Control of a Hybrid Excited Synchronous Generator of an Autonomous Wind Turbine Unit

Wind energy conversion systems have become a key technology to harvest wind energy worldwide. In permanent magnet synchronous generator-based wind turbine systems, the rotor position is needed for variable speed control and it uses an encoder or a speed sensor. However, these sensors lead to some obstacles, such as additional weight and cost, increased noise, complexity and reliability issues. For these reasons, the development of new sensorless control methods has become critically important for wind turbine generators. This paper aims to develop a new sensorless and adaptive control method for a surface-mounted permanent magnet synchronous generator. The proposed method includes a new model reference adaptive system, which is used to estimate the rotor position and speed as an observer. Adaptive control is implemented in the pulse-width modulated current source converter. In the conventional model reference adaptive system, the proportional-integral controller is used in the adaptation mechanism. Moreover, the proportional-integral controller is generally tuned by the trial and error method, which is tedious and inaccurate. In contrast, the proposed method is based on model predictive control which eliminates the use of speed and position sensors and also improves the performance of model reference adaptive control systems. In this paper, the proposed predictive controller is modelled in MATLAB/SIMULINK and validated experimentally on a 6-kW wind turbine generator. Test results prove the effectiveness of the control strategy in terms of energy efficiency and dynamical adaptation to the wind turbine operational conditions. The experimental results also show that the control method has good dynamic response to parameter variations and external disturbances. Therefore, the developed technique will help increase the uptake of permanent magnet synchronous generators and model predictive control methods in the wind power industry.

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One step ahead adaptive control technique for a wind turbine-synchronous generator system

IECEC-97 Proceedings of the Thirty-Second Intersociety Energy Conversion Engineering Conference (Cat. No.97CH6203) ◽

10.1109/iecec.1997.656728 ◽

2002 ◽

Cited By ~ 1

Author(s):

L. Dambrosio ◽

B. Fortunato

Keyword(s):

Adaptive Control ◽

Wind Turbine ◽

Synchronous Generator ◽

Control Technique ◽

Generator System ◽

One Step

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Control of a Stand-Alone Variable Speed Wind Turbine with a Permanent Magnet Synchronous Generator

2021 18th International Multi-Conference on Systems, Signals & Devices (SSD) ◽

10.1109/ssd52085.2021.9429307 ◽

2021 ◽

Author(s):

Albasheri Mohammed Abdulelah ◽

Bouchhida Ouahid ◽

Sofi Youcef

Keyword(s):

Wind Turbine ◽

Permanent Magnet ◽

Synchronous Generator ◽

Variable Speed ◽

Permanent Magnet Synchronous Generator ◽

Variable Speed Wind Turbine

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An internal parallel capacitor control strategy for DC-link voltage stabilization of PMSG-based wind turbine under various fault conditions

Wind Engineering ◽

10.1177/0309524x211060684 ◽

2021 ◽

pp. 0309524X2110606

Author(s):

Mohamed Metwally Mahmoud ◽

Mohamed M Aly ◽

Hossam S Salama ◽

Abdel-Moamen M Abdel-Rahim

Keyword(s):

Wind Turbine ◽

Wind Power ◽

Control Strategy ◽

Low Voltage ◽

Harmonic Distortion ◽

Synchronous Generator ◽

Parallel Capacitor ◽

Wind Generators ◽

Fast Fourier Transform Analysis ◽

Energy Conversion Systems

In recent years, wind energy conversion systems (WECSs) have been growing rapidly. Due to various advantages, a permanent magnet synchronous generator (PMSG) is an appealing solution among different types of wind generators. As wind power penetration level in the grid increases, wind power impacts the grid and vice versa. The most essential concerns in the system are voltage sag and swell, and grid code compliance, particularly for low voltage ride-through (LVRT) and high voltage ride-through (HVRT) capability, is a pressing necessity. This paper presents a parallel capacitor (PC) control strategy to enhance the LVRT and HVRT capability of PMSG. Furthermore, this study presents a method for the sizing of a PC system for the reduction of the overvoltage of the DC-link during voltage sags and swell. Fast Fourier transform analysis is used to determine the total harmonic distortion (THD) for the injected current into the grid. The obtained results illustrate the effectiveness of the proposed system in keeping the DC-link voltage below the limit, power quality improvement, and increasing the LVRT and HVRT capability. Models of wind turbine, PMSG, and PC control system are built using MATLAB/SIMULINK software.

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Wind Turbine Unit Power Prediction Based on Wavelet Neural Network Optimized by Brain Storm Optimization Algorithm

2018 IEEE 7th Data Driven Control and Learning Systems Conference (DDCLS) ◽

10.1109/ddcls.2018.8515922 ◽

2018 ◽

Cited By ~ 1

Author(s):

Qiang Guo ◽

Zhiwei Xue ◽

Longying Zhang ◽

Xiaohui Lu ◽

Yue Yin ◽

...

Keyword(s):

Neural Network ◽

Wind Turbine ◽

Optimization Algorithm ◽

Turbine Unit ◽

Wavelet Neural Network ◽

Power Prediction ◽

Unit Power ◽

Brain Storm Optimization

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Study and Design of a Horizontal Axis Wind Turbine (0.5 kW) Using Software Solid Works

Current Journal of Applied Science and Technology ◽

10.9734/cjast/2021/v40i3131546 ◽

2021 ◽

pp. 1-17

Author(s):

Hagninou E. V. Donnou ◽

Drissa Boro ◽

Jean Noé Fabiyi ◽

Marius Tovoeho ◽

Aristide B. Akpo

Keyword(s):

Wind Energy ◽

Wind Turbine ◽

Wedge Angle ◽

Three Dimensional ◽

Synchronous Generator ◽

Horizontal Axis ◽

Geometrical Shape ◽

Horizontal Axis Wind Turbine ◽

Horizontal Axis Wind Turbines ◽

Lift And Drag

In the present work, the study and design of a horizontal axis wind turbine suitable for the Cotonou site were investigated on the coast of Benin. A statistical study using the Weibull distribution was carried out on the hourly wind data measured at 10 m from the ground by the Agency for Air Navigation Safety in Africa and Madagascar (ASECNA) over the period from January 1981 to December 2014. Then, the models, techniques, tools and approaches used to design horizontal axis wind turbines were presented and the wind turbine components characteristics were determined. The numerical design and assembly of these components were carried out using SolidWorks software. The results revealed that the designed wind turbine has a power of 571W. It is equipped with a permanent magnet synchronous generator and has three aluminum blades with NACA 4412 biconvex asymmetrical profile. The values obtained for the optimum coefficient of lift and drag are estimated at 1.196 and 0.0189 respectively. The blades are characterised by an attack optimum angle estimated at 6° and the wedge angle at 5°. Their length is 2.50 m and the maximum thickness is estimated at 0.032 m for a rope length of 0.27 m. The wind turbine efficiency is 44%. The computer program designed on SolidWorks gives three-dimensional views of the geometrical shape of the wind turbine components and their assembly has allowed to visualize the compact shape of the wind turbine after export via its graphical interface. The energy quantity that can be obtained from the wind turbine was estimated at 2712,718 kWh/year. This wind turbine design study is the first of its kind for the study area. In order to reduce the technological dependence and the import of wind energy systems, the results of this study could be used to produce lower cost wind energy available on our study site.

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