Journal
NANO ENERGY
Volume 113, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.nanoen.2023.108521
Keywords
Triboelectric nanogenerator; Unidirectional charge-supplying flutter; Enhanced current output performance; Electrostatic discharge; Air breakdown
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This paper proposes a unidirectional charge-supplying flutter TENG (UCSF-TENG) that converts mechanical energy into electricity with high peak/RMS current output performance. The UCSF-TENG achieved a peak current of 5.9 A and an RMS current of 20 mA by using a rectifier diode and unique fluttering device design. The electrical output mechanism of the UCSF-TENG was analyzed based on mechanical fluttering motion analysis and achieved an average power of 109 mW through structural optimization. The UCSF-TENG can charge a supercapacitor, power commercial lamps, and operate sensor arrays continuously, demonstrating its potential for boosting TENG output current performance while maintaining integrability and portability.
The triboelectric nanogenerator (TENG) is an innovative technology that converts ambient mechanical energy into electricity based on electrostatic induction and triboelectrification. However, the TENG has an inherent critical problem of low peak and root mean square (RMS) output current due to its high internal impedance. Herein, we propose a unidirectional charge-supplying flutter TENG (UCSF-TENG), which exhibits highly enhanced peak/RMS current output performance. By leveraging just one rectifier diode and distinctive fluttering device design, the UCSF-TENG achieved a peak current of 5.9 A and an RMS current of 20 mA. The electrical output generation mechanism of the UCSF-TENG was systemically analyzed based on the mechanical fluttering motion analysis using a high-speed camera. In addition, the UCSF-TENG was structurally optimized via mechanical and electrical analyses for various design factors, through which it achieved an average power of 109 mW. Benefiting from such high output performance, the UCSF-TENG can successfully charge a supercapacitor of 0.22 F, power 108-W commercial lamps, and operate 12 commercial sensor arrays continuously. This work provides a promising strategy for boosting the output current performance of the TENG while maintaining integrability and portability.
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