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Nonlinear Analysis of Twisted Wind Turbine Blade

Published online by Cambridge University Press:  12 December 2016

M. Yangui ,
S. Bouaziz ,
M. Taktak ,
M. Haddar  and
A. El-Sabbagh
M. Yangui
Affiliation:
Mechanics, Modelling and Production LaboratoryMechanic DepartmentNational School of Engineers of SfaxUniversity of SfaxSfax, Tunisia
S. Bouaziz*
Affiliation:
Mechanics, Modelling and Production LaboratoryMechanic DepartmentNational School of Engineers of SfaxUniversity of SfaxSfax, Tunisia
M. Taktak
Affiliation:
Mechanics, Modelling and Production LaboratoryMechanic DepartmentNational School of Engineers of SfaxUniversity of SfaxSfax, Tunisia
M. Haddar
Affiliation:
Mechanics, Modelling and Production LaboratoryMechanic DepartmentNational School of Engineers of SfaxUniversity of SfaxSfax, Tunisia
A. El-Sabbagh
Affiliation:
ASU Sound and Vibration LabDesign and Production Engineering DepartmentAin Shams UniversityCairo, Egypt
*
*Corresponding author ([email protected])
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Abstract

Modal analysis is developed in this paper in order to study the dynamic characteristics of rotating segmented blades assembled with spar. Accordingly, a three dimensional finite element model was built using the three node triangular shell element DKT18, which has six degrees of freedom, to model the blade and the spar structures. This study covers the effect of rotation speed and geometrically nonlinear problems on the vibration characteristics of rotating blade with various pretwist angles. Likewise, the effect of the spar in the blade is taken into consideration. The equation of motion for the finite element model is derived by using Hamilton's principle, while the resulting nonlinear equilibrium equation is solved by applying the Newmark method combined with the Newton Raphson schema. Results show that the natural frequencies increase by taking account of the spar, they are also proportional to the angular rotation speed and influenced by geometric nonlinearity and pretwist angle.

Keywords

Pretwisted bladeModal analysisGeometric nonlinearityShell element
Type
Research Article
Information
Journal of Mechanics , Volume 34 , Issue 3 , June 2018 , pp. 269 - 278
Copyright
Copyright © The Society of Theoretical and Applied Mechanics 2018 

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References

1. Yoo, H. H. and Shin, S. H., “Vibration analysis of rotating cantilever beams,” Journal of Sound and Vibration, 212, pp. 807828 (1998).Google Scholar
2. Park, J. H., et al., “Linear vibration analysis of rotating wind-turbine blade,” Current Applied Physics, 10, pp. 332334 (2010).Google Scholar
3. Hamdi, H., Mrad, C., Hamdi, A. and Nasri, R., “Dynamic response of a horizontal axis wind turbine blade under aerodynamic, gravity and gyroscopic effects,” Applied Acoustics, 86, pp. 154164 (2014).Google Scholar
4. Sheibani, M. and Akbari, A. A., “Finite element modeling of a wind turbine blade,” Journal of Vibroengineering, 17, pp. 37743791 (2015).Google Scholar
5. Pourazarm, P., Caracoglia, L., Lackner, M. and Modarres-Sadeghi, Y., “Stochastic analysis of flow-induced dynamic instabilities of wind turbine blades,” Journal of Wind Engineering and Industrial Aerodynamics, 137, pp. 3745 (2015).Google Scholar
6. Young, T. H., “Dynamic responses of a pretwisted, tapered beam with non-constant rotating speed,” Journal of Sound and Vibration, 150, pp. 435446 (1991).Google Scholar
7. Chen, L. W. and Peng, W. K., “Dynamic stability of rotating blades with geometric non-linearity,” Journal of Sound and Vibration, 187, pp. 421433 (1995).Google Scholar
8. Hu, K., Vlahopoulos, N. and Mourelatos, Z. P., “A finite element formulation for coupling rigid and flexible body dynamics of rotating beams,” Journal of Sound and Vibration, 253, pp. 603630 (2002).Google Scholar
9. Maalawi, K. Y. and Negm, H. M., “Optimal frequency design of wind turbine blades,” Journal of Wind Engineering and Industrial Aerodynamics, 90, pp. 961986 (2002).Google Scholar
10. Arvin, H. and Bakhtiari-Nejad, F., “Non-linear modal analysis of a rotating beam”, International Journal of Non-Linear Mechanics, 46, pp. 877897 (2011).CrossRefGoogle Scholar
11. Rezaei, M. M., Behzad, M., Haddadpour, H. and Moradi, H., “Development of a reduced order model for nonlinear analysis of the wind turbine blade dynamics,” Renewable Energy, 76, pp. 264282 (2015).CrossRefGoogle Scholar
12. Dokainish, M. A. and Rawtani, S., “Vibration analysis of pretwisted cantilever plates,” Transactions of Canadian Aeronautics and Space Institute, 2, pp. 95100 (1969).Google Scholar
13. Dokainish, M. A. and Rawtani, S., “Pseudo-static deformation and frequencies of rotating turbomachinery blades,” AIAA Journal, 10, pp. 13971398 (1972).Google Scholar
14. Bossak, M. A. J. and Zienkiewicz, O. C., “Free vibration of initially stressed solids, with particular reference to centrifugal-force effects in rotating machinery,” The Journal of Strain Analysis for Engineering Design, 8, pp. 245252 (1973).Google Scholar
15. Leissa, A. W., Lee, J. K. and Wang, A. J., “Rotating Blade Vibration Analysis Using Shells,” Journal of Engineering for Power, 104, pp. 296302 (1982).Google Scholar
16. El Chazly, N. M., “Static and dynamic analysis of wind turbine blades using the finite element method,” Computers & Structures, 48, pp. 273290 (1993).Google Scholar
17. Hu, X. X., Sakiyama, T., Matsuda, H. and Morita, C., “Fundamental vibration of rotating cantilever blades with pre-twist,” Journal of Sound and Vibration, 271, pp. 4766 (2004).Google Scholar
18. Kee, Y. J. and Kim, J. H., “Vibration characteristics of initially twisted rotating shell type composite blades,” Composite Structures, 64, pp. 151159 (2004).Google Scholar
19. Sinha, S. K. and Turner, K. E., “Natural frequencies of a pre-twisted blade in a centrifugal force field,” Journal of Sound and Vibration, 330, pp. 26552681 (2011).Google Scholar
20. Sun, J., Arteaga, I. L. and Kari, L., “General shell model for a rotating pretwisted blade,” Journal of Sound and Vibration, 332, pp. 58045820 (2013).Google Scholar
21. Bayoumy, A. H., Nada, A. A. and Megahed, S. M., “A continuum based three-dimensional modeling of wind turbine blades,” Journal of Computational and Nonlinear Dynamics, 8, 031004 (2013).Google Scholar
22. Kang, H., Chang, C., Saberi, H. and Ormiston, R. A., “Assessment of beam and shell elements for modeling rotorcraft blades,” Journal of Aircraft, 51, pp. 520531 (2014).Google Scholar
23. Kee, Y. J. and Shin, S. J., “Structural dynamic modeling for rotating blades using three dimensional finite elements,” Journal of Mechanical Science and Technology, 29, pp. 16071618 (2015).Google Scholar
24. Batoz, J. L. and Dhatt, G., Modélisation des structures par éléments finis, Coques, Hermès, Paris, pp. 375387 (1990).Google Scholar