Design and analysis of vertical axis thermoplastic composite wind turbine blade

REFERENCES

• ‘British wind generators confident of meeting EU's ambitious targets’, Profess. Eng. , 2008, 5.
   Google Scholar
• S. Giannis and P. Hansen: ‘Blowing in the wind’, Mater. World, May 2009, 44 46.
   Google Scholar
• S. Eriksson, B. Hans and M. Leijon: ‘Evaluation of different turbine concepts for wind power’, Renew. Sustain. Energy Rev. , 2006. 12, 1419–1434.
   Web of Science ®Google Scholar
• H. Reidy: ‘Street credibility’, Profess. Eng. , 2008, London, IMechE, available at: http://www.profeng.com/archive/2008/2112/ 21120054.htm (accessed 15 April 2009).
   Google Scholar
• P. Brondsted, H. Lilholt and A. Lystrup: ‘Composite materials for wind power turbines blades’, Annu. Rev. Mater. Res. , 2005. 35, 505–538.
   Web of Science ®Google Scholar
• G. Gardiner: ‘Wind blade manufacturing, Part II: Are thermoplastic composites the future?’, in ‘High performance composites’, 2008, Composites World, available at: http://www.compositesworld. com/articles/wind-blade-manufacturing-part-ii-are-thermoplastic-composites-the-future.aspx (accessed 24 May 2009).
   Google Scholar
• A. Lystrup: ‘Vacuum consolidation of thermoplastic composites for wind turbine rotor blades’, Proc. 27th Riso Int. Symp. on ‘Materials science’, Roskilde, Denmark, September 2006, Riso National Laboratory, 231-238.
   Google Scholar
• M. D. Wakeman and J. A. E. Manson: ‘Composite manufacturing — thermoplastics’, in ‘Design and manufacture of textile compo-sites’, (ed. A. C. Long), 197-241; 2005, Cambridge, Woodhead.
   Google Scholar
• M. D. Wakeman, C. D. Rudd, T. A. Cain, R. Brooks and A. C. Long: ‘Compression moulding of glass and polypropylene compo-sites for optimised macro- and micro- mechanical properties. 1. Commingled glass and polypropylene’, Compos. Sci. Technol, 1998, 58, (12), 1879–1898.
   Web of Science ®Google Scholar
• E. R. Jorgensen, K. K. Borum, M. McGugan, C. L. Thomsen, F. M. Jensen, C. P. Debel and B. F. Sorensen: ‘Full scale testing of wind turbine blade to failure-flapwise loading’; 2004, Roskilde, Riso National Laboratory.
   Google Scholar
• M. E. Bechly and P. D. Clausen: ‘Structural design of a composite wind turbine blade using finite element analysis’, Comput. Struct. , 1997, 63, (3), 639–646.
   Web of Science ®Google Scholar
• C. J. Kong, J. Bang and Y. Sugiyama: ‘Structural investigation of composite wind turbine blade considering various load cases and fatigue life’, Energy, 2005, 30, 2101-2114.
   Google Scholar
• D. Laird: ‘Finite element modelling of wind turbine blades’, Proc. AIAA Aerospace Science Meet. and Exhib., Reno, NV, USA, January 2005, AIAA, 1-9.
   Google Scholar
• A. D. Otero and F. L. Ponta: ‘Finite element structural study of the VGOT wind turbine’, Int. J. Global Energy Issues, 2004, 21, (3), 221–235.
   Google Scholar
• J. S. Rajadurai, T. Christopher, G. Thanigaiyarasu and B. Nageswara Rao: ‘Finite element analysis with an improved failure criterion for composite wind turbine blades’, Forsch Ingenieurwes. , 2008, 72, 193–207.
   Web of Science ®Google Scholar
• L. C. T. Overgaard and E. Lund: ‘Structural collapse of a wind turbine blade. Part B: Progressive interlaminar failure models’, Composites A, 41A, (2), 271-283.
   Google Scholar
• Twintex Technical Data: available at: http://www.ocvreinforcements. com/solutions/Twintex.asp
   Google Scholar
• Armaform Technical Data: available at: http://www.armacell.com/ www/armacell
   Google Scholar
• K. A. Brown, R. Brooks and N. A. Warrior: ‘The static and high strain rate behaviour of a commingled E-glass/polypropylene woven fabric composite’, Compos. Set Technol, 2010, 70, (2), 272–283.
   Google Scholar
• Polytec: `Polytec scanning vibrometer PSV-200 manual'; 1999, Waldbronn, Polytec.
   Google Scholar
• J. O. Hallquist: ‘LS-DYNA keyword user's manual version 971’; 2007, Livermore, CA, Livermore Software Technology Corporation.
   Google Scholar
• A. Matzenmiller, J. Lubliner and R. L. Taylor: ‘A constitutive model for anisotropic damage in fiber-composites’, Mech. Mater. , 1995, 20, (2), 125–152.
   Web of Science ®Google Scholar
• K. Schweizerhof, K. Weimar, Th. Mfinz and Th. Rottner: `Crashworthiness analysis with enhanced composite materials models in LS-DYNA — merits and limits', Proc. 5th Int. LS-DYNA Users' Conf., Southfield, MI, USA, September 1998, 1-17.
   Google Scholar
• R. Brooks, K. A. Brown, N. A. Warrior and P. P. Kulandaivel : 'Predictive modelling of the impact response of thermoplastic composite sandwich structures', J. Sandwich Struct. Mater. , 2009, 1099636209104537.
   Google Scholar
• K. Brown: ‘Finite element modelling of the static and dynamic impact behaviour of thermoplastic composite sandwich struc-tures’, PhD thesis, University of Nottingham, Nottingham, UK, 2007.
   Google Scholar
• G. Chen: ‘Development of a computational model for a composite micro wind turbine blade’, MSc thesis, University of Nottingham, Nottingham, UK, 2008.
   Google Scholar
• ‘Standard test method for tensile properties of polymer matrix composite materials’, D3039, ASTM International, West Conshohocken, PA, USA, 1995.
   Google Scholar
• ‘Standard test method for in-plane shear response of polymer matrix composite materials by tensile test of a +45° laminate’, D3518, ASTM International, West Conshohocken, PA, USA, 1995.
   Google Scholar
• D. M. Montiel and C. J. Williams: ‘Method for evaluating the high strain rate compressive properties of composite materials’. Proc. 10th Conf. on ‘Composite materials: testing and design’; 1992, Philadelphia, PA, ASTM International.
   Google Scholar
• R. Fernie: ‘Loading rate effects on the energy absorption of lightweight tubular crash structures’, PhD thesis, University of Nottingham, Nottingham, UK, 2002.
   Google Scholar
• T. Burton, D. Sharpe, N. Jenkins and E. Bossanyi: ‘Wind energy handbook’; 2001, Sussex, John Wiley & Sons.
   Google Scholar
• D. J. Malcolm: ‘Modal response of 3-bladed wind turbines’, J. Solar Energy Eng. , 2009, 124, 372–377.
   Google Scholar