Title :
Finite-Element and Analytical Calculations of No-Load Core Losses in Energy-Saving Induction Motors
Author :
Komeza, Krzysztof ; Dems, Maria
Author_Institution :
Inst. of Mechatron. & Inf. Syst., Tech. Univ. of Lodz, Lodz, Poland
fDate :
7/1/2012 12:00:00 AM
Abstract :
This paper presents a no-load core loss analysis of a three-phase energy-saving small-size induction motor supplied by a sinusoidal voltage. In the field-circuit approach, the distribution and changes of magnetic flux density in the motor are computed using a time-stepping finite-element method. The discrete Fourier transform is used to analyze the magnetic flux density waveforms in each element of the motor model. The rotational aspect of the field is included by introducing a correction to the losses generated by the first harmonic of magnetic flux density. The core losses in each element are evaluated using a loss curve measured on a toroidal core at different frequencies. Finally, an approximate analytical formulation is derived for rapid field computation. The results are compared with measurements.
Keywords :
discrete Fourier transforms; energy conservation; finite element analysis; induction motors; losses; machine theory; approximate analytical formulation; discrete Fourier transform; field-circuit approach; loss curve; magnetic flux density waveform analysis; motor model; no-load core losses analysis; sinusoidal voltage; three-phase energy-saving small-size induction motor; time-stepping finite-element method; toroidal core; Core loss; Harmonic analysis; Induction motors; Loss measurement; Magnetic flux density; Rotors; Stator cores; AC machines; discrete Fourier transforms (DFTs); electric machines; electric variable measurements; electromagnetic transients; finite-element method (FEM); induction motors; magnetic losses; power measurement; rotating machines;
Journal_Title :
Industrial Electronics, IEEE Transactions on
DOI :
10.1109/TIE.2011.2168795
