A unified electromechanical finite element dynamic analysis of multiple segmented smart plate energy harvesters: circuit connection patterns

Lumentut, Mikail F.; Shu, Y. C.

doi:10.1007/s00707-018-2249-5

Cited by 18 publications

(19 citation statements)

References 61 publications

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“…Non-uniform distribution of electric field can be observed, especially at the region near the top and bottom edge of the beam, which yields high electric field gradient and consequently induces deformation. Note that the considered flexoelectric beams do not account for the resistive load [10] or the rectifying circuit [77,78]. In [77], a piezoelectric structure is analyzed along with its circuit connections.…”

Section: Cantilever Beammentioning

confidence: 99%

“…Note that the considered flexoelectric beams do not account for the resistive load [10] or the rectifying circuit [77,78]. In [77], a piezoelectric structure is analyzed along with its circuit connections. In addition, in [78], comparisons between the charge type Hamiltonian and voltage type Hamiltonian are performed to identify the output power and voltage of the piezoelectric energy harvester.…”

Section: Cantilever Beammentioning

confidence: 99%

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Computational Modeling of Flexoelectricity—A Review

et al. 2020

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Electromechanical coupling devices have been playing an indispensable role in modern engineering. Particularly, flexoelectricity, an electromechanical coupling effect that involves strain gradients, has shown promising potential for future miniaturized electromechanical coupling devices. Therefore, simulation of flexoelectricity is necessary and inevitable. In this paper, we provide an overview of numerical procedures on modeling flexoelectricity. Specifically, we summarize a generalized formulation including the electrostatic stress tensor, which can be simplified to retrieve other formulations from the literature. We further show the weak and discretization forms of the boundary value problem for different numerical methods, including isogeometric analysis and mixed FEM. Several benchmark problems are presented to demonstrate the numerical implementation. The source code for the implementation can be utilized to analyze and develop more complex flexoelectric nano-devices.

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Section: Cantilever Beammentioning

confidence: 99%

Section: Cantilever Beammentioning

confidence: 99%

Computational Modeling of Flexoelectricity—A Review

et al. 2020

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“…For the first complex natural vibration frequency, for instance, the difference between the results obtained using the finite-element mesh with 510 nodal unknowns and 5678 nodal unknowns for the real part was 0.8% and for the imaginary part was 20.5%. The difference between the results obtained using the finite-element mesh with 5678 nodal unknowns and 13323 nodal unknowns for the real part was 0.09% and for the imaginary part was 3.7% As mentioned earlier, the ANSYS package has the possibility for specifying damping proportional to the full stiffness matrix with the aid of the coefficients g or m p (25). This damping can be considered as a particular case for the model of linear viscoelasticity, which is described by complex dynamic moduli, when the shear and bulk components of the complex dynamic modulus satisfy the following condition G Tables 1 and 2 present the results of the calculations of the natural vibration frequencies for the first five eigenfrequencies of the structure with the piezoelectric element (Figure 4(a)), when it is operated in the open circuit mode (Table 1), and in the short circuit mode (Table 2), when the material of the plate has viscoelastic properties.…”

Section: Approbation Of the Algorithmmentioning

confidence: 87%

Algorithm for solving problems related to the natural vibrations of electro-viscoelastic structures with shunt circuits using ANSYS data

Iurlova

Sevodina

Oshmarin

et al. 2018

International Journal of Smart and Nano Materials

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An algorithm for numerical realisation of a mathematical statement of the natural vibrations problem for electro-viscoelastic bodies with passive external electric circuits (i.e. shunting circuits) with an arbitrary configuration using the finite element method is proposed in the present paper. The proposed algorithm allows considering the viscoelastic properties of materials using the model of linear hereditary viscoelasticity with complex dynamic moduli and is used to solve 3D solid structure problems that are compatible for ANSYS package element types. This technique implies the usage of the global assembled matrices of stiffness and mass, formed in the ANSYS package. The basis of the algorithm is a novel approach that allows performing decomposition of the global assembled stiffness matrix formed in the ANSYS software package into constituents that are needed for calculation of the natural vibration frequencies of the objects under study. These matrix components are used in the program that was written in FORTRAN (Formula Translation) language. This problem could be efficiently applied for analysis of the dynamic processes in smart systems based on piezoelectric materials and could also form a basis for the development of numerical finite element algorithms for optimization of the dissipative characteristics of electromechanical systems with shunted piezoelectric elements.

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“…where b ≡ {b m , −ρ e } denotes the generalized volume loads and t ≡ {t m , σ e } denotes the generalized surface tractions. Substituting Equations (6), (7) and (9) into Equation 11, one obtains…”

Section: Governing Equationsmentioning

confidence: 99%

“…The availability of techniques for manufacturing composite laminates employing layers with multi-physics properties has led to the concept of smart laminates, in which different laminae may exhibit couplings between different physical fields, e.g., mechanical, thermal, electric, magnetic or even a combination of more than two of such fields, thus enabling the design of devices with multifunctional capabilities, besides the basic structural employment [2][3][4][5]. A remarkable example is provided by piezoelectric materials and laminates that, exploiting the coupling between the mechanical and electrical fields, may be employed in several applications of engineering or scientific interest [6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Layer-Wise Discontinuous Galerkin Methods for Piezoelectric Laminates

2020

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In this work, a novel high-order formulation for multilayered piezoelectric plates based on the combination of variable-order interior penalty discontinuous Galerkin methods and general layer-wise plate theories is presented, implemented and tested. The key feature of the formulation is the possibility to tune the order of the basis functions in both the in-plane approximation and the through-the-thickness expansion of the primary variables, namely displacements and electric potential. The results obtained from the application to the considered test cases show accuracy and robustness, thus confirming the developed technique as a supplementary computational tool for the analysis and design of smart laminated devices.

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A unified electromechanical finite element dynamic analysis of multiple segmented smart plate energy harvesters: circuit connection patterns

Cited by 18 publications

References 61 publications

Computational Modeling of Flexoelectricity—A Review

Computational Modeling of Flexoelectricity—A Review

Algorithm for solving problems related to the natural vibrations of electro-viscoelastic structures with shunt circuits using ANSYS data

Layer-Wise Discontinuous Galerkin Methods for Piezoelectric Laminates

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