Title :
Proximity effect and magnetic field calculation in GIL and in isolated phase bus ducts
Author :
Benato, R. ; Dughiero, F. ; Forzan, M. ; Paolucci, A.
Author_Institution :
Dept. of Electr. Eng., Padova Univ., Italy
fDate :
3/1/2002 12:00:00 AM
Abstract :
This paper deals with an integral numerical method suitable to predict the current density distribution in typical multiconductor systems represented by gas-insulated lines (GIL) or by isolated phase MV bus ducts, highlighting their proximity effect. Besides the prediction of power density distribution due to Joule losses, the integral approach makes the evaluation of the external flux density easy. The simplicity of the approach, the conciseness of the matrix algebra applied, and the close-to-reality procedure make this method extremely attractive for self-made software implementation on any commercially available math packages such as Matlab. For the sake of comparison, a finite-element method (FEM) model of the system has been implemented. In this model, a coupling between electric circuit and electromagnetic model has been used in order to take into account the real power supply conditions
Keywords :
current density; current distribution; finite element analysis; gaseous insulation; magnetic fields; magnetic flux; magnetic shielding; power transmission lines; FEM; GIL; close-to-reality procedure; current density distribution; electric circuit; electromagnetic model; external flux density; finite-element method; gas-insulated lines; integral numerical method; isolated phase MV bus ducts; isolated phase bus ducts; magnetic field calculation; magnetic shielding; matrix algebra; multiconductor systems; proximity effect; real power supply; Current density; Ducts; Electromagnetic modeling; Gas insulated transmission lines; Mathematical model; Matrices; Packaging; Power system modeling; Proximity effect; Software packages;
Journal_Title :
Magnetics, IEEE Transactions on
