Design, development and testing of a wearable hybrid energy harvester for sustainable gadgets

This research paper presents the design, development and testing of a novel wearable hybrid energy harvester (WH-EH) aimed at powering sustainable gadgets. By harnessing energy using both electromagnetic and piezoelectric transduction mechanisms to capture ambient mechanical energy from human body m...

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Published inAdvanced Sensor and Energy Materials Vol. 4; no. 1; p. 100137
Main Authors Alsaad, Abdulla, Ahmad, Iftikhar, Aawan, Adel, Abdelrhman, Ahmed M., Khan, Wajid
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.03.2025
Elsevier
Subjects
Electromagnetic
Energy harvesting
Piezoelectric
Sustainable gadgets
Vibration
Wearable devices
Electromagnetic
Vibration
Sustainable gadgets
Energy harvesting
Wearable devices
Piezoelectric
Online AccessGet full text

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Abstract This research paper presents the design, development and testing of a novel wearable hybrid energy harvester (WH-EH) aimed at powering sustainable gadgets. By harnessing energy using both electromagnetic and piezoelectric transduction mechanisms to capture ambient mechanical energy from human body motion, this device offers a versatile solution to the growing demand for portable and renewable energy. The paper details the integration of both mechanisms into a single device that fits in human shoes and the practical implications of deploying such technology in everyday gadgets. The WH-EH comprised of 3D printed frame, a cantilever beam made up of stainless steel, two permanent neodymium magnets residing at the tip of the cantilever beam, two printed circuit board-based micro planar coils that were fixed to the top and bottom of the 3D printed frame. Through rigorous testing, the WH-EH has demonstrated significant potential of producing maximum a power of 577 μW which can help in reducing the reliance on traditional power sources and advancing the frontier of wearable technology. Energy harvesters like WH-EH are pivotal in advancing the sustainability of wearable gadgets, diminishing the dependence on traditional battery sources. These innovations not only strengthen the longevity and eco-friendliness of personal electronics but also align with global sustainable development goals, particularly in the energy and environmental sectors. The progression of such energy harvesters marks a crucial milestone in the ongoing integration of renewable energy practices into daily electrical applications.
AbstractList This research paper presents the design, development and testing of a novel wearable hybrid energy harvester (WH-EH) aimed at powering sustainable gadgets. By harnessing energy using both electromagnetic and piezoelectric transduction mechanisms to capture ambient mechanical energy from human body motion, this device offers a versatile solution to the growing demand for portable and renewable energy. The paper details the integration of both mechanisms into a single device that fits in human shoes and the practical implications of deploying such technology in everyday gadgets. The WH-EH comprised of 3D printed frame, a cantilever beam made up of stainless steel, two permanent neodymium magnets residing at the tip of the cantilever beam, two printed circuit board-based micro planar coils that were fixed to the top and bottom of the 3D printed frame. Through rigorous testing, the WH-EH has demonstrated significant potential of producing maximum a power of 577 μW which can help in reducing the reliance on traditional power sources and advancing the frontier of wearable technology. Energy harvesters like WH-EH are pivotal in advancing the sustainability of wearable gadgets, diminishing the dependence on traditional battery sources. These innovations not only strengthen the longevity and eco-friendliness of personal electronics but also align with global sustainable development goals, particularly in the energy and environmental sectors. The progression of such energy harvesters marks a crucial milestone in the ongoing integration of renewable energy practices into daily electrical applications.
ArticleNumber 100137
Author Aawan, Adel
Abdelrhman, Ahmed M.
Alsaad, Abdulla
Ahmad, Iftikhar
Khan, Wajid
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Issue 1
Keywords Electromagnetic
Vibration
Sustainable gadgets
Energy harvesting
Wearable devices
Piezoelectric
Language English
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Snippet This research paper presents the design, development and testing of a novel wearable hybrid energy harvester (WH-EH) aimed at powering sustainable gadgets. By...
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elsevier
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StartPage 100137
SubjectTerms Electromagnetic
Energy harvesting
Piezoelectric
Sustainable gadgets
Vibration
Wearable devices
Title Design, development and testing of a wearable hybrid energy harvester for sustainable gadgets
URI https://dx.doi.org/10.1016/j.asems.2025.100137
https://doaj.org/article/a4cdb057cac44e0ab6f14e748c0fd595
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