The world's fossil energy is facing a crisis of scarcity year by year, which will impact human life and economic development. Therefore, the development of alternative energy is a global imperative trend. Considering environmental protection, sustainable utilization, economic development and resource advantages, geothermal energy is one of the alternative energy sources suitable for Taiwan's development. Taiwan, located in the western margin of the Pacific Ring of Fire, is a country rich in geothermal resources. Among them, the groundwater in Yilan area is abundant. If we can find an area rich in heat sources and water sources deep in the area, it will be an ideal geothermal power plant site. In this study, the core of Hongchailin No. 1 (HCL01) and Hongchailin No. 2 (HCL02) in Yilan Hongchailin geothermal potential area was taken as samples, and the non-elastic strain recovery method (ASR) experiment was carried out to measure the three-dimensional stress field in situ. The data of water conduction fracture and weak surface state were obtained by core description, and the three-dimensional stress and fracture position state were evaluated by using the three-dimensional stress and fracture position state. The trend of slip and expansion of ground fissures and the effect of water diversion are estimated as the basis for evaluating the potential of geothermal development. The results of triaxial strain field calculated from well Hongchailin 1 show that the triaxial strain field of each sample has no specific law, and the stress field pattern corresponding to each depth sample is also different. HCL01-01 sample results do not belong to the stress field of any fault type in Anderson fault theory. The compression direction of the horizontal maximum stress is northwest-southeast, and the magnitude of the three main stresses calculated is 46.05, 41.06 and 34.29 MPa, respectively. HCL01-02 sample results tend to the stress field of the reverse fault type, and the horizontal maximum stress should be calculated. The compression direction of the force is NNW-SE, and the magnitude of the three principal stresses calculated is 57.86, 34.03 and 29.3 MPa from large to small, respectively. The results of HCL01-03 samples tend to normal fault-type stress field. The compression direction of the horizontal maximum stress is NNE-SW, and the magnitude of the three principal stresses calculated is 41. 35, 34.46, 27.96 MPa; HCL01-04 sample results tend to stress field of reverse fault type. The compression direction of horizontal maximum stress is NNE-SW. The magnitude of the three main stresses calculated is 68.58, 61.16 and 51.09 MPa, respectively. On the whole, the results of ASR experiments show that the stress field of each sample is not consistent, but the extrusion direction of the maximum horizontal principal stress tends to be the common point of the North-South extrusion. The results of triaxial strain field calculated from well Hongchailin No. 2 show that there is no specific rule in triaxial strain field of each sample, and the corresponding stress field pattern of each sample is different. The results of HCL02-06 samples tend to be the stress field of transition fault type between positive and strike-slip. The compression direction of horizontal maximum stress is northwest west-southeast-east. The magnitude of the three main stresses calculated is 65.09, 56.46 and 34.96 MPa, respectively. The results of HCL02-07 samples tend to be the stress field of strike-slip fault type, and the magnitude of the three main stresses calculated is 65.09, 56.46 and 34.96 MPa. The extrusion direction of the maximum stress is from northwest to southeast, and the magnitude of the three principal stresses is 80.08, 60.79 and 46.8 MPa, respectively. The direction of horizontal maximum principal stress in HCL02-6 and 7 samples tends to be northwest and southeast, and there are common points in the direction of horizontal maximum stress extrusion between HCL02-6 and 7 samples. The slip trend calculated from well Hongchailin 1 is less than 0.6, and the weak facets of each state are not easy to be distorted and activated. The expansion trend calculated from well Hongchailin 1 shows that there is a high expansion trend in the weak tectonic plane with a depth of about 1492 meters northwest-southeast and a middle-to-high dip in the Northeast direction, and a high expansion trend in the weak tectonic plane with a depth of about 1560 meters northeast-southwest direction and a middle-dip dip in the Southeast direction. Structural weak planes with a high dip angle of 9 meters north-south, east or South incline have a high trend of expansion, while those with a depth of about 222 meters northwest-southeast and a middle-to-low dip angle inclined northeast have a high trend of expansion. Comparing the dilatation trend calculated by core samples of Well Hongchailin No. 1 with the position of weak plane of deep structure nearby, the results show that most of the structural weak planes (such as bedding, cleavage, fissure, vein, fault scratch surface and water conduction fissure) have no high dilatation trend, which is not conducive to dilatation under the present stress field. The way of bracing crack develops into water conduction crack. Only 1491.5-1555.7 meters of vein group, which has a tendency of high expansion, has a better chance to develop into current water conduction fissures in the form of tension fissures. If other data, such as well logging data, can confirm the existence of water-conducting fissures at this location, it will be helpful to evaluate the relative location of injection wells and production wells in enhanced geothermal power plants.