Improving the wind energy harvesting performance with double upstream fractal bluff bodies
Improving the wind energy harvesting performance with double upstream fractal bluff bodies
Fossil energy sources are not renewable and the technology to harness wind energy has gained considerable interest. This work proposes a wake galloping energy harvester with upstream fractal structures to promote the efficiency of wind energy harvesting. The dynamic response and energy harvesting performance of a conventional galloping energy harvester (GEH), a vortex-induced vibration energy harvester (VIVEH), a traditional wake galloping energy harvester with single or double upstream cuboids (WGEH-SC, WGEH-DC), and a wake galloping energy harvester with single or double fractal upstream structures (WGEH-SF, WGEH-DF) are evaluated numerically and experimentally. At a wind speed of 5.0 m/s, WGEH-DF increases the maximum root mean square (RMS) voltage from 19.36 V to 39.25 V, indicating an improvement of 102.7 % compared to the VIVEH. Meanwhile, the effects of the positions and windward angles of the upstream bluff bodies are discussed, and the WGEH-DF reaches its maximum average RMS voltage at an angle of 75° and x = 2 cm. It is found that when two fractal bluff bodies are placed upstream, the pressure difference increases on both sides of the downstream bluff body and the structural vibration becomes more violent. By comparing the pressure behind the two cuboids and two fractal bluff bodies, it is demonstrated that the negative pressure behind the fractal bluff bodies is increased. The flow field analysis further explains the aerodynamic mechanism that the fractal bluff bodies placed upstream improve energy harvesting performance.
Fractal structures, Wind energy harvesting, Wake galloping, Vortex induced vibration, Galloping
Zheng, Tianyu
ac3c187c-534b-4a80-99fe-be60cbe2c404
Ren, He
814f60fe-7d9f-490f-9dc5-0d4e3e4e7c79
Zhang, Zhongcai
2f161852-15dd-40e1-9dd7-3aa54512f60e
Li, Haitao
9aff277f-71d7-4c1d-80ea-2281ab495fee
Qin, Weiyang
3d9216e4-d29e-4515-9bc0-44d6d4447492
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
4 December 2024
Zheng, Tianyu
ac3c187c-534b-4a80-99fe-be60cbe2c404
Ren, He
814f60fe-7d9f-490f-9dc5-0d4e3e4e7c79
Zhang, Zhongcai
2f161852-15dd-40e1-9dd7-3aa54512f60e
Li, Haitao
9aff277f-71d7-4c1d-80ea-2281ab495fee
Qin, Weiyang
3d9216e4-d29e-4515-9bc0-44d6d4447492
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Zheng, Tianyu, Ren, He, Zhang, Zhongcai, Li, Haitao, Qin, Weiyang and Yurchenko, Daniil
(2024)
Improving the wind energy harvesting performance with double upstream fractal bluff bodies.
Renewable Energy, 239, [122070].
(doi:10.1016/j.renene.2024.122070).
Abstract
Fossil energy sources are not renewable and the technology to harness wind energy has gained considerable interest. This work proposes a wake galloping energy harvester with upstream fractal structures to promote the efficiency of wind energy harvesting. The dynamic response and energy harvesting performance of a conventional galloping energy harvester (GEH), a vortex-induced vibration energy harvester (VIVEH), a traditional wake galloping energy harvester with single or double upstream cuboids (WGEH-SC, WGEH-DC), and a wake galloping energy harvester with single or double fractal upstream structures (WGEH-SF, WGEH-DF) are evaluated numerically and experimentally. At a wind speed of 5.0 m/s, WGEH-DF increases the maximum root mean square (RMS) voltage from 19.36 V to 39.25 V, indicating an improvement of 102.7 % compared to the VIVEH. Meanwhile, the effects of the positions and windward angles of the upstream bluff bodies are discussed, and the WGEH-DF reaches its maximum average RMS voltage at an angle of 75° and x = 2 cm. It is found that when two fractal bluff bodies are placed upstream, the pressure difference increases on both sides of the downstream bluff body and the structural vibration becomes more violent. By comparing the pressure behind the two cuboids and two fractal bluff bodies, it is demonstrated that the negative pressure behind the fractal bluff bodies is increased. The flow field analysis further explains the aerodynamic mechanism that the fractal bluff bodies placed upstream improve energy harvesting performance.
Text
Fractal_Improving wind EH
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Accepted/In Press date: 30 November 2024
e-pub ahead of print date: 1 December 2024
Published date: 4 December 2024
Keywords:
Fractal structures, Wind energy harvesting, Wake galloping, Vortex induced vibration, Galloping
Identifiers
Local EPrints ID: 498178
URI: http://eprints.soton.ac.uk/id/eprint/498178
ISSN: 0960-1481
PURE UUID: 490fd82b-929e-461b-87a1-e70640969ed5
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Date deposited: 12 Feb 2025 17:31
Last modified: 13 Feb 2025 03:06
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Contributors
Author:
Tianyu Zheng
Author:
He Ren
Author:
Zhongcai Zhang
Author:
Haitao Li
Author:
Weiyang Qin
Author:
Daniil Yurchenko
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