Optimal location of piezoelectric actuators for active vibration control of thin axially functionally graded beams

Bruant, Isabelle; Proslier, L.

doi:10.1007/s10999-015-9297-y

Cited by 25 publications

(6 citation statements)

References 58 publications

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“…Nevertheless, spillover effect due to the truncation of the modal basis must be considered. One solution is to optimize the location of sensors and actuators by taking into account the first residual modes into the optimization process [24].…”

Section: Control Law and Observermentioning

confidence: 99%

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A numerical efficiency study on the active vibration control for a FGPM beam

Maruani

Bruant

Pablo

et al. 2017

Composite Structures

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Section: Control Law and Observermentioning

confidence: 99%

“…Regarding the active vibration control using functionally graded material, we can find in literature papers dealing with active vibration control of FGM equipped with piezoelectric patches [14][15][16][17][18][19][20][21][22][23][24].…”

Section: Introductionmentioning

confidence: 99%

A numerical efficiency study on the active vibration control for a FGPM beam

Maruani

Bruant

Pablo

et al. 2017

Composite Structures

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“…Wang et al [ 19 ] investigated the optimal configuration of piezocomposite actuators for bending and twisting vibration control of plate structures. Bruant and Proslier [ 20 ] employed piezoelectric actuators for active vibration control of thin, axial, functionally graded beams. Kuriakose and Sreehari [ 21 ] experimentally demonstrated that piezoelectric patches bonded on an airplane wing panel can actually sense the amount of vibration and suppress it using an active vibration control system.…”

Section: Introductionmentioning

confidence: 99%

Vibration Excitation and Suppression of a Composite Laminate Plate Using Piezoelectric Actuators

Her

Chen

2022

Materials

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Piezoelectric (PZT) actuators bonded on a structure can be used to generate deformation and excite vibration for the shape control and vibration suppression, respectively. This article proposes a theoretical model for predicting vibrational response of a composite laminate plate with PZT actuators. The bending moment induced by the PZT actuator was obtained and applied on the composite laminate plate. Utilizing composite mechanics and plate theory, an analytical solution of the vibrational response of a composite laminate plate excited by the PZT actuator with oscillating voltage was derived. Furthermore, the finite element analysis using ANSYS software (2019 version) was carried out to compare with the proposed model with a good agreement. A parametric study was performed to investigate the influences of PZT location and frequency on the vibration. Numerical results illustrate that mode can be selectively excited provided the PZT actuator is placed in an appropriate location. Moreover, the proposed model was employed to predict the effectiveness of vibration suppression by distributed PZT actuators. The novelty of this work is that a complicated coupling problem between the composite plate and bonded PZT actuator is resolved into two simple problems, leading to a simple analytical solution for the vibrational response of a composite plate induced by PZT actuators. The proposed model has been successfully demonstrated its applications on the vibration excitation and suppression of a composite laminate plate.

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“…For the purposes of flexible structures testing and control, it is useful to investigate the optimal configuration of the actuators and to evaluate their impact on the control performance. Extensive research on the optimal configuration of piezoelectric actuators for vibration control have been carried out (Biglar et al, 2014; Bruant et al, 2010; Bruant and Proslier, 2016; Crawley and De Luis, 1987; Han and Lee, 1999; Leleu et al, 2001; Liu et al, 2003; Qiu et al, 2007; Schulz et al, 2013; Wang and Wang, 2000). The actuators could also be optimized to enhance the shape control performance of smart structures (Gohari et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Optimal unimorph and bimorph configurations of piezocomposite actuators for bending and twisting vibration control of plate structures

Wang

Zhou

et al. 2017

Journal of Intelligent Material Systems and Structures

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Optimal configuration of anisotropic piezocomposite actuators is investigated for vibration control of flexible structures. Actuation effects of the actuators in unimorph and antisymmetric angle-ply bimorph configurations are analyzed. Dynamic equations of the piezo-actuated plate are established using finite element method. The locations and lead zirconate titanate fiber orientations of actuators are optimized simultaneously to improve vibration control performance of a plate. The optimization criterion is presented based on controllability Gramian matrix of the system. The properties of macro-fiber composite are used in the simulations of the actuators. The optimal unimorph and bimorph configurations of actuators are presented for three cases: bending control, twisting control, and coupled bending–twisting control. The results indicate that both optimal locations and fiber orientations are different for bending control and twisting control. A trade-off between control authority for bending and torsional modes can be found in coupled bending–twisting control. The actuators should be placed in the regions of high average strain of the interested modes with appropriate fiber orientations. Special piezocomposite actuators with optimal fiber orientations can be used to achieve improved coupled bending–twisting vibration control performance.

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Optimal location of piezoelectric actuators for active vibration control of thin axially functionally graded beams

Cited by 25 publications

References 58 publications

A numerical efficiency study on the active vibration control for a FGPM beam

A numerical efficiency study on the active vibration control for a FGPM beam

Vibration Excitation and Suppression of a Composite Laminate Plate Using Piezoelectric Actuators

Optimal unimorph and bimorph configurations of piezocomposite actuators for bending and twisting vibration control of plate structures

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