With the development of civilization and technology, increasing attention has been given to energy issues, of which the use of electricity is among the most widely discussed. By the use of transformers, transmission capacity can be improved to reduce power loss during the transmission process. Still, some portion of the power is converted into heat in the transformer windings and core, causing temperature increase of the transformer, shortening the life span of the transformer, and reducing the transformer capacity. Current cooling methods include the use of pumps, fans, water coolers, etc. However, they come with problems like high power consumption, noise, and maintenance difficulties. Thus, the application of shallow geothermal energy is considered to be an energy efficient cooling method. Moreover, the energy itself can be captured using the borehole heat exchanger. This study focuses on the test results of the oil-immersed transformer cooling system combined with shallow geothermal energy in order to understand its cooling performance. The temperature rise of the transformer causes internal insulating oil to circulate by natural convection. With water as working fluid, borehole heat exchanger brings the heat from the cooling equipment into the borehole and finally conducts heat transfer with the soil. Besides the comparison between ONAN Cooling (air cooling) and ONWF Cooling (shallow geothermal energy cooling), we tested the cooling system under different operating conditions. We manipulated (1) the direction of water flow, (2) load of the transformer, and (3) the water flow rate, and matched the results of the experiments and the mathematical theoretical model. The results showed that the cooling system with shallow geothermal energy effectively cooled down the transformer, with a drop in average oil temperature of about 30~40oC. The cooling performance also varied for different directions of water flow to cool down high temperatures. Moreover, the higher the water flow rate, the greater the cooling capacity. The theory and results of the experiment are in good consistency. Thus, this study may be used as a reference for selecting proper transformer capacity as well as providing a basis for follow-up studies.