Multi‐Parameters Self‐Powered Monitoring via Triboelectric and Electromagnetic Mechanisms for Smart Transmission Lines

Zhang, Xiaosong; Wang, Jianlong; Zhai, Shijie; Yu, Yang; Cheng, Xiaojun; Li, Hengyu; Wang, Zhong Lin; Cheng, Tinghai

doi:10.1002/aenm.202401710

Advanced Energy Materials

2024

DOI: 10.1002/aenm.202401710

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Multi‐Parameters Self‐Powered Monitoring via Triboelectric and Electromagnetic Mechanisms for Smart Transmission Lines

Xiaosong Zhang,

Jianlong Wang,

Shijie Zhai

et al.

Abstract: The application of distributed sensors in smart transmission lines to replace traditional inspection methods is an inevitable trend. Currently, the challenge of energy supply for sensors serves as a bottleneck that hinders the intelligent development of transmission lines. This paper focuses on the application of self‐powered inspection technology based on triboelectric and electromagnetic mechanisms in transmission lines. It proposes a self‐powered temperature and vibration monitoring and warning system (STV‐… Show more

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Cited by 4 publications

References 40 publications

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Whole Life Cycle Monitoring of Landslide Deep Deformation via Triboelectric Nanogenerator

Liu,

Bi,

Zhang

et al. 2024

Adv Funct Materials

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The displacement monitoring of the slow landslide deep deformation is an important part of the landslide early warning system. However, the traditional energy supply mode of depth sensors limits the large‐scale landslide monitoring of the whole life cycle. Therefore, it is necessary to realize self‐powered monitoring for deep deformation at extremely low speed. Herein, an extremely low‐speed triboelectric tilt sensor (ELS‐TTS) is proposed for whole life cycle monitoring of landslide deep deformation without an energy supply. The triboelectric self‐sensing unit based on the triboelectric nanogenerator (TENG) and the instantaneous structure of gravity energy storage is designed. A prototype of ELS‐TTS with a resolution of 0.075° is fabricated and experimented. ELS‐TTS can stably monitor extremely low speeds of below 0.0257° s−1 in different environments and motion states, and the monitoring error is less than 0.13°. Furthermore, a real‐time monitoring system for deep landslides based on a multi‐level forewarning method is proposed to realize the whole life cycle monitoring of landslides and the multi‐level forewarning of dangerous states. This work further promotes the development of TENG in the fields of natural disaster prevention and structural health monitoring.

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Whole Life Cycle Monitoring of Landslide Deep Deformation via Triboelectric Nanogenerator

Liu,

Bi,

Zhang

et al. 2024

Adv Funct Materials

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Hybrid Nanogenerator Harvesting Electric‐Field and Wind Energy for Self‐Powered Sensors on High‐Voltage Transmission Lines

Huang,

Hu,

Wang

et al. 2024

Adv Funct Materials

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Triboelectric nanogenerators (TENGs) show potential for powering distributed sensors in the smart grids. However, most studies on TENG's applications for energy harvesting from transmission lines primarily focus on vibration and wind energy, neglecting the abundant electric‐field energy from transmission systems. This study proposes a triboelectric‐electrostatic hybrid energy harvester (TEHEH) that integrates a triboelectric nanogenerator with an electric‐field energy harvester (EFEH) to simultaneously capture wind energy and electric‐field energy from the surroundings of transmission lines. The TENG and EFEH can generate open‐circuit voltages of 1280 and 2800 V, respectively, with output powers of 14.3 and 28.9 mW. Hybrid energy harvesting achieves an average power of 6.1 times that of TENG and 2.4 times that of EFEH, demonstrating its superiority. The dual‐channel energy management circuit, utilizing a gas discharge tube and the LTC‐3588, enables the hybrid nanogenerator to effectively power a wireless sensor node, demonstrating its practicality in the complex environments of power transmission lines. This work offers robust technical support for the development of self‐powered monitoring devices on high‐voltage transmission systems.

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Harvesting Broadband Breeze Vibration Energy via Elastic Bistable Triboelectric Nanogenerator for In Situ, Self‐Powered Monitoring of Power Transmission Lines

Wang,

Zhang,

Zhang

et al. 2024

Advanced Energy Materials

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Triboelectric nanogenerator (TENG), as a new technique for energy capture, has unique advantages in harvesting high‐entropy energy. In view of the wind‐induced vibration characteristics of power transmission lines, the symmetric elastic bistable triboelectric nanogenerator (EB‐TENG) is introduced in this work. The core component of the EB‐TENG is the elastic bistable cantilever beam structure, which is designed by introducing an elastic perturbation structure to the conventional cantilever beam. This beam results in several sub‐resonance frequencies in addition to the natural frequencies, which broadens the frequency band of the EB‐TENG. In addition, the EB‐TENG adopts a symmetrical cantilever beam to ensure effective harvesting of vibration energy, even in situations of self‐tilting and external tilting vibration. The experimental outcomes confirm that the EB‐TENG can significantly harvest vibration energy in the 7–60 Hz frequency range and delivers the maximum peak power of 2.846 mW, which meets the major vibration frequency range of power transmission lines under the action of breeze. Finally, self‐powered strategy based on EB‐TENG online monitoring devices (such as tower obstruction lights, temperature and humidity sensors, and line high temperature wireless alarms) is constructed. This work helps promote the application of in‐situ self‐powered monitoring based on TENG in smart transmission lines.

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Multi‐Parameters Self‐Powered Monitoring via Triboelectric and Electromagnetic Mechanisms for Smart Transmission Lines

Cited by 4 publications

References 40 publications

Whole Life Cycle Monitoring of Landslide Deep Deformation via Triboelectric Nanogenerator

Whole Life Cycle Monitoring of Landslide Deep Deformation via Triboelectric Nanogenerator

Hybrid Nanogenerator Harvesting Electric‐Field and Wind Energy for Self‐Powered Sensors on High‐Voltage Transmission Lines

Harvesting Broadband Breeze Vibration Energy via Elastic Bistable Triboelectric Nanogenerator for In Situ, Self‐Powered Monitoring of Power Transmission Lines

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