Title :
Proximity effect and eddy current losses in insulated cables
Author :
Ferkal, K. ; Poloujadoff, M. ; Dorison, E.
Author_Institution :
Paris VI Univ., France
fDate :
7/1/1996 12:00:00 AM
Abstract :
Insulated cables are generally designed according to thermal criteria: the current rating depends on the permissible temperature inside the insulation. As the heating of a cable mainly results from Joule losses, it is worthy to determine the current distribution in its metallic components (the core and the metallic screen for single core cables). The current distribution in tables is affected by the skin effect and the proximity effect due to neighbouring cables of the circuit itself or from parallel links. A general method is developed to calculate the current distribution in the core and the screen of a single-core cable, starting from Maxwell equations. The stress is set upon skin and proximity effects, taking into account the influence of the frequency. Joule losses are calculated in some practical cases of three-phase links
Keywords :
Maxwell equations; cable sheathing; current distribution; eddy current losses; eddy currents; losses; power cable insulation; power cables; skin effect; thermal analysis; underground cables; Joule losses; Maxwell equations; current distribution; current rating; eddy current losses; insulated cables; metallic components; metallic screen; neighbouring cables; parallel links; proximity effect; single core cables; single phase transmission; skin effect; thermal criteria; three phase transmission; three-phase links; underground cables; Cable insulation; Cables; Circuits; Current distribution; Eddy currents; Heating; Maxwell equations; Proximity effect; Skin effect; Temperature dependence;
Journal_Title :
Power Delivery, IEEE Transactions on
