Considerations on frequency characteristics of an electromechanical vibration energy harvesting converter with nonlinear parametric resonance

Jagieła, Mariusz; Kulik, Marcin

doi:10.3233/jae-160015

Cited by 3 publications

(1 citation statement)

References 12 publications

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“…Micro scale energy harvesting (EH) becoming equally importance of energy generations, this is due to the fact that wasted energy at micro level in nature can be harvested and utilize for another purposes. For example, heat or vibration waste energy can be harvested to supply bank of temporary energy storage [8] [9]. Nowadays, vibration based piezoelectric energy harvesting technology has been evolved drastically.…”

Section: Introductionmentioning

confidence: 99%

Design and implementation of an energy harvester interface circuit using ultra-low power piezo bending generator

Sarke¹

2020

IJATCSE

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This paper presents design and implementations of energy harvesting interface circuit (EHIC) utilizing ultra-low power (ULP) piezo-bending generator PBG to run micro-devices. Conventionally, energy harvesting (EH) devices produce low energy thus incapable to load interface with multiple applications. It is therefore support electronic drives are needed to compensate and match the load demand. In this study, an active technique electronic drives is designed and implemented for energy harvester that consists of full-wave MOSFET bridge rectifier circuit, low pass filter, step-up converter with regulator and temporary storage device. The proposed technique is simulated using PSPICE software and comparisons were made to the conventional technique on the output side. The results show that the performance of proposed technique is better than the conventional technique in terms of the output voltage. The proposed active technique generates an output up to 2.3V whereas the conventional step-up converter generates an output of 0.42V. The proposed model EHIC simulation is run in PSPICE and implemented onto prototype board to verify the functionality. The integrated EHIC is able to generate maximum output of 1.612V from an input of 0.7V. This corresponds to the overall efficiency of developed hardware to be greater than 74%.

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Section: Introductionmentioning

confidence: 99%

Design and implementation of an energy harvester interface circuit using ultra-low power piezo bending generator

Sarke¹

2020

IJATCSE

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Chaotic behavior of new nonlinear electromagnetic microgenerator harvesting energy from mechanical vibrations

Jagieła

Kulik

2017

2017 International Symposium on Electrical Machines (SME)

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Harvesting mechanical vibrations energy using nonlinear electromagnetic minigenerators - a survey of concepts and problems

Kulik

Jagieła

2017

PUT Academic J.: Electrical Engineering

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Considerations on frequency characteristics of an electromechanical vibration energy harvesting converter with nonlinear parametric resonance

Cited by 3 publications

References 12 publications

Design and implementation of an energy harvester interface circuit using ultra-low power piezo bending generator

Design and implementation of an energy harvester interface circuit using ultra-low power piezo bending generator

Chaotic behavior of new nonlinear electromagnetic microgenerator harvesting energy from mechanical vibrations

Harvesting mechanical vibrations energy using nonlinear electromagnetic minigenerators - a survey of concepts and problems

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