Fluctuations of angle of attack and lift coefficient and the resultant fatigue loads for a large Horizontal Axis Wind turbine

Unsteady loads are a major limiting factor for further upscaling of HAWTs considering the high costs associated to strict structural requirements. Alleviation of these unsteady loads on HAWT blades, e.g. using active flow control (AFC), is of high importance. In order to devise effective AFC methods, the unsteady loading sources need to be identified and their relative contribution to the load fluctuations experienced by blades needs to be quantified. The current study investigates the effects of various atmospheric and operational parameters on the fluctuations of α and CL for a large HAWT. The investigated parameters include turbulence, wind shear, yawed inflow, tower shadow, gravity and rotational imbalances. The study uses the DTU's aeroelastic software HAWC2. The study identifies the individual and the aggregate effect of each source on the aforementioned fluctuations in order to distinguish the major contributing factors to unsteady loading. The quantification of contribution of each source on the total fatigue loads reveals >65% of flapwise fatigue loads is a result of turbulence while gravity results in >80% of edgewise fatigue loads. The extensive parametric study shows that the standard deviation of CL is 0.25. The results support to design active load control systems by highlighting the magnitude of CL and α variations experienced by HAWTs, and thus the dCL that needs to be delivered by an AFC system.

[1]  Jörg R. Seume,et al.  Investigation of Site-Specific Wind Field Parameters and Their Effect on Loads of Offshore Wind Turbines , 2012 .

[2]  Robert L. Nelson,et al.  A Smart Wind Turbine Blade Using Distributed Plasma Actuators for Improved Performance , 2008 .

[3]  J. Gordon Leishman,et al.  Challenges in modelling the unsteady aerodynamics of wind turbines , 2002 .

[4]  B. J. Gould,et al.  Effects of wind shear on wind turbine rotor loads and planetary bearing reliability , 2016 .

[5]  G.J.W. Van Bussel,et al.  Wind turbine fatigue loads as a function of atmospheric conditions offshore , 2016 .

[6]  Ahmed A. Shabana,et al.  Dynamics of Multibody Systems , 2020 .

[7]  H. Madsen,et al.  Review paper on wind turbine aerodynamics , 2011 .

[8]  F. Coton,et al.  A study on rotational effects and different stall delay models using a prescribed wake vortex scheme and NREL phase VI experiment data , 2008 .

[9]  L. Henriksen,et al.  The DTU 10-MW Reference Wind Turbine , 2013 .

[10]  Scott J. Johnson,et al.  An overview of active load control techniques for wind turbines with an emphasis on microtabs , 2010 .

[11]  Joachim Christian Heinz,et al.  Partitioned Fluid-Structure Interaction for Full Rotor Computations Using CFD , 2013 .

[12]  Walter Musial,et al.  Determining equivalent damage loading for full-scale wind turbine blade fatigue tests , 2000 .

[13]  Andreas Fischer,et al.  Correlation of amplitude modulation to inflow characteristics , 2014 .

[14]  G.J.W. Van Bussel,et al.  Influence of atmospheric stability on wind turbine loads , 2013 .

[15]  Jason Jonkman,et al.  Atmospheric and Wake Turbulence Impacts on Wind Turbine Fatigue Loading: Preprint , 2012 .

[16]  Vasilis Riziotis,et al.  Benchmarking aerodynamic prediction of unsteady rotor aerodynamics of active flaps on wind turbine blades using ranging fidelity tools , 2016 .

[17]  J. Sørensen,et al.  Wind Climate Parameters for Wind Turbine Fatigue Load Assessment , 2016 .

[18]  J. G. Leishman,et al.  A Semi-Empirical Model for Dynamic Stall , 1989 .

[19]  Stefanie Hellweg,et al.  Wind Power Electricity: The Bigger the Turbine, The Greener the Electricity? , 2012, Environmental science & technology.

[20]  Helge Aagaard Madsen,et al.  Comparison of measured and simulated loads for the Siemens SWT 2.3 operating in wake conditions at the Lillgrund Wind Farm using HAWC2 and the dynamic wake meander model , 2015 .

[21]  J. G. Schepers,et al.  Engineering models in wind energy aerodynamics : Development, implementation and analysis using dedicated aerodynamic measurements , 2012 .

[22]  Torben J. Larsen,et al.  Wake modeling and simulation , 2008 .

[23]  G. Schepers,et al.  Validation of the Beddoes–Leishman dynamic stall model for horizontal axis wind turbines using MEXICO data , 2013 .

[24]  Herbert J. Sutherland,et al.  On the Fatigue Analysis of Wind Turbines , 1999 .

[25]  Abdolrahim Rezaeiha,et al.  Effect of pitch angle on power performance and aerodynamics of a vertical axis wind turbine , 2017 .

[26]  C. Strangfeld,et al.  Airfoil in a high amplitude oscillating stream , 2016, Journal of Fluid Mechanics.

[27]  Niels N. Sørensen,et al.  Fluid–structure interaction computations for geometrically resolved rotor simulations using CFD , 2016 .

[28]  Wieslaw Ostachowicz,et al.  MARE-WINT: New Materials and Reliability in Offshore Wind Turbine Technology , 2016 .

[29]  Dale M Pitt,et al.  Rotor dynamic inflow derivatives and time constants from various inflow models , 1980 .

[30]  Christian Oliver Paschereit,et al.  Finite micro-tab system for load control on a wind turbine , 2014 .

[31]  Sanford Fleeter,et al.  Influence of inflow conditions on turbine loading and wake structures predicted by large eddy simulations using exact geometry , 2016 .

[33]  J. Michalakes,et al.  A numerical study of the effects of atmospheric and wake turbulence on wind turbine dynamics , 2012 .

[34]  H. F. Veldkamp,et al.  Chances in wind energy: A probalistic approach to wind turbine fatigue design , 2006 .

[35]  G.J.W. Van Bussel,et al.  Design of HAWT airfoils tailored for active flow control , 2017 .

[36]  G.J.W. Van Bussel,et al.  Definition of the equivalent atmospheric stability for wind turbine fatigue load assessment , 2014 .

[37]  B. H. Bulder,et al.  Fatigue Equivalent Load Cycle Method A General Method to Compare the Fatigue Loading of Different Load Spectrums , 1995 .

[38]  Daniel Micallef,et al.  Estimation of loads on a horizontal axis wind turbine operating in yawed flow conditions , 2015 .

[39]  R. E. Wilson,et al.  Aerodynamic performance of wind turbines. Final report , 1976 .

[40]  H. Madsen,et al.  A Beddoes-Leishman type dynamic stall model in state-space and indicial formulations , 2004 .

[41]  J. Gordon Leishman,et al.  Challenges in Modeling the Unsteady Aerodynamics of Wind Turbines , 2002 .

[42]  H. Madsen,et al.  A coupled near and far wake model for wind turbine aerodynamics , 2020, Wind Energy.

[43]  Leonardo Bergami,et al.  Sizing and control of trailing edge flaps on a smart rotor for maximum power generation in low fatigue wind regimes , 2016 .

[44]  Abdolrahim Rezaeiha,et al.  CFD simulation of a vertical axis wind turbine operating at a moderate tip speed ratio: guidelines for minimum domain size and azimuthal increment , 2017 .

[45]  K. Pierce,et al.  Prediction of wind turbine rotor loads using the Beddoes-Leishman model for dynamic stall , 1995 .

[46]  Spyros G. Voutsinas,et al.  VORTEX METHOD APPLICATION FOR AERODYNAMIC LOADS ON ROTOR BLADES , 2013 .

[47]  Gunner Chr. Larsen,et al.  Validation of the dynamic wake meander model for loads and power production in the Egmond aan Zee wind farm , 2013 .

[48]  Anders Melchior Hansen,et al.  Development of an anisotropic beam finite element for composite wind turbine blades in multibody system , 2013 .

[49]  J. Michalakes,et al.  A Numerical Study of Atmospheric and Wake Turbulence Impacts on Wind Turbine Fatigue Loadings , 2013 .

[50]  Niels N. Sørensen,et al.  Simulations of a rotor with active deformable trailing edge flaps in half-wake inflow: Comparison of EllipSys 3D with HAWC2 , 2012 .

[51]  Michael Hölling,et al.  Wind Energy - Impact of Turbulence , 2014 .

[52]  Arne V. Johansson,et al.  Pressure fluctuation in high-Reynolds-number turbulent boundary layer: results from experiments and DNS , 2012 .

[53]  Hui Hu,et al.  Dynamic wind loads and wake characteristics of a wind turbine model in an atmospheric boundary layer wind , 2012 .

[54]  J. Mann Wind field simulation , 1998 .

[55]  Michael P. Kinzel,et al.  Space-Time Loadings on Wind Turbine Blades Driven by Atmospheric Boundary Layer Turbulence , 2011 .

[56]  Frank N. Coton,et al.  A Modified Dynamic Stall Model for Low Mach Numbers , 2008 .

[57]  A. J. Bullmore,et al.  Mechanisms of amplitude modulation in wind turbine noise , 2014 .

[58]  Li Wang,et al.  Measurement and analysis of wind turbine blade mechanical load , 2015 .

[59]  Christian Oliver Paschereit,et al.  Matched pitch rate extensions to dynamic stall on rotor blades , 2017 .

[60]  G.A.M. van Kuik,et al.  Review of state of the art in smart rotor control research for wind turbines , 2010 .

[61]  R. P. Coleman,et al.  Evaluation of the Induced-Velocity Field of an Idealized Helicopter Rotor , 1945 .

[62]  F. Grasso,et al.  Blade element momentum modeling of inflow with shear in comparison with advanced model results , 2012 .

[63]  Shun Kang,et al.  Predictions of unsteady HAWT aerodynamics in yawing and pitching using the free vortex method , 2014 .