Theoretical investigation of HVDC disc spacer charging in SF6 gas insulated systems

It seems generally accepted that HVDC technology is to become increasingly relevant in power systems. With this expected future advance of HVDC, the use of gas insulated switchgear or lines for dc application are getting increasingly interesting. As in the case of dc the electric fields are determined resistively in contrast to the capacitive fields in the case of ac, gas insulated technology has to be revisited. In many previous works surface charging of model spacers was investigated. However, the ion flow problem to properly account for the electric conduction in the gas has not yet been solved. Further, no combination with inhomogeneous electric conductivity determined for example by temperature profiles from ohmic heating in nominal condition has been performed so far. In this paper, the gas conductivity arising from ions produced by natural radiation is computed by solving the ion flow field problem, and its role is compared to spacer bulk conductivities. Further, the impact of temperature profiles on spacer charging is investigated. The results indicate that for actual disc spacers, the spacer bulk conductivity is more important than that from the gas ionized by natural radiation. Especially in the case of polarity reversal, thermally enhanced spacer charging can result in considerable increase of tangential field strengths.