Nonlocal strain gradient theory for the magneto-electro-elastic vibration response of a porous FG-core sandwich nanoplate with piezomagnetic face sheets resting on an elastic foundation

Arefi, Mohammad; Kiani, Mohammad Ali; Zamani, MH

doi:10.1177/1099636218795378

“…Considering the boundary condition of the top and bottom sides of MEE layers, one can blend the linear and cosine variations to write the electric potential and magnetic potential in the form 48 …”

Section: Preliminary Formulationsmentioning

confidence: 99%

Sound transmission loss of double-walled sandwich cross-ply layered magneto-electro-elastic plates under thermal environment

Refahati

¹

,

Jearsiripongkul

²

,

Thongchom

³

et al. 2022

Sci Rep

15

0

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This study offers a comprehensive investigation into the parameters affecting the sound transmission characteristics of a double-walled sandwich magneto-electro-elastic cross-ply layered plate resting on viscoelastic medium in thermal environment. To this end, the walls of this sandwich structure are modeled based on the assumptions of the first-order shear deformation theory. The governing equations are derived via a coupled set of equations targeting vibration and acoustic aspects of the problem after the application of Hamilton’s principle. The obtained equations are then solved by the implementation of double Fourier series and the second velocity potential, giving an accurate estimation of sound transmission loss under initial magnetic and electric potentials, variations of temperature, ply angle, acoustic cavity depth, incident angle of sound waves, and viscoelastic parameters.

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“…Considering the boundary condition of the top and bottom sides of MEE layers, one can blend the linear and cosine variations to write the electric potential and magnetic potential in the form [47]…”

Section: Constitutive Relationsmentioning

confidence: 99%

Sound transmission loss of double-walled sandwich cross-ply layered magneto-electro- elastic plates under thermal environment

Refahati

¹

,

Jearsiripongkul

²

,

Thongchom

³

et al. 2022

Preprint

0

View full text Add to dashboard Cite

This study offers a comprehensive investigation into the parameters affecting the sound transmission characteristics of a double-walled sandwich magneto-electro-elastic cross-ply layered plate resting on viscoelastic medium in thermal environment. To this end, the walls of this sandwich structure are modeled based on the assumptions of the first-order shear deformation theory. The governing equations are derived via a coupled set of equations targeting vibration and acoustic aspects of the problem after the application of Hamilton’s principle. The obtained equations are then solved by the implementation of double Fourier series and the second velocity potential, giving an accurate estimation of sound transmission loss under initial magnetic and electric potentials, variations of temperature, ply angle, acoustic cavity depth, incident angle of sound waves, and viscoelastic parameters.

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“…The electric potential distribution is expressed by C and computed by a trigonometric function and a linear function along the direction of face layers thickness as follows (Arefi et al, 2018a(Arefi et al, , 2018b)…”

Section: Formulationmentioning

confidence: 99%

Electric field effect on dynamic analysis of smart porosity-dependent nanocomposite sandwich plate resting on silica aerogel foundation considering carbon nanotubes agglomeration

Zamani

¹

,

Heidari-Rarani

²

,

Ariaei

³

2019

Journal of Intelligent Material Systems and Structures

Self Cite

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In this study, the influence of carbon nanotubes agglomeration is investigated on the electroelastic dynamic behavior of a sandwich plate. The smart sandwich plate consists of functionally graded porous layer as the core and piezoelectric layers as the face sheets, which is subjected to the harmonic electrical loading. In order to take into account the continuum model for the silica aerogel foundation of the smart structure, the modified Vlasov’s model is applied. The porosity distribution of the core layer varies non-uniformly throughout the thickness due to the non-uniform function. The equivalent material properties of nanocomposite core layer are determined using the Eshelby–Mori–Tanaka approach, in which the influence of carbon nanotube agglomeration is considered. For modeling the electroelastic fact sheets behavior, the piezoelasticity theory is adopted. On the basis of non-polynomial shear and normal deformation theory, the governing equations of motion are inferred applying the Hamilton’s principle and the obtained equations are solved by an iterative procedure. The verification is accomplished through the available results in the literature and the influences of carbon nanotube agglomeration, different geometrical parameters, porosity index, and applied voltage are assessed on the dynamic deflection of nanocomposite sandwich plate.

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Nonlocal strain gradient theory for the magneto-electro-elastic vibration response of a porous FG-core sandwich nanoplate with piezomagnetic face sheets resting on an elastic foundation

Cited by 59 publications

References 62 publications

Sound transmission loss of double-walled sandwich cross-ply layered magneto-electro-elastic plates under thermal environment

Sound transmission loss of double-walled sandwich cross-ply layered magneto-electro-elastic plates under thermal environment

Sound transmission loss of double-walled sandwich cross-ply layered magneto-electro- elastic plates under thermal environment

Electric field effect on dynamic analysis of smart porosity-dependent nanocomposite sandwich plate resting on silica aerogel foundation considering carbon nanotubes agglomeration

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