For large-scale offshore wind turbine rotating blades (NREL 5MW), the theoretical model of vibration due to fluid-structure interaction (FSI) is established, and the basic equations for modal analysis are given. Based on ANSYS workbench platform, the blade modal characteristics at different rotating speeds are analyzed, and further research on dynamic stability is carried out. The results indicate that the FSI and the blade rotation have a great influence on modal frequencies, which increase with the rotating speed of the blade under FSI. When the frequency of the periodic wind speed is close to the first-order natural frequency of the blade, both the maximum flapping displacement and the maximum von Mises stress increase with time, and the vibration divergence appears. At the safe tower clearance of 4.50 m, the critical value of the blade maximum von Mises stress shows a linear upward trend with the increase of the elasticity modulus, which provides technical references for optimization design and safe operation of wind turbine blades.
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October 2018
Research-Article
Analysis of Mode and Dynamic Stability for Wind Turbine Rotating Blades
Jian-Ping Zhang,
Jian-Ping Zhang
College of Energy and Mechanical Engineering,
Shanghai University of Electric Power,
Shanghai 200090, China;
Shanghai University of Electric Power,
Shanghai 200090, China;
Shanghai Key Laboratory of Materials Protection
and Advanced Materials in Electric Power,
Shanghai 200090, China
e-mail: jpzhanglzu@163.com
and Advanced Materials in Electric Power,
Shanghai 200090, China
e-mail: jpzhanglzu@163.com
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Zhen Gong,
Zhen Gong
College of Energy and Mechanical Engineering,
Shanghai University of Electric Power,
Shanghai 200090, China
e-mail: 13696766267@163.com
Shanghai University of Electric Power,
Shanghai 200090, China
e-mail: 13696766267@163.com
Search for other works by this author on:
Liang Guo,
Liang Guo
College of Energy and Mechanical Engineering,
Shanghai University of Electric Power,
Shanghai 200090, China
e-mail: guozai.1989@163.com
Shanghai University of Electric Power,
Shanghai 200090, China
e-mail: guozai.1989@163.com
Search for other works by this author on:
Helen Wu
Helen Wu
School of Computing, Engineering and
Mathematics,
Western Sydney University,
Sydney 2751, Australia
e-mail: Helen.Wu@westernsydney.edu.au
Mathematics,
Western Sydney University,
Sydney 2751, Australia
e-mail: Helen.Wu@westernsydney.edu.au
Search for other works by this author on:
Jian-Ping Zhang
College of Energy and Mechanical Engineering,
Shanghai University of Electric Power,
Shanghai 200090, China;
Shanghai University of Electric Power,
Shanghai 200090, China;
Shanghai Key Laboratory of Materials Protection
and Advanced Materials in Electric Power,
Shanghai 200090, China
e-mail: jpzhanglzu@163.com
and Advanced Materials in Electric Power,
Shanghai 200090, China
e-mail: jpzhanglzu@163.com
Zhen Gong
College of Energy and Mechanical Engineering,
Shanghai University of Electric Power,
Shanghai 200090, China
e-mail: 13696766267@163.com
Shanghai University of Electric Power,
Shanghai 200090, China
e-mail: 13696766267@163.com
Liang Guo
College of Energy and Mechanical Engineering,
Shanghai University of Electric Power,
Shanghai 200090, China
e-mail: guozai.1989@163.com
Shanghai University of Electric Power,
Shanghai 200090, China
e-mail: guozai.1989@163.com
Helen Wu
School of Computing, Engineering and
Mathematics,
Western Sydney University,
Sydney 2751, Australia
e-mail: Helen.Wu@westernsydney.edu.au
Mathematics,
Western Sydney University,
Sydney 2751, Australia
e-mail: Helen.Wu@westernsydney.edu.au
1Corresponding author.
Contributed by the Ocean, Offshore, and Arctic Engineering Division of ASME for publication in the JOURNAL OF OFFSHORE MECHANICS AND ARCTIC ENGINEERING. Manuscript received June 22, 2017; final manuscript received March 8, 2018; published online May 2, 2018. Assoc. Editor: Zhen Gao.
J. Offshore Mech. Arct. Eng. Oct 2018, 140(5): 051902 (10 pages)
Published Online: May 2, 2018
Article history
Received:
June 22, 2017
Revised:
March 8, 2018
Citation
Zhang, J., Gong, Z., Guo, L., and Wu, H. (May 2, 2018). "Analysis of Mode and Dynamic Stability for Wind Turbine Rotating Blades." ASME. J. Offshore Mech. Arct. Eng. October 2018; 140(5): 051902. https://doi.org/10.1115/1.4039717
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