Title :
Optimized transformer design: inclusive of high-frequency effects
Author :
Hurley, William Gerard ; Wolfle, Werner Hugo ; Breslin, John G.
Author_Institution :
Dept. of Electron. Eng., Nat. Univ. of Ireland, Galway, Ireland
fDate :
7/1/1998 12:00:00 AM
Abstract :
Switching circuits, operating at high frequencies, have led to considerable reductions in the size of magnetic components and power supplies. Nonsinusoidal voltage and current waveforms and high-frequency skin and proximity effects contribute to power transformer losses. Traditionally, power transformer design has been based on sinusoidal voltage and current waveforms operating at low frequencies. The physical and electrical properties of the transformer form the basis of a new design methodology while taking full account of the current and voltage waveforms and high-frequency effects. Core selection is based on the optimum throughput of energy with minimum losses. The optimum core is found directly from the following transformer specifications: frequency; power output; and temperature rise. The design methodology is illustrated with a detailed design of a push-pull power converter
Keywords :
losses; optimisation; power transformers; skin effect; switching circuits; transformer cores; transformer magnetic circuits; HF switching circuits; core selection; design methodology; frequency; high-frequency effects; high-frequency proximity effect; high-frequency skin effect; magnetic components; nonsinusoidal current waveforms; nonsinusoidal voltage waveforms; optimum throughput; power output; power transformer design optimisation; power transformer losses; push-pull power converter; temperature rise; transformer specifications; Design methodology; Design optimization; Frequency; Power supplies; Power transformers; Proximity effect; Skin; Switching circuits; Throughput; Transformer cores;
Journal_Title :
Power Electronics, IEEE Transactions on
