0004 PDF C25


Chapter 25
SINGLE-PHASE IM TRANSIENTS
25.1 INTRODUCTION
Single-phase induction motors undergo transients during starting, load
perturbation or voltage sags etc. When inverter fed, in variable speed drives,
transients occur even for mechanical steady state during commutation mode.
To investigate the transients, for orthogonal stator windings, the cross field
(or d-q) model in stator coordinates is traditionally used. [1]
In the absence of magnetic saturation, the motor parameters are constant.
Skin effect may be considered through a fictitious double cage on the rotor.
The presence of magnetic saturation may be included in the d-q model
through saturation curves and flux linkages as variables. Even for sinusoidal
input voltage, the currents may not be sinusoidal. The d-q model is capable of
handling it. The magnetisation curves may be obtained either through special
flux decay standstill tests in the d-q (m.a) axes (one at a time) or from FEM-in
d.c. with zero rotor currents. The same d-q model can handle nonsinusoidal
input voltages such as those produced by a static power converter or by power
grid polluted with harmonics by other loads nearby.
To deal with nonorthogonal windings on stator, a simplified equivalence
with a d-q (orthogonal) winding system is worked out. Alternatively a multiple
reference system + - model is used [3]
While the d - q model uses stator coordinates, which means a.c. during
steady state, the multiple-reference model uses + - synchronous reference
systems which imply d.c. steady state quantities. Consequently, for the
investigation of stability, the frequency approach is typical to the d-q model
while small deviation linearization approach may be applied with the multiple-
reference + - model.
Finally, to consider the number of stator and rotor slots-that is space flux
harmonics-the winding function approach is preferred. [4] This way the
torque/speed deep around 33% of no load ideal speed, the effect of the relative
numbers of stator and rotor slots, broken bars, rotor skewing may be considered.
Still saturation remains a problem as superposition is used.
A complete theory of single phase IM, valid both for steady-state and
transients, may be approached only by a coupled FEM-circuit model, yet to be
developed in an elegant computation time competitive software. In what
follows, we will illustrate the above methods in some detail.
© 2002 by CRC Press LLC
Author: Ion Boldea, S.A.Nasar& & & & ..& & & ..
25.2 THE d-q MODEL PERFORMANCE IN STATOR COORDINATES
As in general the two windings are orthogonal but not identical, only stator
coordinates may be used directly in the d-q (cross field) model of the single
phase IMs.
True, when one phase is open any coordinates will do it but this is only the
case of the split-phase IM after starting. [5]
First, all the d-q model variables are reduced to the main winding
Vds = Vs (t)
Vqs = (Vs (t) - Vc (t))/ a
(25.1)
Ids = Im
Iqs = Ia Å" a
jq
I
qs
qs Vqs
aux
q
Va VC
C
Iqr
d
s
d
main
d
I
dr I
I
ds
ds
Vds
V = Vm
s
Figure 25.1 The d-q model
Where a is the equivalent turns ratio of the auxiliary to main winding.
Also
Iqs
dVc 1
= (25.2)
dt C a
The d-q model equations, in stator coordinates, are now straightforward
© 2002 by CRC Press LLC
Author: Ion Boldea, S.A.Nasar& & & & ..& & & ..
d¨ds
= Vs (t) - RsmIds
dt
d¨qs
Rsa
= (Vs (t) - Vc (t))/ a - Iqs
dt a2
(25.3)
d¨dr
= IdrRrm - Ér¨qr
dt
d¨qr
= IqrRrm + Ér¨dr
dt
The flux/current relationships are
¨ds = LsmIds + ¨dm; ¨dm = Lm(Ids + Idr ) = LmIdm
¨dr = LrmIdr + ¨dm
(25.4)
Lsa
¨qs = Iqs + ¨qm; ¨qm = Lm(Iqs + Iqr)= LmIqm
a2
¨qr = LrmIqr + ¨qm
The magnetization inductance Lm depends both on Idm and Iqm when
saturation is accounted for because of cross-coupling saturation effects. As the
magnetic circuit looks nonisotropic even with slotting neglected, the total flux
vector ¨m is a function of total magnetization current Im:
¨m = Lm (Im ) Å" Im
(25.5)
2 2 2 2
Im = Idm + Iqm ;¨m = ¨dm + ¨qm
Once Lm(Im) is known, it may be used in the computation process with its
previous computation step value, provided the sampling time is small enough.
We have to add the motion equation
J dÉr
= Te - Tload(¸r , Ér )
p1 dt
d¸r
= Ér / p1 (25.6)
dt
Te = (¨dsIqs - ¨qsIds)p1
Equations (25.2)-(25.6) constitute a nonlinear 7th order system with Vc, Ids,
Iqs, Idr, Iqr and Ér, ¸r as variables. The inputs are Vs(t)-the source voltage and
Tload-the load torque.
The load torque may vary with speed (for pumps, fans) or with rotor
position (for compressors).
In most applications, ¸r does not intervene as the load torque depends on
speed, so the order of the system becomes six.
When the two stator windings do not occupy the same number of slots,
there may be slight differences between the magnetization curves along the two
© 2002 by CRC Press LLC
Author: Ion Boldea, S.A.Nasar& & & & ..& & & ..
axes, but they are in many cases small enough to be neglected in the treatment
of transients.
¨ [Wb]
m
1.0
0.5
5
I m[A]
Figure 25.2 The magnetization curve
A good approximation of the magnetization curve may be obtained through
FEM, at zero speed, with d.c. excitation along one axis and contribution from
the second axis. Dc current decay tests at standstill in one axis, with dc current
injection in the second axis should provide similar results. After many  points
in Figure 25.2 are calculated, curve fitting may be used to yield a univoque
correspondance between ¨m and Im.
As expected, if enough digital simulation time for transients is allowed,
steady state behaviour may be reached.
In the absence of saturation, for sinusoidal power source voltage, the line
current is sinusoidal for no-load and under load.
In contrast, when magnetic saturation is considered, the simulation results
show nonsinusoidal line current under no-load and load conditions (Figure
25.3). [2]
The influence of saturation is visible. It is even more visible in the main
winding current RMS computation versus experiments. (Figure 25.4) [2]
The differences are smaller in the auxiliary winding for the case in
point: Pn = 1.1 kW, Un = 220 V, In = 6.8 A, C = 25 µF, fn = 50 Hz, a = 1.52,
Rsm = 2.6 &!, Rsa = 6.4 &!, Rrm = 3.11 &!, Lsm = Lrm = 7.5 mH, J = 1.1×10-3 Kgm2,
Lsa = 17.3 mH. The magnetization curve is as in Figure 25.2. The motor power
factor, calculated for the fundamental, at low loads, is much less than predicted
by the nonsaturated d-q model. On the other hand it looks like the saturated d-q
model produces results which are very close to the experimental ones, for a
wide range of loads.
© 2002 by CRC Press LLC
Author: Ion Boldea, S.A.Nasar& & & & ..& & & ..
a.) b.)
c.) d.)
Figure 25.3 Steady state by the d-q model with saturation included
a.) and b.)-no load
c.) and d.)-on load
a.) and c.)-test results
b.) and d.)-digital simulation
© 2002 by CRC Press LLC
Author: Ion Boldea, S.A.Nasar& & & & ..& & & ..
Figure 25.4. RMS of main winding current versus output power
1-saturated model
2-unsaturated model
" -test results
This may be due to the fact that the saturation curve has been obtained
through tests and thus the saturation level is tracked for each instantaneous
value of magnetization current (flux).
The RMS current correct prediction by the saturated d-q model for steady
state represents notable progress in assessing more correctly the losses in the
machine.
Still, the core losses-fundamental and additional-and additional losses in the
rotor cage (including the interbar currents) are not yet included in the model.
Space harmonics though apparently somehow included in the ¨m(Im) curve are
not thoroughly treated in the saturated d-q model.
25.3 STARTING TRANSIENTS
It is a known fact that during severe starting transients, the main flux path
saturation does not play a crucial role. However it is there embedded in the
model and may be used if so desired.
For a single phase IM with the data: Vs = 220 V, f1n = 50 Hz, Rsm = Rsa = 1
&!, a = 1, Lm = 1.9 H, Lsm = Lsa = 0.2 H, Rrm = 35 &!, Lrm = 0.1 H, J = 10-3 Kgm2,
Ca=5 µF, Å› = 900, the starting transients are presented on Figure 25.5. The load
torque is zero from start to t = 0.4 s, when a 0.4 Nm load torque is suddenly
applied.
The average torque looks negative because of the choice of signs.
The torque pulsations are large and so evident on Figure 25.5 b), while the
average torque is 0.4 Nm, equal to the load torque. The large torque pulsations
reflect the departure from symmetry conditions. The capacitor voltage goes up
to a peak value of 600 V, another sign that a larger capacitor might be needed.
© 2002 by CRC Press LLC
Author: Ion Boldea, S.A.Nasar& & & & ..& & & ..
a.) b.)
c.) d.)
Figure 25.5 Starting transients
a.) speed versus time, b.) torque versus time
c.) input current versus time, d.) capacitor voltage versus time
© 2002 by CRC Press LLC
Author: Ion Boldea, S.A.Nasar& & & & ..& & & ..
The hodograph of stator current vector
Is = Id+jIq (25.7)
is shown on Figure 25.6.
Figure 25.6 Current hodograph during starting
For symmetry, the current hodograph should be a circle. Not so in Figure
25.6.
To investigate the influence of capacitance on the starting process, the
starting capacitor is Cs = 30µF, and then at t = 0.4s the capacitance is reduced
suddenly Ca = 5µF (Figure 25.7)
a.) b.)
Figure 25.7 Starting transients for Cs = 30 µF at start and Ca = 5 µF from t = 0.4 s on
a.) speed; b.) torque
The torque and current transients are too large with CS = 30 µF, a sign that
the capacitor is now too large.
25.4 THE MULTIPLE REFERENCE MODEL FOR TRANSIENTS
The d-q model has to use stator coordinates as long as the two windings are
not identical. However if the d-q model is applied separately for the
instantaneous + and-(f, b) components then for synchronous coordinates: +É1
(for the +(f) component) and -É1 (for the - (b) component), the steady state
means d.c. variables. [3]
© 2002 by CRC Press LLC
Author: Ion Boldea, S.A.Nasar& & & & ..& & & ..
Consequently, the dynamic (stability) analysis may be performed via the
system linearization (small deviation theory).
Stability to sinusoidal torque pulsation such as in compressor loads, can
thus be treated. The superposition principle precludes the inclusion of magnetic
saturation in the model. [3]
25.5 INCLUDING THE SPACE HARMONICS
The existence of space harmonics causes torque pulsations, cogging, and
crawling.
The space harmonics have three origins, as mentioned before in Chapter 23,
" Stator m.m.f. space harmonics
" Slot opening permeance pulsations
" Main flux path saturation
A general method to deal with space harmonics of all these three origins is
presented in Reference 6 based on the multiple magnetic circuit approach. The
rotor is considered bar by bar.
Reference 4 treats space harmonics produced only by the stator m.m.f. but
deals also with the effect of skewing. Based on the winding function approach,
the latter method also considers m windings in the stator and Nr bars in the
rotor. Magnetic saturation is neglected.
The deep(s) in the torque/speed curve may be predicted by this procedure.
Also the influence of the ratio of slot numbers Ns/Nr of stator and rotor and of
cogging (parasitic, asynchronous) torques is clearly evidentiated. As an
example, Figure 25.8 illustrates [4] the starting transients of a single-phase
capacitor motor with the same number of slots per stator and rotor, without
skewing. As expected, the motor is not able to start due to the strong parasitic
synchronous torque at stall (Figure 25.8 a)
Figure 25.8 Starting speed transients for Ns = Nr
a) without skewing b) with skewing
© 2002 by CRC Press LLC
Author: Ion Boldea, S.A.Nasar& & & & ..& & & ..
With skewing of one slot pitch, even with Ns = Nr slots, the motor can start
(Figure 25.8 b).
25.6 SUMMARY
" Transients occur during starting or load torque perturbation operation
modes.
" Also power source voltage (and frequency) variation cause transients
in the single phase IM.
" When power converter (variable voltage, variable frequency)-fed, the
single phase IM experiences time harmonics also.
" The standard way to handle the single phase IM is by the cross-field
(d-q) model when magnetic saturation, time harmonics and skin effect
may be considered simultaneously.
" Due to magnetic saturation the main winding and total stator currents
depart from sinusoidal waveforms, both at no-load and under load
conditions. The magnetic saturation level depends on load, machine
parameters and on the capacitance value. It seems that neglecting
saturation leads to notable discrepancy between the main and total
currents measured and calculated RMS values. This is one of the
reasons why losses are not predicted correctly, especially for low
powers.
" Switching the starting capacitor off produces important speed, current,
and torque transients.
" The d-q model has a straightforward numerical solution for transients
but, due to the stator winding asymmetry, it has to make use of stator
coordinates to yield rotor position independent inductances. Steady
state means a.c. variables at power source frequency. Consequently,
small deviation theory, to study stability, may not be used, except for
the case when the auxiliary winding is open.
" The multiple reference system theory, making use of + - (f,b) models in
their synchronous coordinates (+É1 and  É1) may be used to
investigate stability after linearization.
" Finally, besides FEM-circuit coupled model, the winding function
approach or the multiple equivalent magnetic circuit method simulate
each rotor bar and thus asynchronous and synchronous parasitic
torques may be detected.
" A FEM-circuit couple model (software), easy to handle, and
computation time competitive, for single-phase IM, is apparently not
available as of this writing.
© 2002 by CRC Press LLC
Author: Ion Boldea, S.A.Nasar& & & & ..& & & ..
25.7 REFERENCES
1. I. Boldea and S. A. Nasar, Electrical Machine Dynamics, Macmillan
Publishing Company, New York 1986.
2. K. Arfa, S. Meziani, S. Hadji, B. Medjahed, Modelization of Single
Phase Capacitor Run Motor Accounting for Saturation, Record of
ICEM-1998, Vol.1, pp.113-118.
3. T. A. Walls and S. D. Sudhoff , Analysis of a Single-Phase Induction
Machine With a Shifted Auxiliary Winding, IEEE Trans., vol. EC-11,
no. 4, 1996, pp. 681-686.
4. H. A. Toliyat and N. Sargolzaei, Comprehensive Method for Transient
Modelling of Single Phase Induction Motors Including the Space
Harmonics, EMPS Journal vol. 26, no. 3, 1998, pp. 221-234.
5. S. S. Shokralla, N. Yasin, A. M. Kinawy, Perturbation Analysis of a
Split Phase Induction Motor in Time and Frequency Domains, EMPS
Journal vol. 25, no. 2, 1997, pp. 107-120.
6. V. Ostovic, Dynamics of Saturated Electric Machines (book), Springer
Verlag, New York, 1985.
© 2002 by CRC Press LLC


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