Startseite Optimal Sizing of Battery Energy Storage System for Smoothing Power Fluctuations of a PV/Wind Hybrid System
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Optimal Sizing of Battery Energy Storage System for Smoothing Power Fluctuations of a PV/Wind Hybrid System

  • Aeidapu Mahesh EMAIL logo , Kanwarjit Singh Sandhu und Jagilinki Venkata Rao
Veröffentlicht/Copyright: 11. Februar 2017
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International Journal of Emerging Electric Power Systems
Aus der Zeitschrift International Journal of Emerging Electric Power Systems Band 18 Heft 1

Abstract

This paper presents an approach to size the battery energy storage system (BESS) for the suppression of the output power fluctuations in a solar photovoltaic (PV)/Wind hybrid energy system. The strategy presented uses a dynamic averaging technique, with a different number of samples in order to produce different smoothing levels in the output power. The key advantage of the proposed strategy is that, apart from sizing the BESS, the same strategy can be implemented in real time to perform the energy management for the system. The gravitational search algorithm (GSA) has been used to find the optimum size of the BESS which will be able to produce the required level of smoothing. The effectiveness of the proposed strategy has been verified through a case study presented and the results indicate that the strategy is effectively able to size the BESS for reduced power fluctuations from the system. To verify the robustness of the proposed strategy, the uncertainty in the climatic conditions has also been considered and the results indicate that the proposed strategy works well even in the case of a change in the climatic conditions.

Keywords: battery energy storage station; PV/wind hybrid energy system; power fluctuations

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Published Online: 2017-2-11
Published in Print: 2017-2-1

©2017 by De Gruyter

Artikel in diesem Heft

  1. Research Articles
  2. Multi-Objective Optimal Operation for Transmission Systems Considering Voltage Stability
  3. Optimal PV Location Choice Considering Static and Dynamic Constraints
  4. Platform Specific FPGA Based Hybrid Active Power Filter for Power Quality Enhancement
  5. Power Quality Improvement of Single Phase Grid Connected Photovoltaic System
  6. A Hybrid Multi-feature based Islanding Detection Technique for Grid Connected Distributed Generation
  7. Towards the Interactive Effects of Demand Response Participation on Electricity Spot Market Price
  8. Optimal Decentralized Supplementary Inverter Control Loop to Mitigate Instability in an Islanded Microgrid with Active and Passive Loads
  9. Optimal Sizing of Battery Energy Storage System for Smoothing Power Fluctuations of a PV/Wind Hybrid System
  10. Price Responsive Demand Management of an Industrial Buyer in Day-ahead Electricity Market
https://doi.org/10.1515/ijeeps-2016-0105
Schlagwörter für diesen Artikel
battery energy storage station; PV/wind hybrid energy system; power fluctuations

Artikel in diesem Heft

  1. Research Articles
  2. Multi-Objective Optimal Operation for Transmission Systems Considering Voltage Stability
  3. Optimal PV Location Choice Considering Static and Dynamic Constraints
  4. Platform Specific FPGA Based Hybrid Active Power Filter for Power Quality Enhancement
  5. Power Quality Improvement of Single Phase Grid Connected Photovoltaic System
  6. A Hybrid Multi-feature based Islanding Detection Technique for Grid Connected Distributed Generation
  7. Towards the Interactive Effects of Demand Response Participation on Electricity Spot Market Price
  8. Optimal Decentralized Supplementary Inverter Control Loop to Mitigate Instability in an Islanded Microgrid with Active and Passive Loads
  9. Optimal Sizing of Battery Energy Storage System for Smoothing Power Fluctuations of a PV/Wind Hybrid System
  10. Price Responsive Demand Management of an Industrial Buyer in Day-ahead Electricity Market
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