Optimizing Lidars for Wind Turbine Control Applications - Results from the IEA Wind Task 32 Workshop

IEA Wind Task 32 serves as an international platform for the research community and industry to identify and mitigate barriers to the use of lidars in wind energy applications. The workshop “Optimizing Lidar Design for Wind Energy Applications” was held in July 2016 to identify lidar system properties that are desirable for wind turbine control applications and help foster the widespread application of lidar-assisted control (LAC). One of the main barriers this workshop aimed to address is the multidisciplinary nature of LAC. Since lidar suppliers, wind turbine manufacturers, and researchers typically focus on their own areas of expertise, it is possible that current lidar systems are not optimal for control purposes. This paper summarizes the results of the workshop, addressing both practical and theoretical aspects, beginning with a review of the literature on lidar optimization for control applications. Next, barriers to the use of lidar for wind turbine control are identified, such as availability and reliability concerns, followed by practical suggestions for mitigating those barriers. From a theoretical perspective, the optimization of lidar scan patterns by minimizing the error between the measurements and the rotor effective wind speed of interest is discussed. Frequency domain methods for directly calculating measurement error using a stochastic wind field model are reviewed and applied to the optimization of several continuous wave and pulsed Doppler lidar scan patterns based on commercially-available systems. An overview of the design process for a lidar-assisted pitch controller for rotor speed regulation highlights design choices that can impact the usefulness of lidar measurements beyond scan pattern optimization. Finally, using measurements from an optimized scan pattern, it is shown that the rotor speed regulation achieved after optimizing the lidar-assisted control scenario via time domain simulations matches the performance predicted by the theoretical frequency domain model.

[1]  Lucy Y. Pao,et al.  Optimal blade pitch control with realistic preview wind measurements , 2016 .

[2]  Carlo L. Bottasso,et al.  LiDAR-enabled model predictive control of wind turbines with real-time capabilities , 2014 .

[3]  Ulrich Konigorski,et al.  Lidar-Assisted Feedforward Individual Pitch Control to Compensate Wind Shear and Yawed Inflow , 2016 .

[4]  Po-Wen Cheng,et al.  Wake redirecting using feedback control to improve the power output of wind farms , 2016, 2016 American Control Conference (ACC).

[5]  David Schlipf Prospects of multivariable feedforward control of wind turbines using lidar , 2016, 2016 American Control Conference (ACC).

[6]  David Schlipf,et al.  Realistic simulations of extreme load cases with lidar-based feedforward control , 2017 .

[7]  Michael Harris,et al.  Advance measurement of gusts by laser anemometry , 2007 .

[8]  L. Kristensen On longitudinal spectral coherence , 1979 .

[9]  Poul Ejnar Sørensen,et al.  Control design for a pitch-regulated, variable speed wind turbine , 2005 .

[10]  Alan Wright,et al.  Field Test Results from Lidar Measured Yaw Control for Improved Yaw Alignment with the NREL Controls Advanced Research Turbine: Preprint , 2014 .

[11]  John Hauser,et al.  Optimal trajectory tracking control for wind turbines during operating region transitions , 2013, 2013 American Control Conference.

[12]  David Schlipf,et al.  Prospects of a collective pitch control by means of predictive disturbance compensation assisted by wind speed measurements , 2008 .

[13]  David Schlipf,et al.  Field Testing LIDAR Based Feed-Forward Controls on the NREL Controls Advanced Research Turbine , 2013 .

[14]  Carlo L. Bottasso,et al.  Aero-servo-elastic modeling and control of wind turbines using finite-element multibody procedures , 2006 .

[15]  Alan Wright,et al.  The use of preview wind measurements for blade pitch control , 2011 .

[16]  David Schlipf,et al.  Model of the Correlation between Lidar Systems and Wind Turbines for Lidar-Assisted Control , 2012 .

[17]  Niels Kjølstad Poulsen,et al.  Model predictive control of wind turbines using uncertain LIDAR measurements , 2013, 2013 American Control Conference.

[18]  Eric Jeffrey Simley,et al.  Wind Speed Preview Measurement and Estimation for Feedforward Control of Wind Turbines , 2015 .

[19]  Roger A. Pielke,et al.  Turbulence characteristics along several towers , 1970 .

[20]  Alan Wright,et al.  Field-test results using a nacelle-mounted lidar for improving wind turbine power capture by reducing yaw misalignment , 2014 .

[21]  Torben Mikkelsen,et al.  Precision and shortcomings of yaw error estimation using spinner-based light detection and ranging , 2013 .

[22]  Po-Wen Cheng,et al.  Direct Speed Control using LIDAR and turbine data , 2013, 2013 American Control Conference.

[23]  Torben Mikkelsen,et al.  A spinner‐integrated wind lidar for enhanced wind turbine control , 2013 .

[24]  Kathryn E. Johnson,et al.  Lidar-enhanced wind turbine control: Past, present, and future , 2016, 2016 American Control Conference (ACC).

[25]  Michael Harris,et al.  Introduction to continuous-wave Doppler lidar , 2012 .

[26]  David Schlipf,et al.  Nonlinear model predictive control of wind turbines using LIDAR , 2013 .

[27]  J. Jonkman,et al.  Definition of a 5-MW Reference Wind Turbine for Offshore System Development , 2009 .

[28]  Torben Mikkelsen,et al.  On mean wind and turbulence profile measurements from ground-based wind lidars: limitations in time and space resolution with continuous wave and pulsed lidar systems , 2009 .

[29]  Alan Wright,et al.  Field testing of feedforward collective pitch control on the CART2 using a nacelle-based lidar scanner , 2014 .

[30]  Lucy Y. Pao,et al.  Reducing LIDAR wind speed measurement error with optimal filtering , 2013, 2013 American Control Conference.

[31]  Lucy Y. Pao,et al.  Correlation between Rotating LIDAR Measurements and Blade Effective Wind Speed , 2013 .

[32]  Lucy Y. Pao,et al.  A spectral model for evaluating the effect of wind evolution on wind turbine preview control , 2013, 2013 American Control Conference.

[33]  Lars Christian Henriksen,et al.  Sensor comparison study for load alleviating wind turbine pitch control , 2014 .

[34]  B. Ll. Jones,et al.  Real‐time wind field reconstruction from LiDAR measurements using a dynamic wind model and state estimation , 2016 .

[35]  Lucy Y. Pao,et al.  A longitudinal spatial coherence model for wind evolution based on large-eddy simulation , 2015, 2015 American Control Conference (ACC).

[36]  Neil Kelley,et al.  Analysis of Light Detection and Ranging Wind Speed Measurements for Wind Turbine Control , 2014 .

[37]  O Hugues-Salas,et al.  Wind turbine control applications of turbine-mounted LIDAR , 2014 .

[38]  I. Horowitz Synthesis of feedback systems , 1963 .

[39]  David Schlipf,et al.  Three Dimensional Dynamic Model Based Wind Field Reconstruction from Lidar Data , 2014 .

[40]  Lucy Y. Pao,et al.  Importance of lidar measurement timing accuracy for wind turbine control , 2014, 2014 American Control Conference.

[41]  Torben Mikkelsen,et al.  Evaluation of wind flow with a nacelle-mounted, continuous wave wind lidar , 2014 .

[42]  Antoine Borraccino,et al.  Calibration report for Avent 5-beam Demonstrator lidar , 2016 .

[43]  Torben Mikkelsen,et al.  Full two-dimensional rotor plane inflow measurements by a spinner-integrated wind lidar , 2013 .

[44]  Lucy Y. Pao,et al.  Comparison of Two Independent LIDAR-Based Pitch Control Designs , 2012 .

[45]  David Schlipf,et al.  Turbulent Extreme Event Simulations for Lidar-Assisted Wind Turbine Control , 2016 .

[46]  Martin Kühn,et al.  Prospects of optimization of energy production by LIDAR assisted control of wind turbines , 2011 .

[47]  George Scott,et al.  Sensitivity Analysis of Wind Plant Performance to Key Turbine Design Parameters: A Systems Engineering Approach , 2014 .

[48]  Alan Wright,et al.  Assessment and Optimization of Lidar Measurement Availability for Wind Turbine Control: Preprint , 2014 .

[49]  David Schlipf,et al.  Lidar-assisted control concepts for wind turbines , 2016 .

[50]  Avishek A. Kumar,et al.  Field Testing of LIDAR-Assisted Feedforward Control Algorithms for Improved Speed Control and Fatigue Load Reduction on a 600-kW Wind Turbine: Preprint , 2015 .

[51]  Frank Allgöwer,et al.  Look-ahead cyclic pitch control using LIDAR , 2010 .

[52]  Lucy Y. Pao,et al.  Investigation of the Impact of the Upstream Induction Zone on LIDAR Measurement Accuracy for Wind Turbine Control Applications using Large-Eddy Simulation , 2014 .

[53]  S. Grossmann The Spectrum of Turbulence , 2003 .

[54]  Nicolai Cosack,et al.  Detection of Wind Evolution and Lidar Trajectory Optimization for Lidar-Assisted Wind Turbine Control , 2015 .