The study experimentally and theoretically investigates the heat transfer performance of the helical ground heat exchanger (HGHE). The simulation results are made with CFD code Fluent, which are found in fine agreements with the experimental data. The helical ground heat exchanger has been investigated with Fluent under different experimental parameters and working conditions. The parameters include the soil thermal conductivity, the soil heat capacity, the insulation of the center pipe, the inlet flow location and the inlet temperature of the flow. The results show that the heat dissipation rate of the HGHE with insulating the center pipe is lower than the HGHE without insulating the center pipe within 6.5 hours after start-up, but is higher than the HGHE without insulating the center pipe because avoiding the effect of the thermal interference. The heat dissipation rate of the HGHE with the inlet flow from the inside pipe is higher than from the outside pipe. Besides, the higher soil thermal conductivity and the higher soil heat capacity are benefit to elevate the heat transfer performance of the HGHE.The ground cooling is tested under the three cases. The results show that heat dissipation rates of the HGHE are 120W/m under the inlet water temperature of 45℃ and volume flow rate of 12LPM, 147.1W/m under the inlet water temperature of 45℃ and volume flow rate of 3.2LPM and 83.1W/m under the inlet water temperature of 35℃ and volume flow rate of 3.2LPM. The study constructs the relationship between the heat dissipation rate of the HGHE and soil thermal property through the 1-D model and experiment data. The thesis applies the HGHE to dissipate the heat generated from the high power LED. It keeps that the 600W LED normally works with the lamp plate of 0.3m3 and maintains the base plate temperature lower than 55℃. The ground temperature also varies periodically as the 600W LED works periodically. In addition, the base plate temperature and the heat dissipation rate of the HGHE based on a lumped model match the experimental data.