Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2020, Cilt: 24 Sayı: 6, 1151 - 1161, 01.12.2020
https://doi.org/10.16984/saufenbilder.719223

Öz

Kaynakça

  • H. J. Sutherland, “On the fatigue analysis of wind turbines,” Sandia National Laboratories Report, 1999.
  • S. R. Winterstein and P. S. Veers, “A numerical analysis of the fatigue and reliability of wind turbine components,” Sandia National Laboratories Report, 2000.
  • K. Cox and A. Echtermeyer, “Structural design and analysis of a 10 MW wind turbine blade,” Energy Procedia, vol.24: pp. 194–201, 2012.
  • M. Yeh and C. Wang, “Stress analysis of composite wind turbine blade by finite element method,” ACMME 2017 5th Asia Conference on Mechanical and Materials Engineering, vol. 241, pp. 12–15, 2017.
  • L. Wang, R. Quant and A. Kolios, “Fluid structure interaction modeling of horizontal axis wind turbine blades based on CFD and FEA,” Journal of Wind Engineering and Industrial Aerodynamics, vol.158, pp.11-25, 2016.
  • E. M. Fagan, M. Flanagan, S. B. Leen, T. Flanagan, A. Doyle and J. Goggins, “Physical Experimental Static Testing and Structural Design Optimisation for a Composite Wind Turbine Blade,” Composite Structures, 2016.
  • D. K. Choi, B. D. Pyeon, S. Y. Lee, H. G. Lee and J. S. Bae, “Structural Design, Analysis, and Testing of a 10 kW Fabric-Covered Wind Turbine Blade,” Energies, vol.13, pp. 3276, 2020.
  • M. Casini, “Small Vertical Axis Wind Turbines for Energy Efficiency of Buildings,” Journal of Clean Energy Technologies, vol. 4, no. 1, pp. 56–65, 2016.
  • H. J. Sutherland, D. E. Berg, and T. D. Ashwill, “A Retrospective of VAWT Technology,” Sandia National Laboratories Report, 2012.
  • M. Islam, D. King, and A. Fartaj , “Aerodynamic models for Darrieus-type straight-bladed vertical axis wind turbines,” Renewable and Sustainable Energy Reviews, vol. 12, no. 4, pp. 1087–1109, 2008.
  • A. M. Gorlov, “Development of the helical reaction hydraulic turbine. Final Technical Report,” The US Department of Energy, 1998.
  • Q. Cheng, X. Liu, H. S. Ji, K. C. Kim, and B. Yang, “Aerodynamic Analysis of a Helical Vertical Axis Wind Turbine,” Energies, vol. 10, no. 4, pp. 575–592, 2017.
  • NACA Report No.824. http://naca.central.cranfield.ac.uk/reports/1945/naca-report-824.pdf.
  • Airfoil Tools. http://airfoiltools.com/airfoil/details?airfoil=naca0018-il.
  • A. Özekes, “Helisel Dikey Eksen Bir Rüzgar Türbininin Belirli Tasarım Kriterleri Altında Performansının İncelenmesi,” MSc, Manisa Celal Bayar Üniversitesi, 2019.
  • Comsol Multiphysics, CFD Module Users Guide, 2018.
  • S. Turek and J. Hron, “Proposal for numerical benchmarking of fluid-structure interaction between an elastic object and laminar incompressible flow, H. J. Bungartz HJ, M. Schäfer, editors. Fluid-Structure Interaction; Modelling, Simulation, Optimisation,” Springer, pp. 371–385, 2007.
  • ASM Handbook Committee, “ASM Handbook Volume 2: Properties and Selection: Nonferrous Alloys and Special-Purpose Materials,” pp. 62–122, 1990.

Structural Design and Stress Analysis of a Helical Vertical Axis Wind Turbine Blade

Yıl 2020, Cilt: 24 Sayı: 6, 1151 - 1161, 01.12.2020
https://doi.org/10.16984/saufenbilder.719223

Öz

In this study, a Computational Fluid Dynamics (CFD) model is designed to investigate the structural analysis of a helical Vertical Axis Wind Turbine (VAWT) blade which is using National Advisory Committee for Aeronautics (NACA) 0018 airfoil and numerical calculations are conducted by using Comsol Multiphysics. The main objective of this study is to determine that the strength of the turbine blade against bending caused by increased wind speeds is sufficient for the selected turbine blade material. This paper presents also an investigation of the effects of different wind speeds on the structure of a helical VAWT blade that is fixed to the support arm which is attached to the VAWT’s main shaft. In this study, a turbine blade which is placed in an air flow field is subjected to approaching strong wind with different velocities. The model solves for the flow around the blade and the structural displacement due to the fluid load. This investigation consists of two main parts: Solving for the fluid flow around the turbine blade with a free stream velocities of 1, 3, 5, 7, and 9 m/s, and Studying the deformation of the turbine blade caused by the fluid load. The risk of failure according to the von Mises criterion for the ductile materials such as aluminum is also investigated.

Kaynakça

  • H. J. Sutherland, “On the fatigue analysis of wind turbines,” Sandia National Laboratories Report, 1999.
  • S. R. Winterstein and P. S. Veers, “A numerical analysis of the fatigue and reliability of wind turbine components,” Sandia National Laboratories Report, 2000.
  • K. Cox and A. Echtermeyer, “Structural design and analysis of a 10 MW wind turbine blade,” Energy Procedia, vol.24: pp. 194–201, 2012.
  • M. Yeh and C. Wang, “Stress analysis of composite wind turbine blade by finite element method,” ACMME 2017 5th Asia Conference on Mechanical and Materials Engineering, vol. 241, pp. 12–15, 2017.
  • L. Wang, R. Quant and A. Kolios, “Fluid structure interaction modeling of horizontal axis wind turbine blades based on CFD and FEA,” Journal of Wind Engineering and Industrial Aerodynamics, vol.158, pp.11-25, 2016.
  • E. M. Fagan, M. Flanagan, S. B. Leen, T. Flanagan, A. Doyle and J. Goggins, “Physical Experimental Static Testing and Structural Design Optimisation for a Composite Wind Turbine Blade,” Composite Structures, 2016.
  • D. K. Choi, B. D. Pyeon, S. Y. Lee, H. G. Lee and J. S. Bae, “Structural Design, Analysis, and Testing of a 10 kW Fabric-Covered Wind Turbine Blade,” Energies, vol.13, pp. 3276, 2020.
  • M. Casini, “Small Vertical Axis Wind Turbines for Energy Efficiency of Buildings,” Journal of Clean Energy Technologies, vol. 4, no. 1, pp. 56–65, 2016.
  • H. J. Sutherland, D. E. Berg, and T. D. Ashwill, “A Retrospective of VAWT Technology,” Sandia National Laboratories Report, 2012.
  • M. Islam, D. King, and A. Fartaj , “Aerodynamic models for Darrieus-type straight-bladed vertical axis wind turbines,” Renewable and Sustainable Energy Reviews, vol. 12, no. 4, pp. 1087–1109, 2008.
  • A. M. Gorlov, “Development of the helical reaction hydraulic turbine. Final Technical Report,” The US Department of Energy, 1998.
  • Q. Cheng, X. Liu, H. S. Ji, K. C. Kim, and B. Yang, “Aerodynamic Analysis of a Helical Vertical Axis Wind Turbine,” Energies, vol. 10, no. 4, pp. 575–592, 2017.
  • NACA Report No.824. http://naca.central.cranfield.ac.uk/reports/1945/naca-report-824.pdf.
  • Airfoil Tools. http://airfoiltools.com/airfoil/details?airfoil=naca0018-il.
  • A. Özekes, “Helisel Dikey Eksen Bir Rüzgar Türbininin Belirli Tasarım Kriterleri Altında Performansının İncelenmesi,” MSc, Manisa Celal Bayar Üniversitesi, 2019.
  • Comsol Multiphysics, CFD Module Users Guide, 2018.
  • S. Turek and J. Hron, “Proposal for numerical benchmarking of fluid-structure interaction between an elastic object and laminar incompressible flow, H. J. Bungartz HJ, M. Schäfer, editors. Fluid-Structure Interaction; Modelling, Simulation, Optimisation,” Springer, pp. 371–385, 2007.
  • ASM Handbook Committee, “ASM Handbook Volume 2: Properties and Selection: Nonferrous Alloys and Special-Purpose Materials,” pp. 62–122, 1990.
Toplam 18 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Makine Mühendisliği
Bölüm Araştırma Makalesi
Yazarlar

Özer Öğüçlü 0000-0002-6293-7742

Yayımlanma Tarihi 1 Aralık 2020
Gönderilme Tarihi 13 Nisan 2020
Kabul Tarihi 4 Ağustos 2020
Yayımlandığı Sayı Yıl 2020 Cilt: 24 Sayı: 6

Kaynak Göster

APA Öğüçlü, Ö. (2020). Structural Design and Stress Analysis of a Helical Vertical Axis Wind Turbine Blade. Sakarya University Journal of Science, 24(6), 1151-1161. https://doi.org/10.16984/saufenbilder.719223
AMA Öğüçlü Ö. Structural Design and Stress Analysis of a Helical Vertical Axis Wind Turbine Blade. SAUJS. Aralık 2020;24(6):1151-1161. doi:10.16984/saufenbilder.719223
Chicago Öğüçlü, Özer. “Structural Design and Stress Analysis of a Helical Vertical Axis Wind Turbine Blade”. Sakarya University Journal of Science 24, sy. 6 (Aralık 2020): 1151-61. https://doi.org/10.16984/saufenbilder.719223.
EndNote Öğüçlü Ö (01 Aralık 2020) Structural Design and Stress Analysis of a Helical Vertical Axis Wind Turbine Blade. Sakarya University Journal of Science 24 6 1151–1161.
IEEE Ö. Öğüçlü, “Structural Design and Stress Analysis of a Helical Vertical Axis Wind Turbine Blade”, SAUJS, c. 24, sy. 6, ss. 1151–1161, 2020, doi: 10.16984/saufenbilder.719223.
ISNAD Öğüçlü, Özer. “Structural Design and Stress Analysis of a Helical Vertical Axis Wind Turbine Blade”. Sakarya University Journal of Science 24/6 (Aralık 2020), 1151-1161. https://doi.org/10.16984/saufenbilder.719223.
JAMA Öğüçlü Ö. Structural Design and Stress Analysis of a Helical Vertical Axis Wind Turbine Blade. SAUJS. 2020;24:1151–1161.
MLA Öğüçlü, Özer. “Structural Design and Stress Analysis of a Helical Vertical Axis Wind Turbine Blade”. Sakarya University Journal of Science, c. 24, sy. 6, 2020, ss. 1151-6, doi:10.16984/saufenbilder.719223.
Vancouver Öğüçlü Ö. Structural Design and Stress Analysis of a Helical Vertical Axis Wind Turbine Blade. SAUJS. 2020;24(6):1151-6.

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