Optimum combined pitch and trailing edge flap control

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Optimum combined pitch and trailing edge flap control Lars Christian Henriksen, DTU Wind Energy Leonardo Bergami, DTU Wind Energy Peter Bjørn Andersen, DTU Wind Energy Session 5.3 Aerodynamics Danish Wind Power Research 2013 Trinity Gl. Færgevej 30, Fredericia May 27-28, 2013

Structure of the presentation Introduction Why Smart Rotors? Why a combined control framework? Model Based Control Framework Problem formulation Aerodynamic and structural models Verification: compare response on the structure Simulation Test Case Applications and results Focus on Blade Root Loads Alleviation Other applications (preliminary): Increase power capture? Conclusion and Future Work 2

Introduction Why Smart Rotors? Wind turbine operate in non uniform wind field What is a smart rotor? Combination of sensors, control unit, actuators Actively reduces the loads it has to withstand Actuators: Blade Pitch Distributed aerodynamic control (Trailing Edge Flaps) Literature: simulation and a few experiments Different configurations & conditions Widespread figures (from 5 % to 45 %) All confirm load alleviation Active load alleviation Road to up-scaling? Road to decreased Cost of Energy? Next level challenge/solution? 3

Introduction Why a combined control framework? Traditional smart rotor control approach: classic power regulation control unmodified Superimposed control for load alleviation Avoid interferences by frequency separation Aim of the investigation: Outline a combined control framework, explore its possibility, and its advantages A single control system integrates generator, pitch, and distributed device control Main focus: Application to blade load alleviation Other application are possible: Enhanced energy capture below rated conditions (preliminary) Drive train and generator load alleviation 4

Introduction Why a combined control framework? In union there is strength Load variation in IEC conditions compared to actuator variation 5 7 February 2013

Structure of the presentation Introduction Why Smart Rotors? Why a combined control framework? Model Based Control Framework Problem formulation Aerodynamic and structural models Verification: compare response on the structure Simulation Test Case Applications and results Focus on Blade Root Loads Alleviation Other applications (preliminary): Increase power capture? Conclusion and Future Work 6

Model Based control framework How: Model Based Control framework Formulated as Model Predictive Control problem: Optimal control: Minimizes objective function: s.t. a set of constraints Model Based control: Control design requires a model of the system to control Linear model Capture relevant dynamics simple model Aeroelastic problem: model structure & aerodynamics (First principle model) 7

Model Based control framework Structural model (in MPC) Modal shape function approach (simplified model): Superposition of deflection shape functions Component deflection Deflection shape Eigenmodes Tower 1 FA + 1SS, Drive Train 1 Torsion Blade: 2 Mx + 2 My 8

Model Based control framework Aerodynamic model (in MPC) Linearized BEM-based formulation: Compute a-priori (quasi-steady lookup): Integral aerodynamic forces Induction velocities Linearized dependence on flap Dynamic inflow as 1 st order filter 9

Model Based control framework Verification: Response on blade root Pitch (th0): [rad] Purple: 2+2 blade modes Blue: 3+3 blade modes Flap (fl0): [deg] Frequency [Hz] 10

Structure of the presentation Introduction Why Smart Rotors? Why a combined control framework? Model Based Control Framework Problem formulation Aerodynamic and structural models Verification: compare response on the structure Simulation Test Case Applications and results Focus on Blade Root Loads Alleviation Other applications (preliminary): Increase power capture? Conclusion and Future Work 11

Simulation Test Case Simulation Test Case Reference NREL 5 MW turbine Adaptive Trailing Edge Flaps All flaps on one blade moved as one Sensors: Shaft sp., Blade root b.mom, Tower top acc. Simulations with HAWC2 Multibody dynamics, includes torsion Unsteady BEM aerodynamics IEC conditions: class A. Iref:0.16 (wsp: 18 m/s) Focus on blade load alleviation 12

Application and results Blade Root Loads Alleviation Cycl. Loads Cycl. Flap Cycl. Pitch Almost Coll. Pitch PI 0.3 13 Flap Pitch

Application and results Blade Root Loads Alleviation Cycl. Loads Cycl. Flap Cycl. Pitch Almost Coll. Pitch 14 Flap Pitch

Cycl. Loads Application and results Blade Root Loads Alleviation DEL Variation from baseline PI case 15 Flap Pitch

Application and results Blade Root Loads: cost-benefit PI 0.3 16 7 February 2013

Application and results Effects on tower PI 0.3 17 7 February 2013

Structure of the presentation Introduction Why Smart Rotors? Why a combined control framework? Model Based Control Framework Problem formulation Aerodynamic and structural models Verification: compare response on the structure Simulation Test Case Applications and results Focus on Blade Root Loads Alleviation Other applications (preliminary): Increase power capture? Conclusion and Future Work 18

Other Applications: Increase power capture (concept) Increase power capture below rated Below rated: load alleviation not convenient Use Adaptive Trailing Edge Flaps to increase power capture? Simple BEM analysis (ideal rigid rotor): No gain at optimal Cp- Lambda Quick-check with std. controller: Sub-optimal operational pts Tower frq. IEC class II: 11-8 m/s 6 m/s 4 m/s Variations around an operational point 19

Conclusion In union there is strength applies to Smart Rotors MPC framework: Positive collaboration of pitch and flap actuators Advantages of combined actions: load alleviation Increase alleviation potential: [15 %; 18 %] 30% Spare pitch, take over with flap (or viceversa): 16 % + fl 1/3 Alleviation on other parts of the structure Possibly enable other applications (future work) Distributed actuators and sensors Enhance power capture Reducing loads in DT and speed variation 20

Thank you A Model Based Control methodology combining Blade Pitch and Adaptive Trailing Edge Flaps in a common framework Lars Christian Henriksen, DTU Wind Energy Leonardo Bergami, DTU Wind Energy Peter Bjørn Andersen, DTU Wind Energy Aeroelastics: next level challenges and solutions EWEA Wind Energy Conference, Vienna, 4-7 February 2013 21

Bonus slides 22

Other Applications: Increase power capture (concept) Increase power: cyclic Simplified analysis: optimize power from cyclic flow variations Stiff rotor in deterministic (no turbulence) wind field Results need to be confirmed in realistic conditions! Cyclic trajectories for power increase load variation IEC class II: 23

Other Applications: Increase power capture (concept) Increase power capture: cyclic trajectories Cyclic control action for increased power capture increases blade load variation As lambda increases, better Cp is in the direction of lower Ct Amplifies load variation 24

Model Based control framework Verification: Response on tower bottom Pitch (th0): [rad] Purple: 2+2 blade modes Blue: 3+3 blade modes Flap (fl0): [deg] Frequency [Hz] 25

Model Based control framework Verification: Response on tower bottom Pitch (thc): [rad] Purple: 2+2 blade modes Blue: 3+3 blade modes Flap (flc): [deg] Frequency [Hz] 26

Other Applications: Drive train load alleviation Drive train load alleviation (preliminary) Collective flap and pitch both have an effect on aero torque and shaft torsion Also modeled in the MPC framework: Frequency [Hz] Flap (fl0): [deg] Use flap to help in reduction of torque fluctuations reduce DT requirements 27 7 February 2013

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