Full-Scale Fatigue Testing of a Wind Turbine Blade in Flapwise Direction and Examining the Effect of Crack Propagation on the Blade Performance

In this paper, the sensitivity of the structural integrity of wind turbine blades to debonding of the shear web from the spar cap was investigated. In this regard, modal analysis, static and fatigue testing were performed on a 45.7 m blade for three states of the blade: (i) as received blade (ii) when a crack of 200 mm was introduced between the web and the spar cap and (iii) when the crack was extended to 1000 mm. Calibration pull-tests for all three states of the blade were performed to obtain the strain-bending moment relationship of the blade according to the estimated target bending moment (BM) which the blade is expected to experience in its service life. The resultant data was used to apply appropriate load in the fatigue tests. The blade natural frequencies in flapwise and edgewise directions over a range of frequency domain were found by modal testing for all three states of the blade. The blade first natural frequency for each state was used for the flapwise fatigue tests. These were performed in accordance with technical specification IEC TS 61400-23. The fatigue results showed that, for a 200 mm crack between the web and spar cap at 9 m from the blade root, the crack did not propagate at 50% of the target BM up to 62,110 cycles. However, when the load was increased to 70% of target BM, some damages were detected on the pressure side of the blade. When the 200 mm crack was extended to 1000 mm, the crack began to propagate when the applied load exceeded 100% of target BM and the blade experienced delaminations, adhesive joint failure, compression failure and sandwich core failure.

[1]  H. Hadavinia,et al.  Characterising mode I/mode II fatigue delamination growth in unidirectional fibre reinforced polymer laminates , 2015 .

[2]  Ole Thybo Thomsen,et al.  Sandwich Materials for Wind Turbine Blades — Present and Future , 2009 .

[3]  G. Liaghat,et al.  Improving the fracture toughness and the strength of epoxy using nanomaterials--a review of the current status. , 2015, Nanoscale.

[4]  G. C. Larsen,et al.  Experimental determination of stiffness distributions and mode shapes of wind turbine blades , 1995 .

[5]  Lennart Kühlmeier Buckling of wind turbine rotor blades: Analysis, design and experimental validation , 2007 .

[6]  James F. Manwell,et al.  A review and design study of blade testing systems for utility-scale wind turbines , 2012 .

[7]  Chaoyi Peng,et al.  Structural investigation of composite wind turbine blade considering structural collapse in full-scale static tests , 2013 .

[8]  Hak-Gu Lee,et al.  Static test until structural collapse after fatigue testing of a full-scale wind turbine blade , 2016 .

[9]  Paul M. Weaver,et al.  On the structural topology of wind turbine blades , 2013 .

[10]  K. Cox,et al.  Effects of composite fiber orientation on wind turbine blade buckling resistance , 2014 .

[12]  Bin Yang,et al.  Testing, inspecting and monitoring technologies for wind turbine blades: A survey , 2013 .

[13]  C. P. Debel,et al.  Improved design of large wind turbine blade of fibre composites based on studies of scale effects (Phase 1) - Summary Report , 2004 .

[14]  H. Hadavinia,et al.  Building delamination fracture envelope under Mode I / Mode II loading for FRP composite materials , 2013 .

[15]  F. M. Jensen,et al.  Structural testing and numerical simulation of a 34 m composite wind turbine blade , 2006 .

[16]  Gunner Chr. Larsen,et al.  Modal Analysis of Wind Turbine Blades , 2002 .

[17]  Tao Zhang,et al.  Improving the fracture toughness properties of epoxy using graphene nanoplatelets at low filler content , 2017 .

[18]  M. Kang,et al.  Fatigue failure of a composite wind turbine blade at its root end , 2015 .

[19]  L. Mishnaevsky,et al.  Hybrid and hierarchical nanoreinforced polymer composites: Computational modelling of structure-properties relationships , 2014 .