Abstract
For long distance electric power transport, high-voltage direct current (HVDC) cable systems are a commonly used solution. Space charges accumulate in the HVDC cable insulations due to the applied voltage and the nonlinear electric conductivity of the insulation material. The resulting electric field depends on the material parameters of the surrounding soil environment that may differ locally and have an influence on the temperature distribution in the cable and the environment. To use the radial symmetry of the cable geometry, typical electric field simulations neglect the influence of the surrounding soil, due to different dimensions of the cable and the environment and the resulting high computational effort. Here, the environment and its effect on the resulting electric field is considered and the assumption of a possible radial symmetric temperature within the insulation is analyzed. To reduce the computation time, weakly coupled simulations are performed to compute the temperature and the electric field inside the cable insulation, neglecting insulation losses. The results of a weakly coupled simulation are compared against those of a full transient simulation, considering the insulation losses for two common cable insulations with different maximum operation temperatures. Due to the buried depth of HV cables, an approximately radial symmetric temperature distribution within the insulation is obtained for a single cable and cable pairs when, considering a metallic sheath. Furthermore, the simulations show a temperature increase of the earth–air interface above the buried cable that needs to be considered when computing the cable conductor temperature, using the IEC standards.
Highlights
In comparison to high-voltage alternating current (HVAC) cables, high-voltage direct current (HVDC) cables are commonly used for long distance transmission of high electric power
With different thermal conductivity values of the surrounded earth and air, the assumption of a radial symmetric electric field and temperature distribution is under certain configurations not valid
Due to moderate temperate values, the insulation losses showed a negligible influence on the resulting temperature distribution and weakly coupled simulations of the temperature and the electric field were applied
Summary
In comparison to high-voltage alternating current (HVAC) cables, high-voltage direct current (HVDC) cables are commonly used for long distance transmission of high electric power. Differences between the electric field distributions within AC and DC cables result from the constant applied voltage and the nonlinear electric conductivity κ of the insulation. Due to the current inside the conductor and the leakage current in the insulation generate heat and result in a temperature drop in the cable materials and the environment. Considering insulation losses and the nonlinear electric conductivity, a coupled electro-thermal field problem needs to be solved. The electric and the thermal field of single cables and cable pairs are simulated in weakly coupled simulations and the obtained results are compared against full transient simulations to analyze the applicability of an assumption of a radial symmetric temperature within the insulation.
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