Signal Waveform Impact on RF-DC Conversion Efficiency for Different Energy Harvesting Circuits

This paper optimizes the energy harvesting cycle of dissipative dielectric elastomer generators (DEGs) to explore possible approaches for improving the energy harvesting performance. By utilizing the developed theoretical framework, the dissipative performance of the DEG with a constant voltage cycle is analyzed, which shows good agreement with the existing experimental data. On this basis, we design a novel energy harvesting cycle and a corresponding energy harvesting circuit in which a transfer capacitor is utilized to store the charge transferred from the DEG. Then, the energy conversion performance of the DEG with the novel energy harvesting cycle is investigated. The results indicate that both the energy density and conversion efficiency are improved by choosing a high voltage during the discharging process and that as the R-C time constant increases, the enhancement effect of the voltage increases and then approaches to the saturation. In addition, there is an optimal transfer capacitor that can maximize energy density or conversion efficiency, and the optimal transfer capacitor increases with the increase in the R-C time constant. These results and methods are expected to guide the optimal design and assessment of DEGs.

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Analysis and optimal design of a vibration isolation system combined with electromagnetic energy harvester

Journal of Intelligent Material Systems and Structures ◽

10.1177/1045389x19862377 ◽

2019 ◽

Vol 30 (16) ◽

pp. 2382-2395

Author(s):

Uchenna Diala ◽

SM Mahdi Mofidian ◽

Zi-Qiang Lang ◽

Hamzeh Bardaweel

Keyword(s):

Energy Harvesting ◽

Energy Conversion ◽

Conversion Efficiency ◽

Vibration Isolation ◽

Energy Conversion Efficiency ◽

Isolation System ◽

Magnetic Components ◽

Energy Harvesting System ◽

Response Function Method ◽

Conversion Efficiencies

This work investigates a vibration isolation energy harvesting system and studies its design to achieve an optimal performance. The system uses a combination of elastic and magnetic components to facilitate its dual functionality. A prototype of the vibration isolation energy harvesting device is fabricated and examined experimentally. A mathematical model is developed using first principle and analyzed using the output frequency response function method. Results from model analysis show an excellent agreement with experiment. Since any vibration isolation energy harvesting system is required to perform two functions simultaneously, optimization of the system is carried out to maximize energy conversion efficiency without jeopardizing the system’s vibration isolation performance. To the knowledge of the authors, this work is the first effort to tackle the issue of simultaneous vibration isolation energy harvesting using an analytical approach. Explicit analytical relationships describing the vibration isolation energy harvesting system transmissibility and energy conversion efficiency are developed. Results exhibit a maximum attainable energy conversion efficiency in the order of 1%. Results suggest that for low acceleration levels, lower damping values are favorable and yield higher conversion efficiencies and improved vibration isolation characteristics. At higher acceleration, there is a trade-off where lower damping values worsen vibration isolation but yield higher conversion efficiencies.

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Conversion efficiency of broad-band rectennas for solar energy harvesting applications

Optics Express ◽

10.1364/oe.21.00a412 ◽

2013 ◽

Vol 21 (S3) ◽

pp. A412 ◽

Cited By ~ 45

Author(s):

Edgar Briones ◽

Javier Alda ◽

Francisco Javier González

Keyword(s):

Energy Harvesting ◽

Solar Energy ◽

Conversion Efficiency ◽

Broad Band ◽

Solar Energy Harvesting

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Design of Ultra Wideband Rectenna for Ambient RF Energy Harvesting Applications

International Journal of Recent Technology and Engineering - 2 ◽

10.35940/ijrte.c4574.098319 ◽

2019 ◽

Vol 8 (3) ◽

pp. 2155-2158

Keyword(s):

Energy Harvesting ◽

Radio Frequency ◽

Conversion Efficiency ◽

Dielectric Substrate ◽

Ultra Wideband ◽

Low Loss ◽

Radio Frequency Energy ◽

Microstrip Patch ◽

Rf Signals ◽

L Band

In this paper a single fed microstrip patch ultra-wideband rectenna for harvesting ambient radio frequency energy is presented. The rectenna comprises of a rectangular shaped radiating patch operating at L band frequencies. The rectifier circuit is placed in the same plane of radiating patch to minimize the overall rectenna profile. The rectenna is modelled and are fabricated on low loss roger dielectric substrate. Measured results shows that the rectenna attains a maximum gain of 5 dB in the operating L band with maximum RF conversion efficiency of 81%. The rectenna designed is appropriate for harvesting wireless RF signals operating in L band.

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A CMOS Rectifier with 72.3% RF-to-DC Conversion Efficiency Employing Tunable Impedance Matching Network for Ambient RF Energy Harvesting

2018 International SoC Design Conference (ISOCC) ◽

10.1109/isocc.2018.8649983 ◽

2018 ◽

Cited By ~ 1

Author(s):

Donggu Lee ◽

Taejong Kim ◽

Sinyoung Kim ◽

Kanghyeon Byun ◽

Kuduck Kwon

Keyword(s):

Energy Harvesting ◽

Conversion Efficiency ◽

Impedance Matching ◽

Matching Network ◽

Rf Energy Harvesting ◽

Rf Energy ◽

Tunable Impedance

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The effect of nonlinear material viscosity on the energy harvesting performance of dielectric elastomer generators

Journal of Intelligent Material Systems and Structures ◽

10.1177/1045389x20910270 ◽

2020 ◽

Vol 31 (7) ◽

pp. 1029-1038

Author(s):

Yuanping Li ◽

Jianyou Zhou ◽

Liying Jiang

Keyword(s):

Energy Harvesting ◽

Conversion Efficiency ◽

Electromechanical Coupling ◽

Failure Modes ◽

Mechanical Energy ◽

Theoretical Perspective ◽

Dielectric Elastomer ◽

Viscosity Model ◽

Nonlinear Material ◽

Simulation Results

Dielectric elastomer generators are capable of converting mechanical energy from a variety of sources into electrical energy. The energy harvesting performance depends on the interplay between electromechanical coupling, material viscosity, and multiple failure modes. Experiments also suggest that the material viscosity of dielectric elastomers is deformation-dependent, which makes the prediction of the performance of dielectric elastomer generators more challenging. By adopting the coupled field theory, finite-deformation viscoelasticity theory, and the theory for polymer dynamics, this work investigates the harvested energy and conversion efficiency of dielectric elastomer generators from theoretical perspective. By comparing the simulation results from the nonlinear viscosity model to the experimental data and the simulation results from the linear viscosity model, we further examine the possible factors that may strongly influence the performance of dielectric elastomer generators. It is found that dielectric elastomer generators exhibit higher harvested energy when nonlinear material viscosity is considered. Moreover, by selecting a higher voltage of the power supply for the generator, the conversion efficiency of dielectric elastomer generators can be greatly improved. The theoretical framework in this study is expected to offer some new insights into optimizing the design of dielectric elastomer generators and thus improving their performance.

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A Self-Biased Active Voltage Doubler for Energy Harvesting Systems

Active and Passive Electronic Components ◽

10.1155/2017/1650161 ◽

2017 ◽

Vol 2017 ◽

pp. 1-6

Author(s):

Umais Tayyab ◽

Hussain A. Alzaher

Keyword(s):

Energy Harvesting ◽

Power Conversion Efficiency ◽

Conversion Efficiency ◽

Power Conversion ◽

Cmos Process ◽

Dc Voltage ◽

Op Amp ◽

Sinusoidal Input ◽

Voltage Doubler ◽

Load Resistor

An active voltage doubler utilizing a single supply op-amp for energy harvesting system is presented. The proposed doubler is used for rectification process to achieve both acceptably high power conversion efficiency (PCE) and large rectified DC voltage. The incorporated op-amp is self-biased, meaning no external supply is needed but rather it uses part of the harvested energy for its biasing. The proposed active doubler achieves maximum power conversion efficiency (PCE) of 61.7% for a 200 Hz sinusoidal input of 0.8 V for a 20 KΩ load resistor. This efficiency is 2 times more when compared with the passive voltage doubler. The rectified DC voltage is almost 2 times more than conventional passive doubler. The relation between PCE and the load resistor is also presented. The proposed active voltage doubler is designed and simulated in LF 0.15 μm CMOS process technology using Cadence virtuoso tool.

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