Page 500 - Handbook of Electrical Engineering
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490 HANDBOOK OF ELECTRICAL ENGINEERING
Hence the machine with one damper winding on each axis is adequate for most practical
situations, certainly for those in the oil industry.
20.3 SOME NOTES ON INDUCTION MOTORS
At this stage it can be noted that equations (20.5) to (20.11) can be applied to induction motors, but
with the following modifications:-
a) Omit the line and row pertaining to the field winding.
b) There is no saliency and so corresponding d-axis and q-axis parameters are equal. The mutual
inductances are all equal, which can be denoted as M dq or M.
c) The damper windings kd and kq have identical structures and parameters.
d) The d, q notation for the rotor axes will be retained for comparison purposes. Some authors, e.g.
Reference 11, use the notation r, s to denote the stator and the rotor circuits where as many others
use a combination of both notations i.e. dr, qr, ds, qs: rd, rq, sd, sq, e.g. References 5, 15, 18,
19, 20 and 21, Also used is the notation ld, lq,2d,and 2q e.g. in Reference 12, where l and 2
are used in equivalent circuits of induction motors to represent the stator (primary −1) and rotor
(secondary −2) windings.
e) Additional three phase to two axis transformations are required for the following reasons:-
i) The rotor has a uniform construction. The conductors consist of solid copper bars fixed in
slots axially along and near the surface of the rotor. Usually one conductor fills a slot. The
ends of the conductors at the drive end of the shaft are short circuited with a copper ring.
The ends at the non-drive end are also short circuited by a similar ring. The conductors form
what is called a ‘single cage’ or ‘squirrel cage’ design. There are no external connections by
way of slip rings or commutators.
ii) A cage design has no wound or physical poles, as with a synchronous machine. The cage
creates its own poles as it rotates. A three-phase winding with the same number of poles as
the stator is automatically formed by the induction of rotor currents.
iii) The three-phase rotor windings need to be replaced by equivalent two-axis windings fixed to
the rotor. A second transformation is required to convert these windings to a set that rotates
at the frequency of the phase voltages applied to the stator. Although the induction machine
is simpler in construction and operation than the synchronous machine, the transformation
mathematics are more complicated. A basic explanation of the above is given by Cotton in
Reference 12 and a more sophisticated mathematical treatment is given by Krause in Refer-
ence 5 for machines with a greater number of windings, i.e. additional rotor windings. Cotton
in Chapter 31 presents equations of stator-applied voltages in terms of the stator resistive
volt-drops and the d –q axis flux linkages. He shows that these are of identical form to those
of the synchronous machine. (It can be implied from this conclusion that a computer program
could be written using the same form of equations for both type of machines. This observation
has been commented upon in the literature e.g. References 22 and 23. Reference 23 considers
double-cage induction motors in which the ‘deep bar’ effect is included, and results were
obtain for motors having ratings in the range of 2500 hp to 22,000 hp.) The form of these
stator equations are:-
v d = R a i d + pψ d − ωψ q
v q = R a i q + pψ q + ωψ d
