Authors:
Bibhu Prasad Ganthia,Praveen B. M.,Subash Ranjan Kabat,Bijaya Kumar Mohapatra,Rabinarayan Sethi,Abdulrajak Buradi,DOI NO:
https://doi.org/10.26782/jmcms.2024.10.00004Keywords:
Battery Storage,Droop Control,Energy Management System,Microgrids,Optimization,Photovoltaic (PV),Uncertainties,Wind Energy,Abstract
The paper presents an efficient energy management system designed for a small-scale hybrid microgrid incorporating wind, solar, and battery-based energy generation systems using the droop control technique. The heart of the proposed system is the energy management system, which is responsible for maintaining power balance within the microgrid. The EMS continuously monitors variations in renewable energy generation and load demand and adjusts the operation of the energy conversion systems and battery storage to ensure optimal performance and reliability. The primary objective of the energy management system is to maintain power balance within the microgrid, even in the face of fluctuations in renewable energy generation and load demand. This involves dynamically adjusting the operation of the renewable energy sources and battery storage system to match the instantaneous power requirements of the microgrid. Overall, the paper presents a comprehensive approach to designing and implementing an efficient energy management system for a small-scale hybrid wind-solar-battery-based microgrid to extract maximum profit from electricity generation. By integrating renewable energy sources with energy storage and advanced control algorithms, the proposed system aims to enhance the reliability, stability, and sustainability of the microgrid's power supply.Refference:
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