An accurate novel coupled field Timoshenko piezoelectric beam finite element with induced potential effects

Sulbhewar, Litesh N; Raveendranath, P.

doi:10.1590/s1679-78252014000900008

Cited by 11 publications

(15 citation statements)

References 27 publications

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“…where � = +1 − is the voltage (difference of electric potential) in the piezoelectric layer . Marinković et al (2007) and Sulbhewar and Raveendranath (2014) show that an electric potential consistent with a first-order shear deformation theory, as the one based on the Timoshenko assumption, should have an additional quadratic term in related to the curvature. Marinković et al (2007;2009) also show that the use of (13) is sufficiently accurate for typically thin piezoelectric layers.…”

Section: Displacement Strain Electric Potential and Electric Fieldmentioning

confidence: 96%

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A beam element for piezoelectric planar frames under small strains but large rotations using the total Lagrangian description

Monteiro

Neto

et al. 2020

Lat. Am. j. solids struct.

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Section: Displacement Strain Electric Potential and Electric Fieldmentioning

confidence: 96%

“…The coefficients � 11 , ̃3 1 and ̃3 depend on the type of special assumption made. Following Butz et al (2008), Khdeir et al (2012), Elshafei et al (2014) and Sulbhewar and Raveendranath (2014) Substitution of (9), 14and 19into 17gives…”

Section: Constitutive Relationsmentioning

confidence: 99%

A beam element for piezoelectric planar frames under small strains but large rotations using the total Lagrangian description

Monteiro

Neto

et al. 2020

Lat. Am. j. solids struct.

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“…However, assumed higher-order potential distribution in the formulation introduces additional nodal electrical degrees of freedom in the transverse direction and hence increases the computational cost. An alternate efficient way to include the higher-order induced potential in FSDT-based formulation is to use the consistent through-thickness potential distribution derived from the electrostatic equilibrium equation (Sulbhewar and Raveendranath, 2014b).…”

Section: Latin American Journal Of Solids and Structures 13 (2016) 99mentioning

confidence: 99%

A Timoshenko Piezoelectric Beam Finite Element with Consistent Performance Irrespective of Geometric and Material Configurations

Sulbhewar

Raveendranath

2016

Lat. Am. j. solids struct.

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The conventional Timoshenko piezoelectric beam finite elements based on First-order Shear Deformation Theory (FSDT) do not maintain the accuracy and convergence consistently over the applicable range of material and geometric properties. In these elements, the inaccuracy arises due to the induced potential effects in the transverse direction and inefficiency arises due to the use of independently assumed linear polynomial interpolation of the field variables in the longitudinal direction. In this work, a novel FSDT-based piezoelectric beam finite element is proposed which is devoid of these deficiencies. A variational formulation with consistent through-thickness potential is developed. The governing equilibrium equations are used to derive the coupled field relations. These relations are used to develop a polynomial interpolation scheme which properly accommodates the bending-extension, bending-shear and induced potential couplings to produce accurate results in an efficient manner. It is noteworthy that this consistently accurate and efficient beam finite element uses the same nodal variables as of conventional FSDT formulations available in the literature. Comparison of numerical results proves the consistent accuracy and efficiency of the proposed formulation irrespective of geometric and material configurations, unlike the conventional formulations.

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“…In this expression, the quadratic term represents the induced potential, which is dependent on the beam curvature. The modified expression (Sulbhewar and Raveendranath 2014) for through-thickness distribution of potential in the top extension actuator, which is modeled employing Timoshenko's beam theory, is where, u a ð Þ x ð Þ ¼…”

Section: Coupled Constitutive Relationsmentioning

confidence: 99%

Improved finite element modeling of piezoelectric beam with edge debonded actuator for actuation authority and vibration behaviour

Raja¹,

Rao

Gowda³

2015

Int J Mech Mater Des

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The main emphasis of the present work is to model a piezoelectric beam with edge debonded actuator by employing finite element method based layerwise shear deformation theory, to improve the accuracy with which the actuation authority and natural frequencies are computed. The surface-bonded piezoelectric actuators and the host beam are considered to rotate individually due to shear deformation, while they are assumed to undergo the same flexural deflection and slope. These modeling aspects have improved the accuracy of the computed results. Edge debonding of actuator is accounted in the model by modeling healthy and debonded regions of the beam individually and subsequently applying the displacement continuity conditions at the interfaces of different regions. The investigations are carried out to find the effect of different extents of edge debonding on the actuation authority and natural frequencies of the debonded piezoelectric beam. It is found from the numerical results that the behaviour of the beam with edge debonded actuator is affected considerably as regards to the actuation authority and marginally with respect to natural frequencies. Further it has been shown that, when an actuator is edge debonded it introduces the local modes besides displaying significant reduction in its actuation authority.

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An accurate novel coupled field Timoshenko piezoelectric beam finite element with induced potential effects

Cited by 11 publications

References 27 publications

A beam element for piezoelectric planar frames under small strains but large rotations using the total Lagrangian description

A beam element for piezoelectric planar frames under small strains but large rotations using the total Lagrangian description

A Timoshenko Piezoelectric Beam Finite Element with Consistent Performance Irrespective of Geometric and Material Configurations

Improved finite element modeling of piezoelectric beam with edge debonded actuator for actuation authority and vibration behaviour

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