A simulation study on the contact‐separation triboelectric nano‐generator for magnetic energy harvester

IF 3.8 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC IET Nanodielectrics Pub Date : 2024-04-11 DOI:10.1049/nde2.12079
Yibing Zhang, Fenghui Li, Yagang Wang, Shanlin Tong, Yuhao Li, Xuhui Li, Wu Lu, Yongsheng Liu
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Abstract

Transmission lines and outdoor substations are replete with various forms of micro energy such as wind energy, solar energy, and electromagnetic energy. There exists micro energy in the forms of mechanical vibrations, temperature differences, and humidity in power distribution equipment. Innovative sensor or monitoring methods are needed to maintain the stability and digitisation of the grid. Unfortunately, there is limited study on the power supply of these sensor systems. Triboelectric nanogenerators, which are environmentally friendly and use simple materials, show excellent performance in environmental nano‐energy collection and self‐powered online monitoring. Therefore, environmental energy collection systems based on triboelectric nanogenerators are one of the selected methods to convert magnetic energy in the magnetic field into electrical energy. A model structure was designed using the contact separation mode, which is one of the four working modes of triboelectric nanogenerators, based on the strength of the magnetic field in the environment. This structure mainly consists of the friction layer, electrodes for current conduction, and connected loads. The research includes a comparison of four inherent electrical outputs of the triboelectric nanogenerator: open‐circuit voltage, short‐circuit current, capacitance, and power. COMSOL Multiphysics software was used for all modelling and simulation of the TENG. This software was used for the design, material selection, and static study of the TENG. When the relative dielectric constant was fixed, the output voltage reached and the energy reached . Overall, ideal reference can be provided for researchers studying power supply issues for sensors in complex magnetic field situations and help them design high‐performance TENGs.
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用于磁能收集器的接触分离式三电纳米发电机的模拟研究
输电线路和户外变电站充满了各种形式的微能量,如风能、太阳能和电磁能。配电设备中也存在机械振动、温差和湿度等形式的微能量。需要创新的传感器或监测方法来保持电网的稳定性和数字化。遗憾的是,有关这些传感器系统供电的研究十分有限。三电纳米发电机环保且材料简单,在环境纳米能量收集和自供电在线监测方面表现出色。因此,基于三电纳米发电机的环境能量收集系统是将磁场中的磁能转化为电能的首选方法之一。接触分离模式是三电纳米发电机的四种工作模式之一,根据环境中的磁场强度设计了一种模型结构。该结构主要由摩擦层、用于传导电流的电极和连接负载组成。研究包括比较三电纳米发电机的四种固有电气输出:开路电压、短路电流、电容和功率。TENG 的所有建模和仿真都使用了 COMSOL Multiphysics 软件。该软件用于 TENG 的设计、材料选择和静态研究。当相对介电常数固定时,输出电压达到.,能量达到.。总之,研究人员在研究复杂磁场情况下传感器的电源问题时,可以提供理想的参考,帮助他们设计高性能的 TENG。
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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来源期刊
IET Nanodielectrics
IET Nanodielectrics Materials Science-Materials Chemistry
CiteScore
5.60
自引率
3.70%
发文量
7
审稿时长
21 weeks
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