The decline in fossil fuel sources has led to an increase in demand for alternative energy sources. Photovoltaic (PV) technology is one of the most promising and popular renewable energy technologies. During the realoperation of PV cells about15% of thesolarradiation istransformedintoelectricity, therestintoheat that warm up the PV cell. One of the challenges when construction a home photovoltaic capacity generation order or an off-gridiron photovoltaic capacity is the deficit of energy that is converted to heat in the cosmic photovoltaic piece, resulting in a loss of 6 volts per system at a low-energy conversion rate. However, photovoltaic solar panel systems can still offer a significant benefit by optimizing the system design by incorporating an active cooling system that would recover the 6-volt energy loss. In this research, the active cooling system of the photovoltaic module system is examined and discussed. The chill plan was installed with a leg on either side of the photovoltaic piece while the water abating arrangement was on the front. The energy and exergy analysis of both cooling systems were performed separately and combined using EES, METLAP and RET Screen Expert software. The highest temperature of the photovoltaic piece outside a cooling arrangement is 64.4℃. There is a decrease in the hotness of 21.3℃, 34.3℃and 39.4℃when the air, water and integrate chilling order is used to the photovoltaic piece plan to increase the warm adeptness of air, water and connect abating of about 8%, 14% and 23%, respectively. The system power improvement of 29.32W, 32.22W, and 37.37W for air, water, and combined cooling, respectively, was recorded.