In the use of ground source heat pump system(GSHPs), system is usually installed with borehole heat exchanger(BHE) to use geothermal energy by exchanging thermal energy between the device and ground. Because of the growth of environmental awareness, people definitely value the safety and stability of GSHPs, additionally, different soil property and design of system have different thermal performance of heat exchanger and ability of soil temperature recovery. In this essay, theoretical analysis will be used to obtain fluid temperature solution in heat exchanger based on quasi 3D heat transfer model, and three-dimensional soil temperature solution will be obtained by Green`s function theory, image method and change of variable. Besides, The temperature solution will be proof by experimental data from study. Three cases of soil will be used to understand the performance of BHE under each case, then the case which causes worst performance of heat exchanger will be found and improved by increasing the length of borehole, in addition, the soil thermal recovery will be discussed under each case of soil and length of borehole, finally, the case which is related to design of the BHE system will be discussed. The results show Case 3 has better performance of BHE and the ability of soil thermal recovery, Case 1 has the opposite. Under the case of soil which causes worst performance of BHE, the amount of heat transfer rate will be increased by 92%. 347% and 535% and outlet temperature will be decreased by 2.4%, 8.9% and 14% for each length of borehole 50m,150m and 300m, compared to length of borehole 25m. Increasing the length of borehole will improve the performance of BHE. After closing system, soil temperature will decrease by 3.1°C，2.43°Cand 1.7°C near borehole wall for each length of borehole 50m,150 and 300m, however the influence of borehole length on the ability of soil thermal recovery is small far from BHE. Finally, in the case of BHE design, from temperature distribution of soil thermal production and recovery the optimal spacing between BHEs can be known, additionally, the requirement of power and outlet temperature for the number of series and parallel design of BHE will be obtained.