Finite element model based on an efficient layerwise theory for dynamics and active vibration control of smart functionally graded beams

Yasin, M. Yaqoob; Prakash, Bhanu; Khan, Arshad

doi:10.1088/2053-1591/ab6f3f

Cited by 7 publications

(3 citation statements)

References 35 publications

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“…Rafiee et al [12] examined thermal bifurcation buckling of CNT reinforced piezoelectric composite beams and concluded that frequency increases with higher CNT volume fraction. Yasin et al [13] performed dynamic study of smart FG beams by FE method using an efficient layer wise theory. They observed splitting of the piezoelectric material surface and the natural frequency is marginally increased for open circuit condition which is not affected in close circuit condition.…”

Section: Introductionmentioning

confidence: 99%

Bending and vibration study of carbon nanotubes reinforced functionally graded smart composite beams

Kumar

Sarangi

2022

Eng. Res. Express

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A study of smart functionally graded (FG) beams made of carbon nanotube (CNT) reinforced composites combined with piezoelectric materials is presented. The material parameters of the composite beams are assumed to vary along their thickness following extended rule of mixture. A finite element (FE) model was developed for the FG carbon nanotube-reinforced beam combined with piezoelectric materials. This model was tested against previously published studies and was found to be in accordance with them. The numerical results were evaluated using various boundary conditions and are presented. The appropriateness of the piezoelectric layer for deflection control of the FG beam is presented followed by the free vibration results. The numerical analysis revealed that the piezoelectric layer of the smart FG beam efficiently controlled the bending deflections of the presently studied carbon nanotube-reinforced FG beams. Various material profiles for grading FG beams were considered and the results are presented.

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Section: Introductionmentioning

confidence: 99%

Bending and vibration study of carbon nanotubes reinforced functionally graded smart composite beams

Kumar

Sarangi

2022

Eng. Res. Express

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“…Larkin and colleagues [9] used the modified couple stress theory to investigate the impact of small-scale phenomena on the natural frequencies and power density of macro-to nanoscale functionally graded energy harvesters with beam lengths ranging from 62.5 mm to 6.25 m. They found that the natural frequencies and power density of the harvesters were affected by small-scale phenomena. A two-node efficient finite element model combining layerwise mechanics was used by Yasin and colleagues [10] to assess the active vibration stabilization of piezoelectric functionally graded beams. A functionally graded porous piezoelectric sandwich nanobeam reinforced by graphene platelets was investigated by Chen et al [11] using the Euler-Bernoulli beam theory and a differential quadrature technique in order to capture the effect of flexoelectricity on the vibration responses of the nanobeam.…”

Section: Introductionmentioning

confidence: 99%

On the Vibration Analysis of Rotating Piezoelectric Functionally Graded Beams Resting on Elastic Foundation with a Higher-Order Theory

Phuc

Thanh

2022

International Journal of Aerospace Engineering

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This work numerically simulates the natural vibration response of rotating piezoelectric functionally graded (FG) beams resting on two-parameter elastic mediums. This is a common kind of design seen in reality, such as marine engine gas turbine blades, rotating railway bridges, and helicopter rotors, where these components may be thought of as beam models rotating around a fixed axis. For the first time, this study uses the finite element method (FEM) in conjunction with Reddy’s theory of high-order shear deformation to model the vibration response of a beam rotating around one fixed axis. The present theory eliminates the necessity for shear correction factors while precisely describing the structure’s mechanical response. The piezoelectric layers are firmly connected to the top and bottom surfaces of the beam, while the core layer is composed of the FG material, whose material and physical characteristics are expected to gradually change along the thickness direction of the beam in accordance with a power law function as the thickness of the beam is increased. This study is conducted to determine the influences of the structure’s geometric and material characteristics on the beam’s free vibration behavior, including the rotational speed, distance between the fixed axis and beam endpoint, thickness of piezoelectric layers, and elastic foundation parameters, among other things. Due to the obvious calculation results, the free vibration response of this structure can be easily seen by readers, which serves as a foundation for its design and use in engineering practice.

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“…Vodenitcharova and Zhang [11] performed buckling and bending analysis of nanocomposite beam made of single wall CNT. Yasin et al [12] performed dynamic analysis of smart FG beam by FEM using an efficient layer wise theory. They observed that splitting of the piezoelectric material surface increases the natural frequency for open circuit condition but not effective in close circuit condition.…”

Section: Introductionmentioning

confidence: 99%

Finite Element Analysis of Carbon Nanotubes Reinforced Smart Functionally Graded Beam

Kumar

Sarangi

2022

KEM

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Study of smart functionally graded (FG) beam made of carbon nanotube (CNT) reinforced composites combined with piezoelectric material is carried out. Material parameters of the beam are supposed to vary along its thickness following extended rule of mixture. Finite element model is developed for the functionally graded CNT reinforced beam combined with piezoelectric material using ANSYS software. Numerical results are evaluated using different boundary conditions. Computed results revealed that piezoelectric layer of smart FG beam efficiently controls the bending deformations of the presently studied smart CNT reinforced functionally graded beams. Results are also presented considering various material profiles for the grading of FG beams. It is observed that X type profile distribution considering CNT volume fraction of 0.28 provides minimum bending deflection of the presently studied smart FGCNT reinforced composite beams for the activated as well as inactivated piezoelectric material

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Finite element model based on an efficient layerwise theory for dynamics and active vibration control of smart functionally graded beams

Cited by 7 publications

References 35 publications

Bending and vibration study of carbon nanotubes reinforced functionally graded smart composite beams

Bending and vibration study of carbon nanotubes reinforced functionally graded smart composite beams

On the Vibration Analysis of Rotating Piezoelectric Functionally Graded Beams Resting on Elastic Foundation with a Higher-Order Theory

Finite Element Analysis of Carbon Nanotubes Reinforced Smart Functionally Graded Beam

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