ISLANDED

The persistent unreliability of the national power grid in Nigeria has significantly hindered economic growth and forced residential consumers to rely on expensive, noisy, and polluting diesel generators to meet their daily electricity needs. This study investigates the technical and economic feasibility of an islanded hybrid photovoltaic (PV)–wind–battery energy system designed to reliably power a residential building in Benin City, Edo State. Using HOMER Pro simulation software, the research modeled and optimized the system for a 3-bedroom apartment with a daily load demand of 21.73 kWh, utilizing local meteorological data. The optimal system configuration was determined to include a 5 kW solar PV array, three 1 kW wind turbines, a 34.8 kWh battery bank, and a 3.5 kW converter. This configuration achieved a 100% renewable fraction and high reliability, with a Loss of Power Supply Probability (LPSP) of 0.78% and a Loss of Load Expectation (LOLE) of approximately 22 hours per year. Economic analysis revealed a Net Present Cost (NPC) of ₦132,850,500 and a Levelized Cost of Energy (LCOE) of ₦1,305/kWh, placing the system within the competitive range of diesel-based alternatives.Furthermore, a comprehensive sensitivity analysis confirmed that the system remained economically viable across all tested scenarios, affirming the suitability of hybrid renewable systems for off-grid residential applications in Nigeria

The rising cost of grid electricity and the global push for sustainable energy solutions have heightened interest in renewable-based power systems. This project presents a comprehensive reliability assessment and techno-economic analysis of an islanded (standalone) Solar Photovoltaic (PV) and Battery Energy Storage System (BESS) designed to meet the entire electrical load of the Department of Electrical and Electronics Engineering at the University of Benin. The study utilized HOMER Pro software to model, simulate, and optimize the system. A detailed load profile of the department was developed and used as the primary input, alongside solar irradiation data for the Benin City location. The system was designed to operate without any grid connection, making reliability the paramount design constraint. The optimization process aimed to find the most cost-effective system configuration that minimizes the Net Present Cost (NPC) while adhering to a strict maximum allowable capacity shortage of 1%. Using HOMER Pro software, an optimal system configuration was determined: a 180 kW solar PV array coupled with a 100 kWh Lead-acid battery bank. The system demonstrates high reliability, meeting 98.98% of the annual load demand while maintaining complete energy independence. Economic analysis shows the system achieves a Levelized Cost of Energy of ₦619.5/kWh, proving it to be a technically feasible and financially viable sustainable energy solution for the department. The study confirms that islanded PV-Battery systems can provide reliable power while offering long-term economic benefits compared to conventional alternati