实现完全自供电远距离无线传感的高性能磁性质量增强型三电-电磁混合振动能量收集器

Ziyue Xi, Hongyong Yu, Hengxu Du, Hengyi Yang, Yawei Wang, Mengyuan Guan, Zhaoyang Wang, Hao Wang, Taili Du, Minyi Xu
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摘要

无线传感器网络在各个领域都发挥着重要作用,而通过收集未使用的机械振动能来构建完全自供电的无线传感器网络则大有可为。本文提出了一种磁性质量增强三电电磁混合纳米发电机(MM-HNG),用于采集机械振动能。附加磁体产生磁场,用于电磁发电。附加质量可有效增加膜的振幅,从而提高 MM-HNG 的输出性能。MM-HNG 中 TENG 的峰值功率密度达到 380.4 W m-3,而 EMG 的峰值功率密度达到 736 W m-3,可为 0.1 F 的电容器快速充电。此外,还构建了一个完全自供电的无线传感系统,其中集成了微控制器单元(MCU),用于检测和处理各种传感参数并控制无线传输。该系统具有传输速度快、传输距离远(达 1 公里)的特点,其有效性已在实际船舶上的实际应用中得到验证。结果表明,MM-HNG 可广泛应用于各种物联网(IoT)场景,包括智能机械、智能交通和智能工厂。
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High Performance Magnetic Mass‐Enhanced Triboelectric‐Electromagnetic Hybrid Vibration Energy Harvester Enabling Totally Self‐Powered Long‐Distance Wireless Sensing
Wireless sensor networks play a significant role in various fields, and it is promising to construct a totally self‐powered wireless sensor network by harvesting unused mechanical vibration energy. Here, a magnetic mass‐enhanced triboelectric‐electromagnetic hybrid nanogenerator (MM‐HNG) is proposed for harvesting mechanical vibration energy. The additional magnets generate magnetic fields for electromagnetic power generation. As an additional mass effectively increases the membrane's amplitude, thereby enhancing the output performance of the MM‐HNG. The peak power density of TENG in the MM‐HNG reaches 380.4 W m−3, while the peak power density of EMG achieves 736 W m−3, which can charge a 0.1 F capacitor rapidly. In addition, a totally self‐powered wireless sensing system is constructed, with the integrated microcontroller unit (MCU), which detects and processes various sensing parameters and controls wireless transmission. The system features rapid transmission speeds and an extensive transmission range (up to 1 km), and its effectiveness has been validated in a practical application aboard an actual ship. The results illustrate the MM‐HNG's broad applicability across various Internet of Things (IoT) scenarios, including smart machinery, smart transportation, and smart factories.
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