Title :
High-temperature superconducting DC networks
Author :
Johnson, B.K. ; Lasseter, R.H. ; Alvarado, F.L. ; Divan, D.M. ; Singh, H. ; Chandorkar, M.C. ; Adapa, R.
Author_Institution :
Dept. of Electr. Eng., Idaho Univ., Moscow, ID, USA
Abstract :
High-temperature superconducting DC networks are studied as a feasible alternative to AC power transmission systems. The DC network operates at generation voltages allowing direct connection of the generators to the rectifiers, eliminating the need for high-voltage insulation and transformers. The DC system is based on a mesh-connected low-voltage high-current superconducting DC transmission network supplied by unit-connected generators. The DC system feeds many small inverters that pass controlled levels of real and reactive power to AC loads. This paper presents an overview of superconducting low-voltage DC transmission systems, starting with a discussion of the DC system. This discussion is followed by an overview of the operation of AC distribution systems connected to the superconducting DC mesh and then inverter topologies and control strategies required for interfacing the AC distribution systems to the DC mesh. The paper presents a conceptual overview of the operation of the system based on simulation studies.<>
Keywords :
DC power transmission; DC transmission networks; distribution networks; high-temperature superconductors; invertors; power convertors; power system interconnection; superconducting cables; thyristor applications; AC distribution systems; AC loads; LV; generation voltages; generators; high-temperature superconducting DC networks; interconnection; inverters; power cables; reactive power; real power; rectifiers; simulation; superconducting DC mesh; Control systems; DC generators; Feeds; High temperature superconductors; Inverters; Power transformer insulation; Power transmission; Reactive power control; Rectifiers; Superconducting transmission lines;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
