Adaptive PI control and active tower damping compensation of a wind turbine

Lara, Manuel; Garrido, Juan; Vázquez, F.

doi:10.24084/repqj18.323

Cited by 3 publications

(4 citation statements)

References 19 publications

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“…In order to assure a bumpless transfer between controllers without sudden changes in the control signal, all the PI controllers work in the integral tracking mode updating their integral action so that the output of the unselected controllers matches with that of the active controller. It is similar to the mechanism used to achieve anti-windup and bumpless transfer between automatic/manual modes in PID controllers [62,63]. The equation of a non-interactive PI controller is as follows:…”

Section: Gain Scheduling Pi Controlmentioning

confidence: 99%

Adaptive Pitch Controller of a Large-Scale Wind Turbine Using Multi-Objective Optimization

et al. 2021

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This paper deals with the control problems of a wind turbine working in its nominal zone. In this region, the wind turbine speed is controlled by means of the pitch angle, which keeps the nominal power constant against wind fluctuations. The non-uniform profile of the wind causes tower displacements that must be reduced to improve the wind turbine lifetime. In this work, an adaptive control structure operating on the pitch angle variable is proposed for a nonlinear model of a wind turbine provided by FAST software. The proposed control structure is composed of a gain scheduling proportional–integral (PI) controller, an adaptive feedforward compensation for the wind speed, and an adaptive gain compensation for the tower damping. The tuning of the controller parameters is formulated as a Pareto optimization problem that minimizes the tower fore-aft displacements and the deviation of the generator speed using multi-objective genetic algorithms. Three multi-criteria decision making (MCDM) methods are compared, and a satisfactory solution is selected. The optimal solutions for power generation and for tower fore-aft displacement reduction are also obtained. The performance of these three proposed solutions is evaluated for a set of wind pattern conditions and compared with that achieved by a classical baseline PI controller.

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Section: Gain Scheduling Pi Controlmentioning

confidence: 99%

Adaptive Pitch Controller of a Large-Scale Wind Turbine Using Multi-Objective Optimization

et al. 2021

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“…Debido al calentamiento global, actualmente existe un gran interés por las energías renovables. En este contexto, la energía eólica tiene un papel protagonista siendo una de las fuentes que ha experimentado un mayor crecimiento en las últimas décadas [4]. Ya que alrededor del 30% de las emisiones de gases de efecto invernadero se deben a la generación de electricidad, la energía eólica ha tenido un gran impulso como una de las principales renovables para reducir dichas emisiones [2].…”

Section: Introductionunclassified

Control descentralizado de un emulador de aerogenerador VS-VP con DFIG REAL

Lara¹,

Garrido²,

Delgado³

et al. 2022

XLIII Jornadas De Automática: Libro De Actas: 7, 8 Y 9 De Septiembre De 2022, Logroño (La Rioja)

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Resulta difícil encontrar un equipo de laboratorio que permita la emulación del comportamiento de un aerogenerador, ya sea con objetivos docentes, investigadores o técnicos, por ejemplo, para el desarrollo de sistemas de control. Este trabajo presenta el control de un emulador de una turbina eólica, que combina un generador eléctrico real con las componentes aerodinámicas y mecánicas simuladas. La parte experimental consiste en un generador de inducción doblemente alimentado (DFIG) de pequeña potencia (1 kW) cuyo eje de rotación está unido de forma solidaria a un servomotor brushless de corriente continua. Este actúa de motor de arrastre emulando el par aerodinámico siguiendo un modelo no lineal. Dicho modelo también incluye el comportamiento del viento, de forma que se puedan simular condiciones reproducibles. Se ha implementado una estructura de control multivariable descentralizado con la que controlar las principales variables de un aerogenerador de velocidad variable, paso de pala variable con DFIG, en la que se ha realizado un análisis previo de la interacción existente entre las variables implicadas. Los resultados en los ensayos experimentales confirman que el emulador es capaz de reproducir el comportamiento de los aerogeneradores reales de mayor potencia y sirve de banco de ensayos tanto para fines docentes como para diseño de sistemas de control.

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“…Coudurier et al [18] proposed a control strategy to improve the effectiveness of tuned liquid column dampers (TLCD) for offshore wind turbines. Some recent researches [19][20][21][22] proposed to reduce the vibrations on wind turbine towers by operating the pitch angles of the blades. Since the power production of wind turbines relies on the wind source captured by the blades, using the pitch control to damp the wind tower vibrations may lead to a loss in the power production.…”

Section: Introductionmentioning

confidence: 99%

“…To the best of our knowledge, an active damping system inside the wind turbine tower with such a device has not been discussed yet. In addition, most current research focuses on turbulent wind conditions [10][11][12]17,21,27]. In this paper, we study the feasibility of using the TRD for vibration control of wind turbine towers.…”

Section: Introductionmentioning

confidence: 99%

Design of an Active Damping System for Vibration Control of Wind Turbine Towers

et al. 2021

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The vibration of wind turbine towers is relevant to the reliability of the wind turbine structure and the quality of power production. It produces both ultimate loads and fatigue loads threatening structural safety. This paper aims to reduce vibration in wind turbine towers using an active damper named the twin rotor damper (TRD). A single degree of freedom (SDOF) oscillator with the TRD is used to approximate the response of wind turbines under a unidirectional gusty wind with loss of the electrical network. The coincidence between the wind gust and the grid loss is studied to involve the maximum loading on the structure. The performance of the proposed damping system under the maximum loading is then evaluated on the state-of-the-art wind turbine NREL 5 MW. The effectiveness of the TRD is compared to a passive tuned mass damper (TMD) designed with similar requirements. The numerical results reveal that, at the 1st natural mode, the TRD outperforms the passive TMD by three to six times. Moreover, the results show that the TRD is effective in reducing ultimate loads on wind turbine towers.

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Adaptive PI control and active tower damping compensation of a wind turbine

Cited by 3 publications

References 19 publications

Adaptive Pitch Controller of a Large-Scale Wind Turbine Using Multi-Objective Optimization

Adaptive Pitch Controller of a Large-Scale Wind Turbine Using Multi-Objective Optimization

Control descentralizado de un emulador de aerogenerador VS-VP con DFIG REAL

Design of an Active Damping System for Vibration Control of Wind Turbine Towers

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