Experimental Characterization of an AC–DC Boost for Energy Harvesting Device Based on Magnetostrictive Materials

Magnetostrictive alloys hold great promise for Energy Harvesting applications due to their inherent durability. However, their implementation often results in usable voltage ranges that fall significantly below common electronic standards like 1.6, 3.3, and 5 volts. Consequently, the utilization of...

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Published in:Electricity (Basel, Switzerland) Switzerland), 2024-03, Vol.5 (1), p.24-35
Main Authors: Clemente, Carmine Stefano, Davino, Daniele, Iannone, Immacolato, Loschiavo, Vincenzo Paolo
Format: Article
Language:English
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AC–DC boost
Arduino
Design
Efficiency
Energy
energy harvesting
magnetostrictive materials
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container_end_page 35
container_issue 1
container_start_page 24
container_title Electricity (Basel, Switzerland)
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creator Clemente, Carmine Stefano
Davino, Daniele
Iannone, Immacolato
Loschiavo, Vincenzo Paolo
description Magnetostrictive alloys hold great promise for Energy Harvesting applications due to their inherent durability. However, their implementation often results in usable voltage ranges that fall significantly below common electronic standards like 1.6, 3.3, and 5 volts. Consequently, the utilization of electronic circuits becomes essential to amplify the voltage and enhance energy conversion efficiency. Over the past few decades, numerous conversion techniques have been devised for other intelligent materials, such as piezoelectrics, some of which have even made their way into commercial products. Surprisingly, there is a dearth of specialized techniques, if not a complete absence, tailored to magnetostrictive devices. Among potential solutions, a suitable AC–DC Boost converter stands out as a highly promising candidate for addressing this challenge, but this solution has never been fully characterized. Then, this paper presents thorough experimental validations of such a converter, driven by a real-time Arduino board equipped to measure source time periods and operate under various conditions. We present several cases demonstrating the circuit’s substantial potential for enhancing energy harvesting from magnetostrictive materials.
doi_str_mv 10.3390/electricity5010002
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subjects AC–DC boost
Arduino
Design
Efficiency
Energy
energy harvesting
magnetostrictive materials
title Experimental Characterization of an AC–DC Boost for Energy Harvesting Device Based on Magnetostrictive Materials
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