Analytical modeling and experimental validation of a structurally integrated piezoelectric energy harvester on a thin plate

Aridogan, Ugur; Basdogan, Ipek; Ertürk, Alper

doi:10.1088/0964-1726/23/4/045039

Cited by 73 publications

(65 citation statements)

References 51 publications

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“…In the existing literatureofpiezoelectrice nergy harvesting, linear and nonlinear beams and plates with piezoelectric layers have been the main focus of the mainstream research. [7][8][9][10][11][12][13][14][15][16][17][18][19] Numerous articles have reported the development of analytical and numerical electromechanical models of cantilevered energy harvesters for the optimal mechanical and electrical conditions [9,11,[20][21][22] with the assumption that the vibration input to the harvesteri so fd eterministic type,o ften as simple as harmonic excitation at resonance. [7,12,23,24] However, in most applications,a mbientv ibrations are manifested in non-deterministicf orms.W hen compared with the amount of published research on piezoelectric energy harvesters with deterministic harmonic input, the existinge fforts on piezo-electric energy harvesting from broadband and band-limited random vibrations are very limited.…”

Section: Introductionmentioning

confidence: 99%

Soft and Hard Piezoelectric Ceramics and Single Crystals for Random Vibration Energy Harvesting

2018

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Vibration‐based energy harvesting for enabling next‐generation self‐powered devices is a rapidly growing research area. In real‐world applications, the ambient vibrational energy is often available in non‐deterministic forms rather than the extensively studied deterministic scenarios, such as simple harmonic excitation. It is of interest to choose the best piezoelectric material for a given random excitation. Here, performance comparisons of various soft and hard piezoelectric ceramics and single crystals are presented for electrical power generation under band‐limited off‐resonance and wideband random vibration energy‐harvesting scenarios. For low‐frequency off‐resonance excitation, it is found that soft piezoelectric ceramics based upon lead zirconate titanate (e.g., PZT‐5H and PZT‐5A) outperform their hard counterparts (e.g., PZT‐4 and PZT‐8), and likewise soft single crystals based upon lead magnesium niobate and lead titanate as well as PZT (e.g., PMN‐PT and PMN‐PZT) outperform the relatively hard ones (e.g., manganese‐doped PMN‐PZT‐Mn). Overall, for such off‐resonance random vibrations, PMN‐PT is the most suitable choice among the materials studied. For wideband random excitation with a bandwidth covering the fundamental resonance of the harvester, hard piezoelectric ceramics offer larger power output compared to soft ceramics, and likewise hard single crystals produce larger power compared to their soft counterparts. Remarkably, a hard piezoelectric ceramic (e.g., PZT‐8) can outperform a soft single crystal (e.g., PMN‐PT) for wideband random vibration energy harvesting.

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Section: Introductionmentioning

confidence: 99%

Soft and Hard Piezoelectric Ceramics and Single Crystals for Random Vibration Energy Harvesting

2018

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“…Obviously, it is difficult to obtain an exact solution of the PMP-LR according to equation (20). Similar to existing works [8,10], the Rayleigh-Ritz method will be implemented to perform modal vibration analysis in this paper.…”

Section: Modal Analysis Of the Pmp-lr Based On The Rayleigh-ritzmentioning

confidence: 99%

“…Erturk presented analytical formulation for energy harvesting with piezoelectric patches from surface fluctuations of large and high impedance structures [9]. Aridogan et al [10] derived analytical closed-form expressions of piezoelectric patch-based energy harvesters structurally integrated to fully clamped plates. However, those works mostly focus on a single piezoelectric patch, and vibration propagations on the thin plate are often less considered.…”

Section: Introductionmentioning

confidence: 99%

Vibration Bandgaps of Piezoelectric Metamaterial Plate with Local Resonators for Vibration Energy Harvesting

Chen

Wang

2019

Shock and Vibration

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Embedded wireless sensing networks (WSNs) provide effective solutions for structural health monitoring (SHM), where how to provide long-term electric power is a bottle-neck problem. Piezoelectric vibration energy harvesting (PVEH) has been widely studied to realize self-powered WSNs due to piezoelectric effect. Structural vibrations are usually variable and exist in the form of elastic waves, so cantilever-like harvesters are not appropriate. In this paper, one kind of two-dimensional (2D) piezoelectric metamaterial plates with local resonators (PMP-LR) is investigated for structural vibration energy harvesting. In order to achieve low-frequency and broadband PVEH in SHM, it is highly necessary to study dynamic characteristics of PMP-LR, particularly bandgaps. Firstly, an analytical model is developed based on the Kirchhoff plate theory, and modal analysis is done by using the Rayleigh–Ritz method. Then, effects of geometric and material parameters on vibration bandgaps are analyzed by finite element-based simulations. In the end, experiments are carried out to validate the simulated results. The results demonstrate that the location of bandgaps can be easily adjusted by the design of local resonators. Therefore, the proposed method will provide an effective tool for optimizing local resonators in PMP-LR.

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“…Since the neighboring modes are not included, as the excitation frequency deviates from the resonance condition, the single-mode solution fails to be reliable and accurate. Having validated the analytical (modal analysis) results versus numerical (FEM) results through figures 4-6 (note that the analytical model was experimentally validated previously [34]), next the AC-DC conversion problem is explored by adding the standard ideal rectification circuit. Figure 7 illustrates the standard AC-DC piezoelectric energy harvesting circuit consisting of a full-wave rectifier, a smoothing capacitor, and a resistive load.…”

Section: Standard Ac-ac Problemmentioning

confidence: 99%

Equivalent circuit modeling of a piezo-patch energy harvester on a thin plate with AC–DC conversion

Bayik

Aghakhani

Basdogan

et al. 2016

Smart Mater. Struct.

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As an alternative to beam-like structures, piezoelectric patch-based energy harvesters attached to thin plates can be readily integrated to plate-like structures in automotive, marine, and aerospace applications, in order to directly exploit structural vibration modes of the host system without mass loading and volumetric occupancy of cantilever attachments. In this paper, a multi-mode equivalent circuit model of a piezo-patch energy harvester integrated to a thin plate is developed and coupled with a standard AC-DC conversion circuit. Equivalent circuit parameters are obtained in two different ways: (1) from the modal analysis solution of a distributed-parameter analytical model and (2) from the finite-element numerical model of the harvester by accounting for two-way coupling. After the analytical modeling effort, multi-mode equivalent circuit representation of the harvester is obtained via electronic circuit simulation software SPICE. Using the SPICE software, electromechanical response of the piezoelectric energy harvester connected to linear and nonlinear circuit elements are computed. Simulation results are validated for the standard AC-AC and AC-DC configurations. For the AC input-AC output problem, voltage frequency response functions are calculated for various resistive loads, and they show excellent agreement with modal analysis-based analytical closed-form solution and with the finite-element model. For the standard ideal AC input-DC output case, a full-wave rectifier and a smoothing capacitor are added to the harvester circuit for conversion of the AC voltage to a stable DC voltage, which is also validated against an existing solution by treating the singlemode plate dynamics as a single-degree-of-freedom system.

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Analytical modeling and experimental validation of a structurally integrated piezoelectric energy harvester on a thin plate

Cited by 73 publications

References 51 publications

Soft and Hard Piezoelectric Ceramics and Single Crystals for Random Vibration Energy Harvesting

Soft and Hard Piezoelectric Ceramics and Single Crystals for Random Vibration Energy Harvesting

Vibration Bandgaps of Piezoelectric Metamaterial Plate with Local Resonators for Vibration Energy Harvesting

Equivalent circuit modeling of a piezo-patch energy harvester on a thin plate with AC–DC conversion

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