This thesis explores the issue of orphaned wells, which are abandoned oil and gas wells left uncapped, leading to the release of greenhouse gases, including methane and hydrogen sulphide gas H₂S, which is lethal to humans into the atmosphere. These wells contribute significantly to global warming, as methane is a potent greenhouse gas with a high heat-trapping capability, unfortunately due to it cost an average of 100,000CAD per well for oil well plugging, most oil industry abandon these wells. The research identifies cost-effective strategies to mitigate the impact of abandoned wells using renewable technology, specifically focusing on a comprehensive system sizing approach for Olobiri oil well 17. To address the problem, the study recommends the use of solar-powered pumps to remove the remnants of oil from the wells. PVsyst software is employed to determine the appropriate pump size if the system ran continuously or solar peak hours of the location. The results demonstrate that a 5-hour running time yields higher system efficiency compared to continuous running time. Based on HOMERpro optimization result, a 50kW PV unit and 54.9kW batteries are recommended for the system setup, resulting in improved efficiency and cost-effective option during the 5-hour operation with an overall efficiency of 11.4% and pump efficiency was 37.9% compared to a continuous flow system efficiency of 5%, and the pump efficiency of 11%. For monitoring and data logging purposes, the addition of PLX DAQ aids in real-time monitoring system for the design characteristics such as PV voltage and current, inverter AC output, oil level and temperature. This low-cost data logging system allows for easy maintenance and provides valuable data for further analysis since the PLX DAQ is a Microsoft Excel’s add-on. Also, due to the site location and the specification describing the location, Lora Technology is implemented for real time monitoring, which is independent on the internet network. In conclusion, this research highlights the importance of addressing orphaned wells' environmental impact and proposes a viable solution for capping using renewable technology, particularly solar-powered pumps, to mitigate greenhouse gas emissions and the potential hazards posed by abandoned wells
