High voltage resistance ceramic coating fabricated on titanium alloy for insulation shielding application

Abstract

Abstract To endow the insulation shielding of electromechanical devices, a TiO2 based ceramic coating with high voltage resistance was fabricated on titanium alloy by plasma electrolytic oxidation (PEO). The effects of PEO coatings with different phase composition and microstructure on insulation performance were determined. The results show that the ceramic coating formed in the silicate-based solution was mainly composed of rutile, anatase TiO2 and Al2TiO5. As the coating thickens from 10 to 36\u202fµm, the increasing cross-sectional porosity enables the dielectric strength decrease from 32.94\u202f±\u202f2.1\u202fV/μm to 11.9\u202f±\u202f0.71\u202fV/μm and the electric resistivity drop from 1.17\u202f×\u202f108 Ω\u202fcm to 0.99\u202f×\u202f108 Ω\u202fcm respectively. With 2\u202fg/L KOH added into the basic electrolyte, the thickness of coating significantly increased to 50.0\u202f±\u202f2.1\u202fµm, accompanied by the enhanced crystalline degree of rutile TiO2 phase and the decreasing of internal defects. In this way, the optimum coating with preferable resistivity of 1.08\u202f×\u202f1010 Ω\u202fcm, high breakdown voltage of 617.78\u202f±\u202f26.31\u202fV and dielectric strength of 12.36\u202f±\u202f0.53\u202fV/μm was achieved.