For Libraries For Publication Open Access Downloads About Us Contact Us
Paper Titles
The Formation of Temperature Controller by PSoC
p.127
Research on the Work Space Optimization of the Six Bar Parallel Machine Tool
p.131
The Design of Passive RFID Reader System Based on MF RC500
p.135
The Design of Measurement System Based on Digital Temperature Sensors
p.139
Research on the Optimization Design of Gas-Solid Coupling of Wind Turbine Blades
p.143
Research on Wind Turbine Blade Load Based on the Analysis of Structural Dynamics
p.147
Study on Fault Testing System of Photovoltaic Cells
p.151
Research on Electromagnetic Energy Absorbed by Human Body in the Vicinity of High-Voltage Transmission Line
p.155
The Property Analysis of the Leaf Spring Based on Abaqus and Elastic Mechanics
p.159

Research on the Optimization Design of Gas-Solid Coupling of Wind Turbine Blades

Article Preview

Abstract:

The effects of high-altitude wind shear of wind speed should be considered, the appropriate number of distribution group should be determined and the distribution of wind speed hybrid model parameters and solving should be loaded onto the blades. When the stress of rotor blade is analyzed, the elastic deformation of the blades and the effects of the vibration of oscillating flow field on reaction of the blades must be considered during the operation. Thus the laws of blade load distribution and the corresponding deformation can be accurately calculated to analyze the interplay between deformation vibration airflow and paddle, to determine the law of deformation of rotor blades, the surface pressure distribution, stress distribution and blade design safety factors. When wind load changes with the wind speed, the adaptive blades are powered by aeroelastic, the law of wielding and flapping of the blade will be studied. The torsion coupling effects of adaptive blade, blade bending ,the law of torsional deformation variation of the angle of attack and the impact on aeroelastic blades structural strength will be explored. The results of this study design will be optimized as the power factor, improving the stability of the design of wind turbine power output, reducing material consumption blades absorb vibration and reducing wind load maneuvering to avoid blade stall achieve pitch control. Thus it provides a theoretical basis for optimal design of strength and stiffness of the elongated paddles.

You might also be interested in these eBooks
Advanced Research on Information Science, Automation and Material System IV View Preview

Info:

Periodical:

Advanced Materials Research (Volume 1022)

Pages:

143-146

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1022.143

Citation:

Cite this paper

Online since:

August 2014

Authors:

Zhi Qiang Xu*

Keywords:

Blade, Gas-Solid Coupling Analysis, Hybrid Wind Model, Performance Optimization, Structure

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2014 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

* - Corresponding Author

References

[1] D.A. Griffin. WindPACT Turbine Design Scaling Studies Technical Area 1 - Composite Blades for 80- to 120-Meter Rotor. NREL /SR-500-29492, Golden, CO, National Renewable Energy Laboratory (2001).

DOI: 10.2172/783406

Google Scholar

[2] Balduzzi F. Feasibility analysis of a Darrieus vertical-axis wind turbine installation in the rooftop of a building[J]. Applied Energy (2011).

DOI: 10.1016/j.apenergy.2011.12.008

Google Scholar

[3] Weifei Hu, Insik Han, Sang-Chul Park and Dong-Hoon Choi, Multi-objective structural optimization of a HAWT composite blade based on ultimate limit state analysis[J], Journal of Mechanical Science and Technology 26 (1) (2012) 129-135.

DOI: 10.1007/s12206-011-1018-3

Google Scholar

[4] Hyung Il Kwon, Ju Yeol You and Oh Joon Kwon. Enhancement of wind turbine aerodynamic performance by a numerical opti mization technique[J], Journal of Mechanical Science and Technology 26 (2) (2012): 455-462.

DOI: 10.1007/s12206-011-1035-2

Google Scholar

[5] A.F.P. Ribeiro, An airfoil optimization technique for wind turbines[J], Appl. Math. Modell. (2012).

Google Scholar

[6] A.D. Wright and L.J. Fingersh, Advanced Control Design for Wind Turbines: Part I, Control Design, Implementation, and Initial Tests. NREL /TP-500-42437, Golden, CO, National Renewable Energy Laboratory (2008).

DOI: 10.2172/927269

Google Scholar

[7] D. Lobitz, P. Veers, G. Eisler, D. Laino, P. Migliore and G. Bir. The Use of Twist-Coupled Blades to Enhance Performance of Horizontal Axis Wind Turbines, SAND2001-1303, Albuquerque, NM, Sandia National Laboratories (2001).

DOI: 10.2172/783086

Google Scholar

[8] J. Paquette, J. van Dam and S. Hughes, Structural Testing of 9 m Carbon Fiber Wind Turbine Research Blades, AIAA 2007, Wind Energy Symposium, Reno Nevada, NREL/CP-500-40985, Golden, CO, National Renewable Energy Laboratory.

DOI: 10.2514/6.2007-816

Google Scholar

[9] JAMES E, LOCKE, and THOMAS M HERMANN. Laminate design for coupled wind turbine blades[A]. 44th AIAAaerospace sciences meeting and xhibit[C]. RenoNevada, (2006).

DOI: 10.2514/6.2006-1198

Google Scholar

[10] Denis Matha, Markus Schlipf, Andrew Cordle and Ricardo Pereira. Challenges in Simulation of Aerodynamics, Hydrodynamics and Mooring-Line Dynamics of Floating Offshore Wind Turbines[C], Presented at the 21st International Offshore and Polar Engineering Conference, 19-24 June 2011, Maui, Hawaii.

Google Scholar

[11] J.A. Carta , P. Ram ´rez and S. Vela ´zquez. A review of wind speed probability distributions used in wind energy analysis Case studies in the Canary Islands[J]. Renewable and Sustainable Energy Review 2009: 13(933-955).

DOI: 10.1016/j.rser.2008.05.005

Google Scholar

[12] K.K. Wetzel. Utility Scale Twist-Flap Coupled Blade Design[J]. Journal of Solar Energy Engineering, 2005(127): 529-537.

DOI: 10.1115/1.2037089

Google Scholar

[13] Seungmin Lee, Hogeon Kim, Eunkuk Son and Soogab Lee. Effects of design parameters on aerodynamic performance of a counter-rotating wind turbine[J], Renewable Energy 42 (2012): 140-144.

DOI: 10.1016/j.renene.2011.08.046

Google Scholar

[14] A. Maheri, S Noroozi and J Vinney. Decoupled aerodynamic and structural design of wind turbine adaptive blades[J]. Renewable Energy, 2007(32): 1753–1767.

DOI: 10.1016/j.renene.2006.11.004

Google Scholar

[15] Yuwei Li, Kwang-Jun Paik and Tao Xing. Dynamic overset CFD simulations of wind turbine aerodynamic[J], Renewable Energy 37 (2012) : 285-298.

DOI: 10.1016/j.renene.2011.06.029

Google Scholar

[16] Kenji Takizawa, Bradley Henicke and Darren Montes. Numerical performance studies for the stabilized space-time computation of wind turbine rotor aerodynamics[J], Comput Mech (2011) 48: 647-657.

DOI: 10.1007/s00466-011-0614-5

Google Scholar

[1] Dj.M. Maric, P.F. Meier and S.K. Estreicher: Mater. Sci. Forum Vol. 83-87 (1992), p.119.

Google Scholar

[2] M.A. Green: High Efficiency Silicon Solar Cells (Trans Tech Publications, Switzerland 1987).

Google Scholar

[3] Y. Mishing, in: Diffusion Processes in Advanced Technological Materials, edtied by D. Gupta Noyes Publications/William Andrew Publising, Norwich, NY (2004), in press.

Google Scholar

[4] G. Henkelman, G. Johannesson and H. Jónsson, in: Theoretical Methods in Condencsed Phase Chemistry, edited by S.D. Schwartz, volume 5 of Progress in Theoretical Chemistry and Physics, chapter, 10, Kluwer Academic Publishers (2000).

Google Scholar

[5] R.J. Ong, J.T. Dawley and P.G. Clem: submitted to Journal of Materials Research (2003).

Google Scholar

[6] P.G. Clem, M. Rodriguez, J.A. Voigt and C.S. Ashley, U.S. Patent 6, 231, 666. (2001).

Google Scholar

[7] Information on http: /www. weld. labs. gov. cn.

Google Scholar

© 2025 Trans Tech Publications Ltd. All rights are reserved, including those for text and data mining, AI training, and similar technologies. For open access content, terms of the Creative Commons licensing CC-BY are applied.
Scientific.Net is a registered trademark of Trans Tech Publications Ltd.