ADVANCED ENERGY COORDINATION FOR HYBRID RENEWABLE SYSTEMS

Abstract

The increasing demand for clean and reliable energy has accelerated the development of hybrid renewable power systems. This study presents an Advanced Energy Coordination strategy for a hybrid photovoltaic (PV), wind, and fuel cell system designed to improve power reliability, efficiency, and system stability under varying environmental conditions. The proposed framework integrates advanced power conditioning, intelligent load sharing, and an optimized control strategy to manage the intermittent nature of PV and wind sources while utilizing the fuel cell as a stable backup unit. The system ensures balanced power flow by dynamically adjusting energy contributions based on real-time generation and load requirements. Simulation results demonstrate significant improvements in voltage regulation, reduced power fluctuations, and better utilization of renewable resources compared to conventional distribution methods. The enhanced energy distribution model offers a robust solution for sustainable energy applications, microgrid development, and rural electrification scenarios.