Repetitive Individual Pitch Control for Load Alleviation at Variable Rotor Speed

Kallen, T.; Zierath, János; Dickler, Sebastian; Konrad, Thomas; Jassmann, Uwe; Abel, Dirk

doi:10.1088/1742-6596/1618/2/022055

Cited by 4 publications

(6 citation statements)

References 12 publications

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“…When the TI increases, the stochastic part of the load variations, and hence of the DEL, increases, yet both IPCs have a hard time dealing with these additional fatigue loads. Several contributions in the literature have addressed the challenge of alleviating non‐deterministic loads, like Kallen et al 21 and Bottasso et al, 58 by explicitly designing the controller with two layers: one in charge of the periodical loads and the other focusing on the stochastic ones typically resulting from turbulence. Though the RL‐IPC controller does not have such a two‐layer architecture, it can detect gusts through the sensing module and directly react to them by adapting the pitching amplitude and phase of the blades.…”

Section: Resultsmentioning

confidence: 99%

“…On the other hand, repetitive control has also been reported due to its ability to deal with periodic signals and track periodic references 20 . Kallen 21 takes advantage of that and uses the information perceived on a blade to anticipatively pass it on to the next blade. Friis 22 used repetitive model predictive control by including a repetitive wind disturbance in the MPC prediction.…”

Section: Introductionmentioning

confidence: 99%

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A reinforcement‐learning approach for individual pitch control

et al. 2022

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Individual pitch control has shown great capability of alleviating the oscillating loads experienced by wind turbine blades due to wind shear, atmospheric turbulence, yaw misalignment, or wake impingement. This work presents a novel controller structure that relies on the separation of low-level control tasks and high-level ones. It is based on a neural network that modulates basic periodic pitch angle signals. This neural network is trained with reinforcement learning, a trial and error way of acquiring skills, in a low-fidelity environment exempt from turbulence. The trained controller is further deployed in large eddy simulations to assess its performances in turbulent and waked flows. Results show that the method enables the neural network to learn how to reduce fatigue loads and to exploit that knowledge to complex turbulent flows.When compared to a state-of-the-art individual pitch controller, the one introduced here presents similar load alleviation capacities at reasonable turbulence intensity levels, while displaying very smooth pitching commands by nature.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A reinforcement‐learning approach for individual pitch control

et al. 2022

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“…Proportional-integral (PI) controllers are typically used as the tilt and yaw controllers [8], and studies using optimal controllers, robust controllers, and fuzzy controllers have been conducted [13][14][15][16][17]. In addition to the 1P component of the asymmetric moment load acting on the blade, research was also conducted on using additional individual pitch control inputs to reduce higher-order harmonic components above 2P [18][19][20][21]. Just as gain scheduling is applied to compensate for the nonlinearity of the power coefficient in the collective pitch controller [3], gain scheduling can also be applied to compensate for the nonlinearity of the thrust coefficient in the individual pitch controller [21].…”

Section: Introductionmentioning

confidence: 99%

A Study of a Gain-Scheduled Individual Pitch Controller for an NREL 5 MW Wind Turbine

Lim

2024

Energies

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In order to reduce the asymmetric load acting on the blades of MW-class wind turbines, it is necessary to apply an individual pitch controller that independently adjusts the pitch angles of the three blades. This paper takes a new look at the relationship between the individual pitch controller applied to MW-class wind turbines and the vibration mode of the blades. The purpose of this study is to propose a method in which the individual pitch controller further reduces the 1P component of the bending moment in the out-of-plane direction acting on the blade, without exciting the in-plane vibration mode of the blade within the entire wind speed range, from the rated wind speed to the cut-out wind speed. To this end, a problem related to the excitation of the blade’s vibration mode that may occur when applying the individual pitch controller to an NREL 5 MW wind turbine is examined, and a method that uses gain scheduling to overcome this problem is presented. It is confirmed that it is possible to solve the problem of exciting the first-order vibration mode in the in-plane direction of the blade that can occur in the high wind speed range by applying the proposed gain scheduling method to the individual pitch controller aimed at reducing the 1P component of the out-of-plane bending moment of the blade.

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“…It is thus of a crucial importance to deploy efforts in the prediction of the fatigue damage a wind turbine will suffer during its operation, either to optimally design the wind farm or to develop load alleviation strategies that can be used during the wind farm operation. Those strategies encompass load alleviation at a wind turbine level 3–5 but also schemes aiming at ensuring a more uniform and potentially reduced wear and tear of the rotors at a wind farm scale 6,7 …”

Section: Introductionmentioning

confidence: 99%

“…For some wind turbine subassemblies, the downtime associated with repair may be significant, mainly in the offshore environment: This decreases the wind turbine reliability, directly impacting the Levelized Cost of Energy, as demonstrated in Dao et al 2 It is thus of a crucial importance to deploy efforts in the prediction of the fatigue damage a wind turbine will suffer during its operation, either to optimally design the wind farm or to develop load alleviation strategies that can be used during the wind farm operation. Those strategies encompass load alleviation at a wind turbine level [3][4][5] but also schemes aiming at ensuring a more uniform and potentially reduced wear and tear of the rotors at a wind farm scale. 6,7 As the development of control strategies or the potential arrangement of a future wind farm often relies on numerical studies, it is essential that the simulation tools provide accurate blade/structural loads and fatigue estimates.…”

mentioning

confidence: 99%

Assessment of an actuator disk‐based approach for the prediction of fatigue loads in a perspective of wind farm‐scale application

2022

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This work aims at assessing the loads and the fatigue estimates computed using an advanced actuator disk (AD) method coupled to large eddy simulation, at a resolution appropriate for large wind farm calculations. In order to compute pertinent fatigue loads, blade trajectories are replicated through the disk, and the AD aerodynamic forces are interpolated onto these "virtual blades" at each time step. This approach, denoted AD-B, is verified against a Vortex-Particle Mesh (VPM) method coupled to immersed lifting lines at a fine resolution, through simulations of an isolated rotor in a turbulent wind. Two different methods are used to evaluate the fatigue damages: the widely used Rainflow counting (RFC) procedure and the spectral Dirlik's approach (DK), both combined with a Palgrem-Miner rule. In the present work, the DK counting method is considered to further investigate the potential of extrapolating some loading data in the high frequencies, uncaptured by the AD-B model at a coarse resolution. The results show that the fatigue estimates computed using the RFC procedure are very similar for the VPM and the AD-B methods, thus without any modeling of the unresolved scales for the disk. Indeed, the AD-B model captures the loads of middle and large amplitudes that contribute the most to the rotor damage. The use of extrapolated loading data makes the AD-B fatigue estimates closer to the VPM ones, but the DK counting method globally leads to results that are quite different from those obtained using the RFC procedure. Further investigations are thus required for the combination of extrapolated loading information and spectral counting methods.

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Repetitive Individual Pitch Control for Load Alleviation at Variable Rotor Speed

Cited by 4 publications

References 12 publications

A reinforcement‐learning approach for individual pitch control

A reinforcement‐learning approach for individual pitch control

A Study of a Gain-Scheduled Individual Pitch Controller for an NREL 5 MW Wind Turbine

Assessment of an actuator disk‐based approach for the prediction of fatigue loads in a perspective of wind farm‐scale application

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