Modular Environment for Development and Characterization of Tunable Energy Harvesting Systems

Electronics ETF Pub Date : 2018-08-08 DOI:10.7251/ELS1721053C

Javier Casatorres-Aguero, O. Nieto-Taladriz

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Abstract

This paper presents the design and development process for an electromagnetic self-tuned vibrational energy harvester prototype. Most state-of-the-art publications present non-tunable or manually tunable vibrational energy harvesters, even the market provides some commercial models of these categories for specific applications. On the other hand, self-tuned energy harvesters are yet rarely seen on the research community. The presented work follows the complete process of designing a prototype to work as a second-order oscillatory system in the form of a cantilever. Three different approaches to tune the resonant frequency of the harvester were considered, each based in changing a property of the cantilever that modifies its resonant frequency. Firstly, it was changed the effective vibrating length of the cantilever. Secondly it was introduced an axial load to the system. Then, the use of a dual cantilever wishbone structure was studied as it allows changing the equivalent stiffness of the system. Finally a prototype based on the first strategy was built and tested, including control algorithms for the maximum electrical energy harvesting point tracking which are presented.

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可调能量收集系统的模块化开发与表征环境

介绍了一种电磁自调谐振动能量采集器样机的设计与研制过程。大多数最先进的出版物都展示了不可调谐或手动可调谐的振动能量采集器，甚至市场也为特定应用提供了这些类别的一些商业模型。另一方面，自调谐能量收集器在研究界还很少见到。所呈现的工作遵循设计原型的完整过程，以悬臂形式作为二阶振荡系统工作。考虑了三种不同的方法来调整收割机的谐振频率，每一种方法都是基于改变悬臂梁的特性来改变其谐振频率。首先，改变悬臂梁的有效振动长度;其次，引入轴向载荷。然后，研究了双悬臂梁叉骨结构的使用，因为它允许改变系统的等效刚度。最后建立了基于第一种策略的原型并进行了测试，给出了最大电能收集点跟踪的控制算法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Electronics ETF

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