Failure mechanism and vibration control for tower tube of wind generator under extreme climate
Authors
-
Yang Mingliyang -
Wang Jisheng
-
Meng Wenjun
-
Wang Shoucheng
DOI:
https://doi.org/10.18311/ijprvd/2021/29370Keywords:
Vibration control, tower tube of wind, failure mechanism, extreme climate.Abstract
The wind power tower is sensitive to wind loads with high aspect ratio. The failure characteristics and failure mechanism of the wind turbine tower structure are analyzed under the extreme climate conditions. Based on the principle of tuned mass damper theory, the suspension damper application in wind turbine tower structure is designed. The appropriate typhoon wind speed spectrum is selected. With the finite element software, the 3D model for tower structure is established and the control effect of the damper structure is analyzed. The maximum displacement and acceleration of the structure under extreme climatic conditions are greatly reduced after the suspension tuned mass damper being given. The efficiency of vibration reduction is 80.26% and 54% respectively. The results show that the response of displacement and acceleration for the damper are obviously decreased, which is beneficial to the safety of the tower structure under the extreme climate condition.
Downloads
Metrics
Downloads
Published
How to Cite
Issue
Section
Accepted 2022-01-21
Published 2022-01-21
References
References
Qu Weilian, Wei Wenhui(2010): Analysis and
prevention of collapse process of disaster wind and
wind-induced tall[A]. Proceedings of the 30 Annual
Conference on structural wind engineering in
China[C].
Wang Zhaomin (1994): Research and design of TMD
wind vibration control of TV Tower Structure[J].
Journal of Building Structures, (5):2-13.
Liu Yu, Xu Xu, Zhou Xiaojuan (2009): Dynamic
response and wind vibration control of high-rise
structures under the action of typhoon [J]. Noise and
Vibration Control, (2): 30-34.
Chen Junling, Yang Rongchang (2013): Ball damper in
the wind power generation tower vibration control.
Journal of Tongji University, 41 (8) 1145-1150.
Feng Youquan, Chen Junling (2011): The accelerationinput equivalent wind turbine tower measured
response method [J]. Journal of Shijiazhuang Tiedao
University: Science Edition, 24 (1): 21-24.
Luo Chao, Cao Wensheng. (2013): The impact of
typhoon on the development of China’s offshore wind
power [J]. Energy and Environment. (2):2-3.
Guangling, Tian Jingku (2013): Chang Desheng.
Offshore wind turbine anti typhoon concept design of
[J]. Electric Power Construction. (2): 11-17.
Wu Jincheng, Zhang Rongyan, Zhang Xiuzhi (2010):
Anti-typhoon design of offshore wind turbines [J].
China Engineering Science, 12 (11): 25-31.
Prowell I, Veletzos M, Elgamal Aÿet al.( 2009):
Experimental and numerical scismic response of a 65
kW wind turbine steel tower [J]. Journal of
Earthquake Engineering, 13(8):1172.
Zhang Xiangting (1990): Wind load theory of
engineering structure and wind resistant calculation
manual [M]. Tongji University pres.
Zhang Peixin (2013): Building structure and wind load
[M]. Shanghai Science and Technology Publishing
House.
