In this research, titanium-based filler Ti-35Ni-25Nb is used to braze CP-Ti and Ti-15-3 plates in vacuum. Microstructural evolution, shear strength, wetting behavior and phase identification are assessed in the experiment. Specimens prepared with standard metallographic procedure are examined using electron probe microanalyzer (EPMA) equipped with the wavelength dispersive spectroscope (WDS) and SEM for microstructural evolution observation and quantitative chemical analysis. In the part of CP-Ti/Ti-35Ni-25Nb/CP-Ti, intermetallic compound, Ti2Ni, appeared in the brazing zone under various temperature parameters. The appearance of this intermetallic compound can seriously affect the mechanical properties of this material. Ti2Ni exhibits high brittleness, and when shear strength is applied, it easily causes the fracture. It mainly occurs in the eutectoid structure of Ti2Ni and α-Ti. In addition, the phase boundary of the eutectoid structure also easily leads to the growth of cracks. In this experiment, it was found that increasing the brazing temperature to 1200°C can reduce the proportion of Ti2Ni in brazing zone and also increase the shear strength, which is due to the reduction of Ni in brazing zone after the brazing process. Ni in the brazing zone decreases, making it difficult for Ti2Ni to form, and will become dominated by the α-Ti and β-Ti. In the part of Ti-15-3/Ti-35Ni-25Nb/Ti-15-3, the intermetallic compound, Ti2Ni, is also found in the brazing zone, and the same, it will also seriously affect the mechanical properties of the material. However, as the brazing temperature is increased to 1200°C, or the brazing time is extended to 30 minutes at 1100°C, Ti2Ni will not appear in the brazing zone, the overall brazing zone is β-Ti, and the shear strength also be significantly improved.