Simulation of Permittivity and Conductivity Graded Materials for HVDC GIL for Different Voltage Forms

TL;DR

This paper proposes a combined approach using graded permittivity and conductivity materials in HVDC gas insulated lines to effectively control electric fields under various transient and steady-state conditions, significantly reducing field intensity.

Contribution

It introduces a novel combination of permittivity and conductivity grading in GIL spacers to improve electric field management across multiple DC operational scenarios.

Findings

Electric field reduction up to 65.8% achieved

Combined permittivity and conductivity grading enhances control

Effective under transient and steady-state conditions

Abstract

Functionally graded materials (FGM) are applied in HVDC gas insulated lines (GIL) to control the electric field within the DC insulation system. In HVDC GIL, FGM with a spatial distribution of the electric conductivity (conductivity-FGM) is applied to control the electric field under DC steady state condition. However, besides DC steady state, different DC conditions occur, e.g. DC-on process, polarity reversal and lightning impulse. Under these conditions conductivity-FGM is not sufficient to control the electric field, since these conditions result in transient capacitive fields, where the permittivity is decisive for the electric field. In this paper, we suggest combining conductivity-FGM and a spatial distribution of permittivity (permittivity-FGM) in the spacer material to control the electric field around DC-GIL spacer for various DC-conditions, considering nonlinear material models for the insulating gas and the epoxy spacer. A variation of the spatial distribution of permittivity and conductivity in the spacer is investigated in this paper for an effective field reduction. The results show a reduction of the electric field intensity up to 65.8 %, when conductivity/permittivity-FGM is applied.