Design and Power Output Characteristics of an EYE-type Piezoelectric Energy Harvester

With the rapid development of wearable electronics, novel power solutions are required to adapt to flexible surfaces for widespread applications, thus flexible energy harvesters have been extensively studied for their flexibility and stretchability. However, poor power output and insufficient sensitivity to environmental changes limit its widespread application in engineering practice. A doubly clamped flexible piezoelectric energy harvester (FPEH) with axial excitation is therefore proposed for higher power output in a low-frequency vibration environment. Combining the Euler–Bernoulli beam theory and the D’Alembert principle, the differential dynamic equation of the doubly clamped energy harvester is derived, in which the excitation mode of axial load with pre-deformation is considered. A numerical solution of voltage amplitude and average power is obtained using the Rayleigh–Ritz method. Output power of 22.5 μW at 27.1 Hz, with the optimal load resistance being 1 MΩ, is determined by the frequency sweeping analysis. In order to power electronic devices, the converted alternating electric energy should be rectified into direct current energy. By connecting to the MDA2500 standard rectified electric bridge, a rectified DC output voltage across the 1 MΩ load resistor is characterized to be 2.39 V. For further validation of the mechanical-electrical dynamical model of the doubly clamped flexible piezoelectric energy harvester, its output performances, including both its frequency response and resistance load matching performances, are experimentally characterized. From the experimental results, the maximum output power is 1.38 μW, with a load resistance of 5.7 MΩ at 27 Hz, and the rectified DC output voltage reaches 1.84 V, which shows coincidence with simulation results and is proved to be sufficient for powering LED electronics.

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Performance analysis of a lever piezoelectric energy harvester for roadway applications

Journal of Intelligent Material Systems and Structures ◽

10.1177/1045389x211001445 ◽

2021 ◽

pp. 1045389X2110014

Author(s):

Guangya Ding ◽

Hongjun Luo ◽

Jun Wang ◽

Guohui Yuan

Keyword(s):

Output Power ◽

Energy Harvester ◽

Open Circuit ◽

Traffic Load ◽

Energy Harvesters ◽

Speed Sensor ◽

Piezoelectric Energy ◽

Optimal Load ◽

Self Powered ◽

Output Characteristics

A novel lever piezoelectric energy harvester (LPEH) was designed for installation in an actual roadway for energy harvesting. The model incorporates a lever module that amplifies the applied traffic load and transmits it to the piezoelectric ceramic. To observe the piezoelectric growth benefits of the optimized LPEH structure, the output characteristics and durability of two energy harvesters, the LPEH and a piezoelectric energy harvester (PEH) without a lever, were measured and compared by carrying out piezoelectric performance tests and traffic model experiments. Under the same loading condition, the open circuit voltages of the LPEH and PEH were 20.6 and 11.7 V, respectively, which represents a 76% voltage increase for the LPEH compared to the PEH. The output power of the LPEH was 21.51 mW at the optimal load, which was three times higher than that of the PEH (7.45 mW). The output power was linearly dependent on frequency and load, implying the potential application of the module as a self-powered speed sensor. When tested during 300,000 loading cycles, the LPEH still exhibited stable structural performance and durability.

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Optimization of energy harvesting based on the uniform deformation of piezoelectric ceramic

Functional Materials Letters ◽

10.1142/s1793604716500697 ◽

2016 ◽

Vol 09 (05) ◽

pp. 1650069 ◽

Cited By ~ 4

Author(s):

Yaoze Liu ◽

Tongqing Yang ◽

Fangming Shu

Keyword(s):

Energy Harvesting ◽

Power Output ◽

Piezoelectric Ceramic ◽

Energy Harvester ◽

Optimization Method ◽

Piezoelectric Energy ◽

Bonding Area ◽

Almost All ◽

Matching Load ◽

Tip Mass

Since the piezoelectric properties were used for energy harvesting, almost all forms of energy harvester needs to be bonded with a mass block to achieve pre-stress. In this article, disc type piezoelectric energy harvester is chosen as the research object and the relationship between mass bonding area and power output is studied. It is found that if the bonding area is changed as curved, which is usually complanate in previous studies, the deformation of the circular piezoelectric ceramic is more uniform and the power output is enhanced. In order to test the change of the deformation, we spray several homocentric annular electrodes on the surface of a piece of bare piezoelectric ceramic and the output of each electrode is tested. Through this optimization method, the power output is enhanced to more than 11[Formula: see text]mW for a matching load about 24[Formula: see text]k[Formula: see text] and a tip mass of 30[Formula: see text]g at its resonant frequency of 139[Formula: see text]Hz.

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Performance Analysis of Piezoelectric Energy Harvesting in Pavement: Laboratory Testing and Field Simulation

Transportation Research Record Journal of the Transportation Research Board ◽

10.1177/0361198119830308 ◽

2019 ◽

Vol 2673 (3) ◽

pp. 115-124 ◽

Cited By ~ 7

Author(s):

Abbas F. Jasim ◽

Hao Wang ◽

Greg Yesner ◽

Ahmad Safari ◽

Pat Szary

Keyword(s):

Energy Harvesting ◽

Power Output ◽

Laboratory Testing ◽

Energy Harvester ◽

Total Power ◽

Piezoelectric Energy Harvesting ◽

Loading Frequency ◽

Vehicle Speed ◽

Piezoelectric Energy ◽

Energy Harvesting System

This study investigated the energy harvesting performance of a piezoelectric module in asphalt pavements through laboratory testing and multi-physics based simulation. The energy harvester module was assembled with layers of Bridge transducers and tested in the laboratory. A decoupled approach was used to study the interaction between the energy harvester and the surrounding pavement. The effects of embedment location, vehicle speed, and temperature on energy harvesting performance were investigated. The analysis findings indicate that the embedment location and vehicle speed affects the resulted power output of the piezoelectric energy harvesting system. The embedment depth of the energy module affects both the magnitude and frequency of stress pulse on top of the energy module induced by tire loading. On the other hand, higher vehicle speed causes greater loading frequency and thus greater power output; the effect of pavement temperature is negligible. The analysis of total power output before reaching fatigue failure of the energy module can be used to determine the optimum embedment location in the asphalt layer. The proposed energy harvesting system provides great potential to generate green energy from waste kinetic energy in roadway pavements. Field study is recommended to verify these findings with long-term performance monitoring of pavement with embedded energy harvesters.

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On the Efficiency of a Piezoelectric Energy Harvester under Combined Aeroelastic and Base Excitation

Micromachines ◽

10.3390/mi12080962 ◽

2021 ◽

Vol 12 (8) ◽

pp. 962

Author(s):

Antiopi-Malvina Stamatellou ◽

Anestis I. Kalfas

Keyword(s):

Conversion Efficiency ◽

Power Output ◽

Polyvinylidene Fluoride ◽

Energy Harvester ◽

Excitation Frequency ◽

Elastic Strain Energy ◽

Rate Of Change ◽

Mode Shapes ◽

Base Excitation ◽

Piezoelectric Energy

A flutter-type, nonlinear piezoelectric energy harvester was tested in various combinations of aerodynamic and harmonic base excitation to study its power output and efficiency. The commercial polyvinylidene fluoride film transducer LDT1-028K was used in 33 excitation mode. The aerodynamic excitation was created by a centrifugal fan and the base excitation by a cone speaker. The excitations were produced by varying independently the mean airflow velocity and the frequency of base vibration. A capacitive load was used to store the harvested energy. A line laser was employed along with long exposure photography and high-speed video, for the visualization of the piezo film’s mode shapes and the measurement of maximum tip deflection. The harvested power was mapped along with the maximum tip deflection of the piezo-film, and a process of optimally combining the two excitation sources for maximum power harvesting is demonstrated. The energy conversion efficiency is defined by means of electrical power output divided by the elastic strain energy rate of change during oscillations. The efficiency was mapped and correlated with resonance conditions and results from other studies. It was observed that the conversion efficiency is related to the phase difference between excitation and response and tends to decrease as the excitation frequency rises.

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Modeling and Analysis the Effect of PZT Area on Square Shaped Substrate for Power Enhancement in MEMS Piezoelectric Energy Harvester

Journal of Circuits System and Computers ◽

10.1142/s0218126617501286 ◽

2017 ◽

Vol 26 (09) ◽

pp. 1750128 ◽

Cited By ~ 2

Author(s):

Babak Montazer ◽

Utpal Sarma

Keyword(s):

Lead Zirconate Titanate ◽

Power Output ◽

Energy Harvester ◽

Single Layer ◽

Beam Theory ◽

Lead Zirconate ◽

Modeling And Analysis ◽

Piezoelectric Energy ◽

Resonance Frequencies ◽

Array Structure

Modeling and analysis of a MEMS piezoelectric (PZT-Lead Zirconate Titanate) unimorph cantilever with different substrates are presented in this paper. Stainless steel and Silicon [Formula: see text] are considered as substrate. The design is intended for energy harvesting from ambient vibrations. The cantilever model is based on Euler–Bernoulli beam theory. The generated voltage and power, the current density, resonance frequencies and tip displacement for different geometry (single layer and array structure) have been analyzed using finite element method. Variation of output power and resonant frequency for array structure with array elements connected in parallel have been studied. Strain distribution is studied for external vibrations with different frequencies. The geometry of the piezoelectric layer as well as the substrate has been optimized for maximum power output. The variation of generated power output with frequency and load has also been presented. Finally, several models are introduced and compared with traditional array MEMS energy harvester.

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The Effect of Axial Displacement of Magnets in Piezoelectric Energy Harvester

International Journal of Engineering & Technology ◽

10.14419/ijet.v7i3.7.16221 ◽

2018 ◽

Vol 7 (3.7) ◽

pp. 95

Author(s):

Li Wah Thong ◽

Yu Jing Bong ◽

Swee Leong Kok ◽

Roszaidi Ramlan

Keyword(s):

Frequency Spectrum ◽

Power Output ◽

Energy Harvester ◽

Vibrational Energy ◽

Vibration Energy ◽

Vibration Energy Harvester ◽

Energy Harvesters ◽

Piezoelectric Energy ◽

Operational Frequency ◽

And Performance

The utilization of vibration energy harvesters as a substitute to batteries in wireless sensors has shown prominent interest in the literature. Various approaches have been adapted in the energy harvesters to competently harvest vibrational energy over a wider spectrum of frequencies with optimize power output. A typical bistable piezoelectric energy harvester, where the influence of magnetic field is induced into a linear piezoelectric cantilever, is designed and analyzed in this paper. The exploitations of the magnetic force specifically creates nonlinear response and bistability in the energy harvester that extends the operational frequency spectrum for optimize performance. Further analysis on the effects of axial spacing displacement between two repulsive magnets of the harvester, in terms of x-axis (horizontal) and z-axis (vertical) on its natural resonant frequency and performance based on the frequency response curve are investigated for realizing optimal power output. Experimental results show that by selecting the optimal axial spacing displacement, the vibration energy harvester can be designed to produce maximized output power in an improved broadband of frequency spectrum.

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Research on output characteristics of piezoelectric energy harvester with different circuit load

10.1109/auteee52864.2021.9668770 ◽

2021 ◽

Author(s):

Kai Zhang ◽

Li Dong ◽

Yongyong Zhu

Keyword(s):

Energy Harvester ◽

Piezoelectric Energy ◽

Output Characteristics

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Uncertainty analysis of galloping based piezoelectric energy harvester system using polynomial neural network

Journal of Intelligent Material Systems and Structures ◽

10.1177/1045389x211072519 ◽

2022 ◽

pp. 1045389X2110725

Author(s):

Rakesha Chandra Dash ◽

Narayan Sharma ◽

Dipak Kumar Maiti ◽

Bhrigu Nath Singh

Keyword(s):

Neural Network ◽

Power Output ◽

Energy Harvester ◽

Electrical Power ◽

Piezoelectric Energy ◽

Polynomial Neural Network ◽

Input Parameters ◽

Uncertain Input ◽

System Properties ◽

The Impact

This paper deals with the impact of uncertain input parameters on the electrical power generation of galloping-based piezoelectric energy harvester (GPEH). A distributed parameter model for the system is derived and solved by using Newmark beta numerical integration technique. Nonlinear systems tend to behave in a completely different manner in response to a slight change in input parameters. Due to the complex manufacturing process and various technical defects, randomness in system properties is inevitable. Owing to the presence of randomness within the system parameters, the actual power output differs from the expected one. Therefore, stochastic analysis is performed considering uncertainty in aerodynamic, mechanical, and electrical parameters. A polynomial neural network (PNN) based surrogate model is used to analyze the stochastic power output. A sensitivity analysis is conducted and highly influenced parameters to the electric power output are identified. The accuracy and adaptability of the PNN model are established by comparing the results with Monte Carlo simulation (MCS). Further, the stochastic analyses of power output are performed for various degrees of randomness and wind velocities. The obtained results showed that the influence of the electromechanical coefficient on power output is more compared to other parameters.

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