Abstract
Dielectric elastomer (DE) is a kind of smart soft material that has many advantages such as large deformation, fast response, lightweight and easy synthesis. These features make dielectric elastomer a suitable material for actuators. This article focuses on the shape control of a cantilever beam by using dielectric elastomer actuators. The shape control equation in finite element formulation of the cantilever beam partially covered with dielectric elastomer actuators is derived based on the constitutive equation of dielectric elastomer material by using Hamilton principle. The actuating forces produced by dielectric elastomer actuators depend on the number of layers, the position and the actuation voltage of dielectric elastomer actuators. First, effects of these factors on the shape control accuracy when one pair or multiple pairs of actuators are employed are simulated, respectively. The simulation results demonstrate that increasing the number of actuators or the number of layers can improve the control effect and reduce the actuation voltages effectively. Second, to achieve the optimal shape control effect, the position of the actuators and the drive voltages are all determined using a genetic algorithm. The robustness of the genetic algorithm is analyzed. Moreover, the implications of using one pair and multiple pairs of actuators to drive the cantilever beam to the expected shape are investigated. The results demonstrate that a small number of actuators with optimal placement and optimal voltage values can achieve the shape control of the beam effectively. Finally, a preliminary experimental verification of the control effect is carried out, which shows the correctness of the theoretical method.
Highlights
Due to the increasing high structural requirements, the modeling and control of flexible structures have received considerable interest among the research community
In order to guarantee the normal operation of structures, the deformed structures commonly need to be restored to their original design shapes
This paper focuses on the shape control of structure using Dielectric elastomer (DE) material as actuator and is intended to provide the methodology of analyzing the coupling deformation between DE material and structure
Summary
Some researchers have developed user-defined material subroutines and embed them in commercial finite element software in order to extend the capability of analyzing electromechanical coupling characteristics of dielectric elastomer The main contents are organized as follows: firstly, the basic principle of DE material is introduced; secondly, the theoretical model and constitutive relation of DE thin film under external load and voltage are deduced; thirdly, the governing equation of the cantilever beam controlled by multiple pairs of DE actuators is established based on the constitutive relations of the elastic material and dielectric elastomer material, shear deformation beam theory and the Hamilton principle; the finite element formulations of shape control are presented.
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