Investigating the behavior of smart thin beams with piezoelectric actuators under dynamic loads

Investigating the behavior of smart thin beams with piezoelectric actuators under dynamic loads

In this paper, the constitutive equation of motion for an Euler–Bernoulli beam in which a number of piezoelectric patches are bonded to the bottom and top surfaces of it, and arbitrary boundary conditions, is derived by employing Hamilton's principle. Assuming a number of linear springs with hi...

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Bibliographic Details
Published in:Mechanical systems and signal processing Vol. 45; no. 2; pp. 513 - 530
Main Author: Nikkhoo, Ali
Format: Journal Article
Language:English
Published: Elsevier Ltd 04-04-2014
Subjects:
Active control
Beams (structural)
Boundary conditions
Constitutive relationships
Control systems
Differential equations
Dynamic loads
Loads (forces)
Mathematical analysis
Moving mass
Piezoelectric materials
Rectangular impulse
Smart structures
Thin beams
Smart structures
Moving mass
Thin beams
Rectangular impulse
Piezoelectric materials
Active control
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Summary:In this paper, the constitutive equation of motion for an Euler–Bernoulli beam in which a number of piezoelectric patches are bonded to the bottom and top surfaces of it, and arbitrary boundary conditions, is derived by employing Hamilton's principle. Assuming a number of linear springs with high stiffness as intermediate supports, the motion equation of a multi-span smart beam could be found. Classical linear optimal control algorithm with displacement–velocity and velocity–acceleration feedbacks is used. Utilizing eigenfunction expansion method, the equation of motion is decoupled into a number of ordinary differential equations. All the numerical examples are presented for the simple boundary conditions. The applied dynamic excitations are a rectangular impulse, moving load and the moving mass. Parametric studies on the capability of the control system in vibration suppression of the beams under these dynamic loads are achieved. The obtained results reveal the efficiency of the proposed control system in reducing the response of the beam structures to the required levels. •Application of the piezoceramic actuators in vibration suppression of thin beams.•Performance of different control feedbacks in the employed control algorithm.•Vibration suppression of the structural system under severe moving mass loadings.•Exploring the control system effect on the possibility of the moving mass separation.
Bibliography:ObjectType-Article-1
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content type line 23
ISSN:0888-3270
1096-1216
DOI:10.1016/j.ymssp.2013.11.003