectric elastomer actuators
Dielectrics
Dimensionless analysis
Electric fields
Electric potential
Electrodes
Finite element method
Flux density
integrated design
Locomotion
locomotion in confined space
Mechatronics
Optimization
Polyurethane resins
Robot dynamics
Soft robotics
soft robots
Strain
Stress
Tensors
Two dimensional displays
Urethane thermoplastic elastomers
Voltage
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Summary:Dielectric elastomers (DEs) are promising soft actuators for use in soft material robots, due to their considerable voltage-induced strain. The actuator's behavior is highly nonlinear due to the complex interplay between the DE, the support structure, and the input electric field, making it a big challenge to automatically design dielectric elastomer actuators (DEAs). Here, in this article, we present an integrated design strategy for planar DEAs, aiming to realize their full potential. To endow the actuator module with the maximal actuation strain, we carry out dimensionless analysis to identify the key design variables, develop a fast finite element analysis model, and thoroughly investigate how the geometric structuring and the material prestretch tailor the voltage-induced deformation. We also provide a fabrication strategy by patterning the compliant electrodes on the DE membrane and then directly printing the support structure made of thermoplastic polyurethane. The experiments show that the optimized actuator obtains a remarkable nominal strain up to 38.6%. We also characterize the dynamic performance of the optimized actuator, evaluate its energy density and power density, and develop a soft locomotion robot that can crawl through a confined tunnel, at a fast moving speed up to 0.17 body length/s.
ISSN:1083-4435
1941-014X
DOI:10.1109/TMECH.2020.3043883