期刊
NANO RESEARCH
卷 16, 期 5, 页码 6933-6939出版社
TSINGHUA UNIV PRESS
DOI: 10.1007/s12274-023-5476-6
关键词
charge excitation; superstructure; vibration energy; volume charge density; resonant frequency
Efficiently converting random vibration energy into electricity is significant for local power supply in the internet of things. However, the conversion efficiency of energy harvesters is limited by their intrinsic frequency. In this study, a multi-layered, wavy super-structured triboelectric nanogenerator (SS-TENG) is designed to improve output performance through charge excitation. The SS-TENG, with a steel sheet acting as both an electrode and a supporter, achieves a high volume charge density and widened resonant frequency range. It can sustainably drive sensors by harvesting vibration energy, providing an effective strategy for energy harvesting and frequency response broadening.
Efficiently converting the random vibration energy widely existed in human activities and natural environments into electricity is significant to the local power supply of sensor nodes in the internet of things. However, the conversion efficiency of energy harvester is relatively low due to the limitation of device's intrinsic frequency. In this work, a multi -layered, wavy super-structuredtriboelectric nanogenerator (SS-TENG) is designed, whose output performances can be greatly promoted by combining the charge excitation mechanism. The steel sheet acts not only as an electrode but also as a supporter for the overall frame of SSTENG, which effectively improves the space utilization rate and results in a volume charge density up to 129 mC.m-a. In addition, the resonant frequency width of the SS-TENG can be widened by changing the parameters of the superstructure. For demonstration, the SS-TENG can sustainably drive two temperature and humidity sensors in parallel by harvesting vibration energy. This work may provide an effective strategy for harvesting vibration energy and broadening frequency response.
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