The global shift toward sustainable energy has increased demand for decentralized, reliable power solutions that integrate renewables. Hybrid renewable energy systems—combining multiple sources with storage—address the intermittency of individual renewables, making them ideal for remote or underserved communities. This study analyzes a hybrid solar-wind-battery system for community-scale electricity. The proposed architecture integrates photovoltaic arrays, wind turbines, and lithium-ion batteries via an intelligent power management unit. Using high-resolution meteorological data and realistic load profiles, we assess performance in energy reliability, economic feasibility, and environmental impact. Hourly simulations over one year show that optimized hybrid systems can achieve over 85% renewable penetration, drastically reducing fossil fuel dependence. Economic analysis, using levelized cost of energy and net present cost metrics, highlights long-term viability, especially with declining technology costs and potential carbon pricing. The findings emphasize the role of integrated renewables as cornerstones of sustainable, community-focused energy infrastructure, advancing both climate goals and energy access.
Daud Samara (Thu,) studied this question.