Energy storage system-based power control for grid-connected wind power farm

Ge, Baoming; Wang, Wenliang; Bi, Dongxue; Rogers, C. B.; Peng, Fang Zheng; Almeida, Anı́bal T. de; Abu‐Rub, Haitham

doi:10.1016/j.ijepes.2012.07.021

Cited by 71 publications

(19 citation statements)

References 29 publications

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“…The power engineering field seems to constitute approximately 90% of the references found in the ISI Web of Science. The research in this area covers many issues, e.g., use of battery storage , control of voltage in High‐voltage direct current (HVDC) wind farm (WF) grids , primary frequency control using droop curves and improved frequency support using the wind turbine (WT) rotor inertia . A good tutorial to grid frequency support by active WT power control is provided in Aho et al .…”

Section: Introductionmentioning

confidence: 99%

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Survey of wind farm control—power and fatigue optimization

2014

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The main goal of this paper is to establish the present state of the art for wind farm control. The control area that will be focused on is the mechanical/aerodynamic part, which includes the wind turbines, their power production, fatigue and wakes affecting neighbouring wind turbines. The sub‐objectives in this area of research are as follows: (i) maximizing the total wind farm power production; (ii) following a reference for the total wind farm active power; and (iii) doing this in a manner that minimizes fatigue loading for the wind turbines in the farm. Each of these sub‐objectives is discussed, including the following important control issues: choice of input and output, control method and modelling used for controller design and simulation. The available literature from industry is also considered. Finally, a conclusion is presented discussing the established results, open challenges and necessary research. Copyright © 2014 John Wiley & Sons, Ltd.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Survey of wind farm control—power and fatigue optimization

2014

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“…As a key component of VRB, the proton conductive membrane not only provides a proton conduction pathway between catholyte and anolyte, but also prevents the mixing of positive and negative electrolytes. Ideal proton conductive membranes should have the following properties: high proton conductivity to improve voltage efficiency, low vanadium permeability to reduce self-discharge, good chemical stability for long cycle life, and low price, etc [4,5].…”

Section: Introductionmentioning

confidence: 99%

Sulfonated polyimide membranes with different non-sulfonated diamines for vanadium redox battery applications

Zhang

et al. 2014

Electrochimica Acta

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“…The only way of storing the electrical energy is by converting it to other forms of energy such as mechanical energy, chemical energy, electrochemical energy, thermal energy, and electromagnetic energy . Figure gives a broad categorization of different methods of energy storage according to their forms of energy.…”

Section: Energy Storage Methodsmentioning

confidence: 99%

An updated review of energy storage systems: Classification and applications in distributed generation power systems incorporating renewable energy resources

2018

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Summary The demand of electric energy is increasing globally, and the fact remains that the major share of this energy is still being produced from the traditional generation technologies. However, the recent trends, for obvious reasons of environmental concerns, are indicating a paradigm shift towards distributed generation (DG) incorporating renewable energy resources (RERs). But there are associated challenges with high penetration of RERs as these resources are unpredictable and stochastic in nature, and as a result, it becomes difficult to provide immediate response to demand variations. This is where energy storage systems (ESSs) come to the rescue, and they not only can compensate the stochastic nature and sudden deficiencies of RERs but can also enhance the grid stability, reliability, and efficiency by providing services in power quality, bridging power, and energy management. This paper provides an extensive review of different ESSs, which have been in use and also the ones that are currently in developing stage, describing their working principles and giving a comparative analysis of important features and technical as well as economic characteristics. The wide range of storage technologies, with each ESS being different in terms of the scale of power, response time, energy/power density, discharge duration, and cost coupled with the complex characteristics matrices, makes it difficult to select a particular ESS for a specific application. The comparative analysis presented in this paper helps in this regard and provides a clear picture of the suitability of ESSs for different power system applications, categorized appropriately. The paper also brings out the associated challenges and suggests the future research directions.

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Energy storage system-based power control for grid-connected wind power farm

Cited by 71 publications

References 29 publications

Survey of wind farm control—power and fatigue optimization

Survey of wind farm control—power and fatigue optimization

Sulfonated polyimide membranes with different non-sulfonated diamines for vanadium redox battery applications

An updated review of energy storage systems: Classification and applications in distributed generation power systems incorporating renewable energy resources

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