Sliding Mode Control Strategy for Wind Turbine Power Maximization

Barambones, Óscar

doi:10.3390/en5072310

Cited by 48 publications

(39 citation statements)

References 19 publications

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“…One of them is to optimize the capture of energy from the wind utilizing effective control strategies [4][5][6][7]. The contributions of these studies include new control structures, even for the aeroturbine mechanical part [4,6,7] and the electrical components [5][6][7] that overcome some of the drawbacks of existing control methods. For the mechanical part control, the control design is generally based on a local linearized model of the WTS around its operating points [4].…”

Section: Introductionmentioning

confidence: 99%

“…For the mechanical part control, the control design is generally based on a local linearized model of the WTS around its operating points [4]. Some nonlinear controllers were also proposed assuming that the wind turbine operates under steady state conditions [6,7]. For the generator, a doubly fed induction generator (DFIG) with a power converter is a common and efficient configuration to transfer the mechanical energy from the variable speed rotor to a constant frequency electrical grid [6].…”

Section: Introductionmentioning

confidence: 99%

“…The stator is directly connected to the grid while the rotor is fed through a variable frequency convertor. In order to produce electrical active power at constant voltage and frequency, the active power flow between the rotor circuit and the grid is controlled both in magnitude and direction by controlling the stator flux and rotor current of the asynchronous generator using standard nonlinear [5,6] and/or adaptive control techniques [7,8].…”

Section: Introductionmentioning

confidence: 99%

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Modeling and Design Optimization of Variable-Speed Wind Turbine Systems

Eminoğlu

Ayasun

2014

Energies

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As a result of the increase in energy demand and government subsidies, the usage of wind turbine system (WTS) has increased dramatically. Due to the higher energy production of a variable-speed WTS as compared to a fixed-speed WTS, the demand for this type of WTS has increased. In this study, a new method for the calculation of the power output of variable-speed WTSs is proposed. The proposed model is developed from the S-type curve used for population growth, and is only a function of the rated power and rated (nominal) wind speed. It has the advantage of enabling the user to calculate power output without using the rotor power coefficient. Additionally, by using the developed model, a mathematical method to calculate the value of rated wind speed in terms of turbine capacity factor and the scale parameter of the Weibull distribution for a given wind site is also proposed. Design optimization studies are performed by using the particle swarm optimization (PSO) and artificial bee colony (ABC) algorithms, which are applied into this type of problem for the first time. Different sites such as Northern and Mediterranean sites of Europe have been studied. Analyses for various parameters are also presented in order to evaluate the effect of rated wind speed on the design parameters and produced energy cost. Results show that proposed models are reliable and very useful for modeling and optimization of WTSs design by taking into account the wind potential of the region. Results also show that the PSO algorithm has better performance than the ABC algorithm for this type of problem.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Modeling and Design Optimization of Variable-Speed Wind Turbine Systems

Eminoğlu

Ayasun

2014

Energies

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“…The most important technical aspects are the choice of HVDC converter topology [11][12][13][14], the necessity of dc/dc converters [15,16], the need for protection schemes [17][18][19], dynamic stability issues [20][21][22], and power-flow control strategies [23][24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Operation and Power Flow Control of Multi-Terminal DC Networks for Grid Integration of Offshore Wind Farms Using Genetic Algorithms

et al. 2012

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For achieving the European renewable electricity targets, a significant contribution is foreseen to come from offshore wind energy. Considering the large scale of the future planned offshore wind farms and the increasing distances to shore, grid integration through a transnational DC network is desirable for several reasons. This article investigates a nine-node DC grid connecting three northern European countries-namely UK, The Netherlands and Germany. The power-flow control inside the multi-terminal DC grid based on voltage-source converters is achieved through a novel method, called distributed voltage control (DVC). In this method, an optimal power flow (OPF) is solved in order to minimize the transmission losses in the network. The main contribution of the paper is the utilization of a genetic algorithm (GA) to solve the OPF problem while maintaining an N-1 security constraint. After describing main DC network component models, several case studies illustrate the dynamic behavior of the proposed control method.

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“…In previous works (e.g., [2]), it has been proposed the use of classical sliding mode control for WT control. Such approaches deal efficiently with the power regulation objective and provide the advantage of robustness against system uncertainties and perturbations but its well-known drawback has been the discontinuous behavior of the computed control inputs that may derive into a high-frequency oscillation known as chattering.…”

Section: Introductionmentioning

confidence: 99%

Super-twisting controllers for wind turbines

Tutivén¹,

Vidal²,

Acho³

et al. 2016

REPQJ

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Abstract. The main contribution of this paper is to propose new control techniques which not only provide fault tolerance capabilities to the WT system, but also improve the overall performance of the system in both fault free and faulty conditions. Coupled nonlinear aero-hydro-servo-elastic simulations of an offshore wind turbine with jacket platform are carried out. The proposed controllers are based in the super-twisting algorithm (STA) by using feedback of the generator shaft speed as well as the fore-aft and side-to-side acceleration signals of the WT tower.

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Sliding Mode Control Strategy for Wind Turbine Power Maximization

Cited by 48 publications

References 19 publications

Modeling and Design Optimization of Variable-Speed Wind Turbine Systems

Modeling and Design Optimization of Variable-Speed Wind Turbine Systems

Operation and Power Flow Control of Multi-Terminal DC Networks for Grid Integration of Offshore Wind Farms Using Genetic Algorithms

Super-twisting controllers for wind turbines

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