Electrostatic Energy Harvester Design using In-plane Gap Closing and In-plane Overlap Varying Mechanisms

2019 International Conference on Robotics and Automation in Industry (ICRAI) Pub Date : 2019-10-01 DOI:10.1109/ICRAI47710.2019.8967362

Umar Jamil, R. I. Shakoor

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引用次数: 2

Abstract

Demand of energy is increasing day by day with the development of new technologies. Renewable energy resources are mostly focused nowadays to harvest energy. Mostly vibration-based energy harvesters include Electrostatic, Electromagnetic and Piezoelectric energy harvesting mechanisms. Electrostatic energy harvester (EEH) is preferable as compared to other two mechanisms due to low cost and possibility of integration on small scale. Electrostatic energy harvesting would be possible using in-plane and out-of-plane capacitive mechanisms. In-plane capacitive mechanisms include gap closing, overlap varying, full plate varying and patterned varying mechanisms. In this research paper, combined in-plane gap closing (IPGC) and in-plane overlap varying (IPOV) mechanisms have been used to design an energy harvester on small scale. IntelliSuite® software is used for design and simulation purpose. Electrostatic, frequency and electromechanical analysis have been performed. Comparison between other relevant work is also presented with respect to power density.

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基于面内间隙闭合和面内重叠变化机构的静电能量采集器设计

随着新技术的发展，对能源的需求日益增加。可再生能源目前主要集中在获取能源上。大多数基于振动的能量收集器包括静电、电磁和压电能量收集机制。与其他两种机制相比，静电能量收集器(EEH)由于成本低和小规模集成的可能性而更可取。静电能量收集可以使用面内和面外电容机构。面内电容机构包括间隙闭合机构、重叠变化机构、全板变化机构和图案变化机构。本文采用面内间隙闭合(IPGC)和面内重叠变化(IPOV)联合机制设计了一种小型能量采集器。IntelliSuite®软件用于设计和仿真目的。进行了静电、频率和机电分析。本文还就功率密度与其他相关工作进行了比较。

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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2019 International Conference on Robotics and Automation in Industry (ICRAI)

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