The classical dq method for analysis of electrical machines is based on assumption that terminal variables are sinusoidally distributed. In case of non-sinusoidal distribution of these variables, a computationally intensive time-stepping technique is required. This paper presents a methodology, which allows fast and accurate analysis of sinusoidal as well as non-sinusoidal machines. The given technique uses magnetic flux density distribution along the air gap, obtained from finite element solutions for various operating conditions. These distributions are then converted into family of mutually orthogonal functions which forms the basis for analyzing the machine. The influence of magnetic saturation is taken into account by interpolating the magnitudes of the known basic orthogonal functions at corresponding RMS phase currents values. Presented approach enable calculations of back EMF in time domain for arbitrarily chosen load conditions. Validation of the proposed theory was done on an experimental setup comprising of an 8 pole, 2000rpm, 8KW machine.
[1]
Pawel Witczak,et al.
Spectral analysis of permanent magnet electric machines
,
2008
.
[2]
Pawel Witczak,et al.
Representation of permanent magnet brushless machine by means of orthogonal functions
,
2006
.
[3]
P. L. Alger,et al.
The nature of polyphase induction machines
,
1951
.
[4]
Antero Arkkio,et al.
Extraction of circuit parameters from time stepping FEM computation for coupled field‐circuit simulation
,
2006
.
[5]
Jacek F. Gieras,et al.
Permanent magnet motor technology : design and applications
,
1996
.
[6]
B. Heller,et al.
Harmonic field effects in induction machines
,
1977
.
[7]
Pawel Witczak,et al.
Determination of exploitation parameters of permanent magnet synchronous machine following the finite element solutions
,
2006
.