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风电变流技术
★ 5.0
可持续自感知铁路风之花密封混合纳米发电机
Sustainable self-sensing railway wind-blossom with sealed hybrid nanogenerator
| 作者 | Hao Wang · Tengfei Liu · Zutao Zhang · Dabing Luo · Bendong Xiong · Congcong Zhang · Long Wang · Chengliang Fan |
| 期刊 | Applied Energy |
| 出版日期 | 2025年1月 |
| 卷/期 | 第 392 卷 |
| 技术分类 | 风电变流技术 |
| 相关度评分 | ★★★★★ 5.0 / 5.0 |
| 关键词 | Designing [wind energy](https://www.sciencedirect.com/topics/physics-and-astronomy/windpower-utilization "Learn more about wind energy from ScienceDirect's AI-generated Topic Pages") harvester for Barrier: protecting harvesting and sensing. |
语言:
中文摘要
摘要 智能铁路的发展对先进的铁路物联网(IoRT)系统提出了迫切需求,其中主要挑战之一是为偏远的IoRT节点提供持续电力供应。一种可行方案是在强风区域将风能收集装置集成于风屏障中,从而同时实现防风与能量采集功能。本研究提出了一种名为“风之花”(Wind-Blossom, WB)的风能采集装置,将其应用于铁路屏障中,兼具防风、能量采集和风速自感知功能,旨在构建可长期运行的铁路状态监测IoRT系统。WB的设计采用阿基米德螺旋转子与风透镜结构,以实现高效的风能采集与风力削弱效果。该装置集成了电磁与摩擦电纳米发电机,用于发电及自感知功能。通过结合仿真分析与田口法(Taguchi's analysis method)对转子结构进行优化设计,并据此制备出高效原型样机。风洞实验结果显示其输出功率达3.63 W,均方根电压达143 V,验证了其作为稳定电源的潜力。基于摩擦电信号开发了自感知风速监测系统,实现了精确的实时风速监测。在恶劣环境条件下的测试证实了该装置的可靠性。此外,在多个地点部署并运行了多日,成功构建了一个长期、广域的IoRT系统。本研究展示了风之花在防风保护、能量采集、风速监测以及铁路物联网应用中的多功能潜力,为其商业化应用奠定了基础。
English Abstract
Abstract The development of smart railways demands advanced Internet of Railway Things (IoRT) systems, with a major challenge being the power supply remote IoRT nodes. One approach is to integrate wind energy harvesters into wind barriers in high-wind regions, achieving both wind protection and energy harvesting . This study introduces Wind-Blossom (WB), a wind energy harvester in railway barriers for wind protection, energy harvesting , and wind self-sensing. The goal is to enable a long-term IoRT system for monitoring railway conditions. The WB design features an Archimedean spiral rotor and wind-lens for efficient wind energy harvesting and wind mitigation. It incorporates electromagnetic and triboelectric nanogenerators for power generation and self-sensing. A combination of simulation and Taguchi's analysis method was used to optimize the rotor design, guiding the fabrication of an efficient prototype. Wind tunnel tests showed an output power of 3.63 W and an RMS voltage of 143 V, validating its potential as a power source. A self-sensing wind speed monitoring system was developed based on triboelectric signals, providing accurate real-time monitoring. The device's reliability was confirmed under harsh conditions. A long-term wide-area IoRT system was implemented across multiple locations for several days. This study demonstrates the multifunctional potential of Wind-Blossom for wind protection, energy harvesting, wind speed monitoring, and IoRT, paving the way for commercialization.
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SunView 深度解读
该铁路风能采集与自感知技术对阳光电源新能源基础设施布局具有启发意义。其混合发电机制(电磁+摩擦纳米发电)可借鉴至光储充一体站的微能量采集系统,为偏远监测节点供电。风速自感知原理可应用于iSolarCloud平台的环境监测模块,提升风光互补电站的预测性维护能力。该多功能集成思路与阳光电源ST储能系统的模块化设计理念契合,可探索交通基础设施分布式能源解决方案,拓展充电桩网络在高速铁路沿线的智能化部署场景。