Optimal Energy Storage Sizing and Control for Wind Power Applications

The variable output of a large wind farm presents many integration challenges, especially at high levels of penetration. The uncertainty in the output of a large wind plant can be covered by using fast-acting dispatchable sources, such as natural gas turbines or hydro generators. However, using dispatchable sources on short notice to smooth the variability of wind power can increase the cost of large-scale wind power integration. To remedy this, the inclusion of large-scale energy storage at the wind farm output can be used to improve the predictability of wind power and reduce the need for load following and regulation hydro or fossil-fuel reserve generation. This paper presents sizing and control methodologies for a zinc-bromine flow battery-based energy storage system. The results show that the power flow control strategy does have a significant impact on proper sizing of the rated power and energy of the system. In particular, artificial neural network control strategies resulted in significantly lower cost energy storage systems than simplified controllers. The results show that through more effective control and coordination of energy storage systems, the predictability of wind plant outputs can be increased and the cost of integration associated with reserve requirements can be decreased.

[1]  M. Baran,et al.  Improved wind farm’s power availability by battery energy storage systems: modeling and control , 2008, 2008 34th Annual Conference of IEEE Industrial Electronics.

[2]  B.M. Wilamowski,et al.  Neural network architectures and learning algorithms , 2009, IEEE Industrial Electronics Magazine.

[3]  B. Roberts,et al.  Capturing grid power , 2009, IEEE Power and Energy Magazine.

[4]  Benoit Robyns,et al.  Control and Performance Evaluation of a Flywheel Energy-Storage System Associated to a Variable-Speed Wind Generator , 2006, IEEE Transactions on Industrial Electronics.

[5]  Srdjan M. Lukic,et al.  Energy Storage Systems for Automotive Applications , 2008, IEEE Transactions on Industrial Electronics.

[6]  J.P. Barton,et al.  Energy storage and its use with intermittent renewable energy , 2004, IEEE Transactions on Energy Conversion.

[7]  Subhashish Bhattacharya,et al.  Optimal Control of Battery Energy Storage for Wind Farm Dispatching , 2010, IEEE Transactions on Energy Conversion.

[8]  Susan M. Schoenung,et al.  Long vs. short-term energy storage:sensitivity analysis. , 2007 .

[9]  G. Joos,et al.  Supercapacitor Energy Storage for Wind Energy Applications , 2007, IEEE Transactions on Industry Applications.

[10]  Chengxiong Mao,et al.  Use of Battery Energy Storage System to Improve the Power Quality and Stability of Wind Farms , 2006, 2006 International Conference on Power System Technology.

[11]  Ha Thu Le,et al.  Sizing energy storage systems for wind power firming: An analytical approach and a cost-benefit analysis , 2008, 2008 IEEE Power and Energy Society General Meeting - Conversion and Delivery of Electrical Energy in the 21st Century.

[12]  M. Khatibi,et al.  An analysis for increasing the penetration of renewable energies by optimal sizing of pumped-storage power plants , 2008, 2008 IEEE Canada Electric Power Conference.

[13]  Alfred Rufer,et al.  Hybrid Energy Storage System Based on Compressed Air and Super-Capacitors with Maximum Efficiency Point Tracking (MEPT) , 2006 .

[14]  Jorge Moreno,et al.  Energy-management system for a hybrid electric vehicle, using ultracapacitors and neural networks , 2006, IEEE Transactions on Industrial Electronics.

[15]  Giuseppe Marco Tina,et al.  Optimal hydrogen storage sizing for wind power plants in day ahead electricity market , 2007 .

[16]  D. Signorini,et al.  Neural networks , 1995, The Lancet.

[17]  A.H. Gastaj,et al.  Optimal sizing of hybrid power system using genetic algorithm , 2005, 2005 International Conference on Future Power Systems.

[18]  A. Price Technologies for energy storage-Present and future: flow batteries , 2000, 2000 Power Engineering Society Summer Meeting (Cat. No.00CH37134).

[19]  Roberto Cárdenas,et al.  Control strategies for enhanced power smoothing in wind energy systems using a flywheel driven by a vector-controlled induction machine , 2001, IEEE Trans. Ind. Electron..

[20]  G. Balzer,et al.  The Impact of the "Wind Farm - Battery" Unit on the Power System Stability and Control , 2007, 2007 IEEE Lausanne Power Tech.

[21]  G. Joos,et al.  Sizing and power management strategies for battery storage integration into wind-diesel systems , 2008, 2008 34th Annual Conference of IEEE Industrial Electronics.

[22]  Allan E. Ingram Storage Options and Sizing for Utility Scale Integration of Wind Energy Plants , 2005 .

[23]  S. Bhattacharya,et al.  Control Strategies for Battery Energy Storage for Wind Farm Dispatching , 2009, IEEE Transactions on Energy Conversion.

[24]  Gerd Balzer,et al.  COMPUTATION DIMENSIONING OF A SODIUM-SULPHUR BATTERY AS A BACKUP OF LARGE WIND FARM , 2008 .

[25]  Pavol Bauer,et al.  Energy storage and power management for typical 4Q-load , 2008 .

[26]  Binggang Cao,et al.  The application of combinatorial optimization by Genetic Algorithm and Neural Network , 2008, 2008 3rd IEEE Conference on Industrial Electronics and Applications.

[27]  Adrian Ilinca,et al.  Energy storage systems—Characteristics and comparisons , 2008 .

[28]  James M. Eyer,et al.  Benefit/cost framework for evaluating modular energy storage : a study for the DOE energy storage systems program. , 2008 .

[29]  Marcelo Godoy Simões,et al.  Distributed Intelligent Energy Management System for a Single-Phase High-Frequency AC Microgrid , 2007, IEEE Transactions on Industrial Electronics.