The purpose of this study is to design a high efficiency geothermal heat pump system to replace the traditional heating and cooling equipment. This work aims at using geothermal energy to reduce energy consumption and improving effectiveness of the heat pump system. In the first part of this research, performance analysis of a borehole heat exchanger was made. The results show that the temperature of the ground water and soil will not be affected by the experiment, maintaining around 22 degree. When the input heat capacity is 3 kW, flow rate is 8 LPM, and circulating water extraction rate is 20 PLM, the system has the best performance; its UA is 0.35. That is, the best input heat capacity is 3 kW and the best flow rate is 8LPM. Besides, the mechanism of the circulating water extraction has a noticeable boost on the enhancement of UA. As the amount of circulating water flow increases, both inlet and outlet water temperature become lower; meanwhile, the UA of the heat exchanger becomes larger. That proves circulating water extraction will enhance the heat exchanging capacity. In this study, a high efficiency heat pump system was designed to replace the traditional equipment through different operating modes. In addition, the locations of the pipes on the tank is based on the effect of temperature stratification. A particle swarm optimization was used for designing heat pump optimization. The primary variables include heat pump capacity, chill water tank capacity and hot water tank capacity. The experimental results indicated that the cost of life cycle would reduce to a minimum value under the assumption that heat pump capacity is 16 kW, hot water tank capacity is 1093L, and chill water tank is 1358L. The initial consumption of the geothermal heat pump is NT 84260 and the daily operating cost is NT 68. It reveals a fact that the geothermal heat pump can effectively reduce 75.40% of energy consumption.