Abstract
Air conditioning (AC) is crucial for comfortable living in countries with challenging desert climates like Qatar. In the face of such harsh conditions, cooling applications account for up to 70% of energy consumption in residential buildings. Given the high-energy demand for cooling and the region's abundant solar resources, rooftop photovoltaics (PVs) can offer an ideal sustainable solution, as peak solar supply closely aligns with the electricity demand. This study aims to enhance the feasibility, effectiveness, and system design for solar ACs in Qatar's climate conditions. A simulation model is developed to evaluate different setups of solar AC systems, utilizing local historical weather data. Optimization strategies are explored and validated for the purpose of minimizing the need for costly battery storage. Results demonstrate the efficacy of these techniques, with potential reductions in battery capacity needs of up to 15% through heat inertia management and matching of energy supply and demand. The complete elimination of battery storage is found to be possible but would be at the expense of slight compromises in end-of-day indoor comfort, which can be addressed by cooling storage solutions.