Advanced aerodynamics-driven energy harvesting leveraging galloping-flutter synergy
Flow-induced vibrations (FIVs) serve as the fundamental principle of non-rotary wind energy harvesting. However, nanogenerators relying on a single FIV effect remain constrained by insufficient breeze energy conversion efficiency. In this paper, we propose a novel galloping-flutter coupled nanogener...
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sg-ntu-dr.10356-1822652025-01-20T02:57:41Z Advanced aerodynamics-driven energy harvesting leveraging galloping-flutter synergy Dong, Liwei Hu, Guobiao Tang, Qian Zhao, Chaoyang Yang, Fan Yang, Yaowen School of Civil and Environmental Engineering Engineering Flow-induced vibration Triboelectric Flow-induced vibrations (FIVs) serve as the fundamental principle of non-rotary wind energy harvesting. However, nanogenerators relying on a single FIV effect remain constrained by insufficient breeze energy conversion efficiency. In this paper, we propose a novel galloping-flutter coupled nanogenerator (GFNG) that leverages the synergistic interaction between these two aerodynamic phenomena, to achieve high performance across broad wind speed bandwidth. A galloping-flutter coupled mechanism (GFM) is implemented using a multifunctional flexible beam that integrates a galloping piezoelectric energy harvester (GPEH) and a fluttering triboelectric nanogenerator (FTENG). Through meticulous optimization, it significantly enhances the average electrical output of the FTENG by up to six times at low wind speeds below 6 m s−1, by intensifying the triboelectric contact behavior through galloping-induced beam oscillations. The GFNG demonstrates a maximum average power of 6.3 mW across wind speeds from 1.4 to 10 m s−1, along with a remarkable power density of 7.1 W m−2 of the enhanced FTENG at 10 m s−1, enabling the lighting of 508 LEDs and stable power supply for wireless sensor nodes (WSNs). This study offers new insights into designing high-performance aerodynamics-driven nanogenerators by harnessing multiple FIV synergistic effects, broadening the potential for intelligent wind energy applications. Nanyang Technological University This research is sponsored by the National Natural Science Foundation of China (Grant No. 52305135), the National Natural Science Foundation of China (Grant No. 12202276), the Guangzhou Municipal Science and Technology Project (Grant No. 2023A03J0011), Guangdong Provincial Key Lab of Integrated Communication, Sensing and Computation for ubiquitous Internet of Things (No. 2023B1212010007), NTU grant 020671-00001, the China Scholarship Council (Grant No. 202206260157), and innovative re-search team of high-level local universities in Shanghai. 2025-01-20T02:57:41Z 2025-01-20T02:57:41Z 2024 Journal Article Dong, L., Hu, G., Tang, Q., Zhao, C., Yang, F. & Yang, Y. (2024). Advanced aerodynamics-driven energy harvesting leveraging galloping-flutter synergy. Advanced Functional Materials, 2414324-. https://dx.doi.org/10.1002/adfm.202414324 1616-301X https://hdl.handle.net/10356/182265 10.1002/adfm.202414324 2-s2.0-85209747745 2414324 en 020671-00001 Advanced Functional Materials © 2024 Wiley-VCH GmbH. All rights reserved. |
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NTU Library |
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Engineering Flow-induced vibration Triboelectric |
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Engineering Flow-induced vibration Triboelectric Dong, Liwei Hu, Guobiao Tang, Qian Zhao, Chaoyang Yang, Fan Yang, Yaowen Advanced aerodynamics-driven energy harvesting leveraging galloping-flutter synergy |
| description |
Flow-induced vibrations (FIVs) serve as the fundamental principle of non-rotary wind energy harvesting. However, nanogenerators relying on a single FIV effect remain constrained by insufficient breeze energy conversion efficiency. In this paper, we propose a novel galloping-flutter coupled nanogenerator (GFNG) that leverages the synergistic interaction between these two aerodynamic phenomena, to achieve high performance across broad wind speed bandwidth. A galloping-flutter coupled mechanism (GFM) is implemented using a multifunctional flexible beam that integrates a galloping piezoelectric energy harvester (GPEH) and a fluttering triboelectric nanogenerator (FTENG). Through meticulous optimization, it significantly enhances the average electrical output of the FTENG by up to six times at low wind speeds below 6 m s−1, by intensifying the triboelectric contact behavior through galloping-induced beam oscillations. The GFNG demonstrates a maximum average power of 6.3 mW across wind speeds from 1.4 to 10 m s−1, along with a remarkable power density of 7.1 W m−2 of the enhanced FTENG at 10 m s−1, enabling the lighting of 508 LEDs and stable power supply for wireless sensor nodes (WSNs). This study offers new insights into designing high-performance aerodynamics-driven nanogenerators by harnessing multiple FIV synergistic effects, broadening the potential for intelligent wind energy applications. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Dong, Liwei Hu, Guobiao Tang, Qian Zhao, Chaoyang Yang, Fan Yang, Yaowen |
| format |
Article |
| author |
Dong, Liwei Hu, Guobiao Tang, Qian Zhao, Chaoyang Yang, Fan Yang, Yaowen |
| author_sort |
Dong, Liwei |
| title |
Advanced aerodynamics-driven energy harvesting leveraging galloping-flutter synergy |
| title_short |
Advanced aerodynamics-driven energy harvesting leveraging galloping-flutter synergy |
| title_full |
Advanced aerodynamics-driven energy harvesting leveraging galloping-flutter synergy |
| title_fullStr |
Advanced aerodynamics-driven energy harvesting leveraging galloping-flutter synergy |
| title_full_unstemmed |
Advanced aerodynamics-driven energy harvesting leveraging galloping-flutter synergy |
| title_sort |
advanced aerodynamics-driven energy harvesting leveraging galloping-flutter synergy |
| publishDate |
2025 |
| url |
https://hdl.handle.net/10356/182265 |
| _version_ |
1821833200299671552 |