Linear models‐based LPV modelling and control for wind turbines

Corcuera, Asier Díaz de; Pujana-Arrese, Aron; Ezquerra, J. M.; Milo, Aitor; Landaluze, Joseba

doi:10.1002/we.1751

Cited by 13 publications

(14 citation statements)

References 13 publications

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“…To avoid this additional measurement for the present design, the scheduling approach described in Lescher et al . and de Corcuera et al . is used.…”

Section: Clipper Liberty Wind Turbinementioning

confidence: 99%

Load reduction on a clipper liberty wind turbine with linear parameter‐varying individual blade pitch control

2017

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The increasing size of modern wind turbines also increases the structural loads caused by effects such as turbulence or asymmetries in the inflowing wind field. Consequently, the use of advanced control algorithms for active load reduction has become a relevant part of current wind turbine control systems. In this paper, an individual blade pitch control law is designed using multivariable linear parameter-varying control techniques. It reduces the structural loads both on the rotating and non-rotating parts of the turbine. Classical individual blade pitch control strategies rely on single-control loops with low bandwidth. The proposed approach makes it possible to use a higher bandwidth since it accounts for coupling at higher frequencies. A controller is designed for the utility-scale 2.5 MW Liberty research turbine operated by the University of Minnesota. Stability and performance are verified using the high-fidelity nonlinear simulation and baseline controllers that were directly obtained from the manufacturer. pitch control algorithm should not change the thrust and the torque of the turbine in order to maintain the power output at its desired level.Sophisticated, model-based state space control approaches also became possible by transforming the whole periodic system into the non-rotating frame. 7 Multivariable control designs were investigated in Bossanyi 2 on the basis of a linear quadratic regulator and in Geyler and Caselitz 8 and Vali et al. 9 on the basis of H 1 -norm optimal control. Adaptive control techniques for individual blade pitch control are presented in Magar et al. 10 Periodic control for load reduction using individual blade-pitch control was developed and tested in Stol et al. 11 These controllers aimed at the once-per-revolution (1P) blade loads and were shown to yield similar results as the classical two-SISO-loops control strategy. A direct extension of this control strategy to target loads at higher frequencies is addressed in van Engelen 12 and Petrović et al. 13 additionally using complex, higher-order transformations of the sensor data. Successful field test results of such controllers for two-bladed and three-bladed turbines is presented in Bossanyi et al. 14 However, in this case, a linear analysis of the closed-loop model to verify robustness and performance is not straightforward anymore. Further, it also requires several design steps instead of a single one. This is also true for the feedforward filters added in each of the two SISO loops to cope with the 3P loads on the nacelle proposed in Bossanyi. 15 The feedforward filters are designed using a constrained numerical optimizations technique. Because of these reasons, the classical two-SISO-loops control strategy serves for comparison in this paper. The reduction of higher frequency loads was also achieved in Barlas et al. 16 and Unguran and Kühn 17 by employing additional trailing edge flaps and in Larsen et al. 18 by using additional flow measurement sensors. The disturbance accommodation techniques that are presented in W...

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“…To avoid this additional measurement for the present design, the scheduling approach described in Lescher et al . and de Corcuera et al . is used.…”

Section: Clipper Liberty Wind Turbinementioning

confidence: 99%

Load reduction on a clipper liberty wind turbine with linear parameter‐varying individual blade pitch control

2017

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“…LPV controllers have also been used for loads reduction, where the majority of the work considers above-rated wind conditions. [23][24][25] In an attempt to improve on the standard industrial approach to designing wind turbine controllers where each control loop is designed individually, a very enthusiastic approach is proposed in a study 17 that considers multiple-input multiple-output LPV control design with multiple performance objectives, namely RS control, drivetrain damping and tower fore-aft damping. The LPV controller covers both below-rated and above-rated wind conditions and is scheduled on the (estimated) wind speed.…”

Section: Introductionmentioning

confidence: 99%

Adaptive tower damping control for offshore wind turbines

2016

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This paper deals with the problem of wind turbine tower damping control design and implementation in situations where the support structure parameters vary from their nominal design values. Such situations can, in practice, occur for onshore and especially offshore wind turbines and are attributed to aging, turbine installation, scour or marine sand dunes phenomena and biofouling. Practical experience of wind turbine manufacturing industry has shown that such effects are most easily quantified in terms of the first natural frequency of the turbine support structure. The paper brings forward a study regarding the amount to which nominal tower damping controller performance is affected by changes in the turbine natural frequency. Subsequently, an adaptive tower damping control loop is designed using linear parameter‐varying control synthesis; the proposed tower damping controller depends on this varying parameter which is assumed throughout the study to be readily available. An investigation of the fatigue load reduction performance in comparison with the original tower damping control approach is given for a generic three‐bladed horizontal‐axis wind turbine. Copyright © 2016 John Wiley & Sons, Ltd.

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“…One of the approaches to achieve these goals is to improve the wind turbine control system. There has been a lot of research activity in this area and here are some of the relevant methods, along with the referenced application to wind turbines: Maximum Power Point Tracking (MPPT) [1], Individual Pitch Control (IPC) [2], H ∞ control [3], Linear Parameter-Varying (LPV) theory [4], [5], Model Predictive Control (MPC) [6], Quantitative Feedback Theory (QFT) [7], fuzzy control [8] etc. Application of these advanced control methods to wind turbines has two main goals: (i) increase in energy conversion efficiency, (ii) reduction of wind turbine structural loads.…”

Section: Introductionmentioning

confidence: 99%

“…LPV control can be regarded as an extension of H ∞ control theory to nonlinear and parameter-varying systems [9], [10]. In [4] and [5] LPV controllers are designed with the aim to ensure stability and performance guarantees in certain wind turbine operating regions. However, obtained controllers are not self-sufficient and they require additonal control loops (not encompassed by the LPV synthesis) in order to accomplish all control objectives.…”

Section: Introductionmentioning

confidence: 99%

Adaptive H<inf>∞</inf> control of large wind turbines

Bobanac¹,

Vašak

2015

2015 IEEE International Conference on Industrial Technology (ICIT)

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Modern, large wind turbines require multiobjective, robust controllers in order to fulfill all the control objectives. In the presented work linear matrix inequality (LMI) approach to H∞ control and linear parameter-varying (LPV) theory are utilized to design multivariable, adaptive controller which aims at improving rotational speed control and at reducing tower structural loads. Designed H∞ pitch controller is implemented in the operating region above rated wind speed, in a self-sufficient structure which does not require any additonal control loops. Behaviour of the H∞ controller is compared with the baseline control system designed by classical mehtods. Simulations are performed in professional software tool GH Bladed and the subsequent analysis is carried out by calculating damage equivalent loads (DEL).

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Linear models‐based LPV modelling and control for wind turbines

Cited by 13 publications

References 13 publications

Load reduction on a clipper liberty wind turbine with linear parameter‐varying individual blade pitch control

Load reduction on a clipper liberty wind turbine with linear parameter‐varying individual blade pitch control

Adaptive tower damping control for offshore wind turbines

Adaptive H<inf>∞</inf> control of large wind turbines

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