设计、开发和测试一种可穿戴的混合能源采集器

Abdulla Alsaad, Iftikhar Ahmad, Adel Aawan, Ahmed M. Abdelrhman, Wajid Khan
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摘要

本研究报告介绍了一种新型可穿戴混合能源采集器(WH-EH)的设计、开发和测试,旨在为可持续发展的小工具提供动力。通过使用电磁和压电转导机制来利用能量从人体运动中捕获环境机械能,该设备为便携式和可再生能源日益增长的需求提供了一个通用的解决方案。这篇论文详细介绍了将这两种机制集成到一个适合人类鞋子的单一设备中,以及在日常设备中部署这种技术的实际意义。WH-EH由3D打印框架、不锈钢悬臂梁、位于悬臂梁尖端的两个永久钕磁铁、固定在3D打印框架顶部和底部的两个基于印刷电路板的微平面线圈组成。经过严格的测试,WH-EH显示出最大功率为577 μW的巨大潜力,这有助于减少对传统电源的依赖,并推进可穿戴技术的前沿。像WH-EH这样的能量采集器对于提高可穿戴设备的可持续性至关重要,减少了对传统电池的依赖。这些创新不仅增强了个人电子产品的使用寿命和生态友好性,而且符合全球可持续发展目标,特别是在能源和环境领域。这种能量收集器的进展标志着可再生能源实践融入日常电力应用的一个重要里程碑。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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 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.
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