0004 PDF C28


Chapter 28
SINGLE-PHASE IM TESTING
28.1 INTRODUCTION
The elliptic magnetic field in the airgap of single phase IMs in presence of
space m.m.f. harmonics, magnetic saturation, rotor skin effect, and interbar rotor
currents makes a complete theoretical modelling a formidable task.
In previous chapters, we did touch all these subjects through basically
refined analytical approaches. Ideally, a 3D-FEM, with eddy currents
computation and circuit model coupling should be used to tackle simultaneously
all the above phenomena.
However, such a task still requires a prohibitive amount of programming
and computation effort.
As engineering implies intelligent compromises between results and costs,
especially for single-phase IMs, characterized by low powers, experimental
investigation is highly recommended. But, again, it is our tendency to make tests
under particular operation modes such as locked rotor (shortcircuit) and no-load
tests to segregate different kinds of losses and then use them to calculate on-
load performance.
Finally, on-load tests are used to check the loss segregation approach.
For three phase IMs, losses from segregation methods and direct on-load
tests are averaged to produce safe practical values of stray load losses and
efficiency (IEEE Standard 112B).
The presence of rotor currents even at zero slip (S = 0)-due to the backward
field component-in single phase IM makes the segregation of losses and
equivalent circuit parameter computation rather difficult. Among many potential
tests to determine single phase IM parameters and loss segregation two of them
have gained rather large acceptance.
One is based on single phase supplying of either main or auxiliary winding
of the single phase IM at zero speed (S = 1) and on no-load. The motor may be
started as capacitor or split-phase motor and then the auxiliary phase is turned
off with the motor free at shaft. [1]
The second method is based on the principle of supplying the single phase
IM from a symmetrical voltage supply. The auxiliary winding voltage Va is 900
ahead of the main winding voltage and Va = Vma, such that the current Ia is Ia =
Im/a; a is the ratio between main and auxiliary winding effective turns. [2]
This means in fact that pure forward travelling field conditions are
provided. The 900 shifted voltage source is obtained with two transformers with
modified Scott connection and a Variac.
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
Again shortcircuit (zero speed)-at low voltage-and no load testing is
excersized. Moreover, ideal no-load operation (S = 0) is performed by using a
drive at synchronous speed n1 = f1/p1
Then both segregation methods are compared with full (direct) load testing.
[2] For the case studies considered both methods claim superior results. [1,2]
The two methods have a few common attributes
" They ignore the stray losses (or take them as additional core losses
already present under no load tests).
" They consider the magnetization inductance as constant from
shortcircuit (S = 1) to no-load and load conditions.
" They ignore the space m.m.f. harmonics, and, in general, consider the
current in the machine as sinusoidal in time.
" They neglect the skin effect in the rotor cage. Though the value of the
rotor slot depth is not likely to go over 1510-3m (the power per unit is
limited to a few kW), the backward field produces a rotor current
component whose frequency f2b = f1(2-S) varies from f1 to 2f1 when the
motor accelerates from zero to rated speed. The penetration depth of
electromagnetic field in aluminum is about 1210-3m at 50Hz and
(12 / 2)10-3m at 100Hz. The symmetrical voltage method [2] does
not have to deal with the backward field and thus the rotor current has
a single frequency (f2f = Sf1). Consequently the skin effect may be
neglected. The trouble is that during variable load operation, the
backward field exists and thus the rotor skin effect is present. In the
single phase voltage method [1] the backward field is present under no
load and thus it may be claimed that somehow the skin effect is
accounted for. It is true that, as for both methods the shortcircuit tests
(S = 1) are made at rated frequency, the rotor resistance thus
determined already contains a substantial skin effect. This may explain
why both methods give results which are not far away from full load
tests.
" Avoiding full load tests, both methods measure under no-load tests,
smaller interbar currents losses in the rotor than under load. Though
there are methods to reduce the interbar currents, there are cases when
they are reported to be important, especially with skewed rotors.
However, in this case, the rotor surface core additional losses are
reduced and thus some compensation of errors may occur to yield good
overall loss values.
" Due to the applied simplifications, neither of the methods is to be used
to calculate the torque/speed curve of the single-phase IM beyond the
rated slip (S>Sn). Especially for tapped winding or split-phase IMs
which tend to have a marked third order m.m.f. space harmonic that
causes a visible deep in the torque/speed curve around 33% of ideal no
load speed (S = 0).
As the symmetrical voltage method of loss segregation and parameter
computation is quite similar to that used for three phase IM testing (Chapter 22),
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
we will concentrate here on Veinott s method [1] as it sheds more light on
single phase IM peculiarities, given by the presence of backward travelling
field. The presentation here will try to retain the essentials of Veinott s method
while making it show a simple form, for the potential user.
28.2 LOSS SEGREGATION THE SPLIT PHASE AND CAPACITOR
START IMs
The split phase and capacitor start IMs start with the auxiliary winding on
but end up operating only with the main stator winding connected to the power
grid.
It seems practical to start with this case by exploring the shortcircuit (zero
speed) and no load operation modes with the main winding only on, for
parameter computation and loss segregation.
We will make use of the cross field model (see Chapter 24, Figure 24.21),
though the travelling field (+, -) model would give similar results as constant
motor parameters are considered.
For the zero speed test (S = 1) Zf = Zb and, thus,
Psc
Rsm + Rrm H" (28.1)
I2
msc
Vs
Zsc = (28.2)
Imsc
2
ł ł
Vs
2
ł ł - (Rsm + Rrm) (28.3)
Xsm + Xrm H"
ł ł
Imsc
ł łł
With Rsm d.c. measured and temperature-corrected, and Xsm H" Xrm for first
iteration the values of Rsm, Xsm = Xrm and Rrm are determined. For the no-load
test (still Ia = 0) we may measure the slip value S0 or we may not. If we do, we
make use of it. If not, S0 H" 0.
Making use of the equivalent circuit of Figure 28.1, for S = S0 = 0 and with
Im0(A), Vs(V), Pm(W) and Ea measured, we have the following mathematical
relations
1
Zf H" jXmm (28.4)
2
1 Rrm
ł
Zb H" + jXrm łł (28.5)
ł śł
2 2
ł ł
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
I Rsm jX
sm jX Z C= - jX +RC
m sa
R
sa C
Zf
jaZ I
f
m
E
V a
s
-jaZ b I
m
Zb
rm
S = S
f
(R )
j Xmm Sf,b +jXrm
1
Z f,b= S = 2 - S
b
2 Rrm
+j(X mm )
+X
S
f,b
Figure 28.1 The cross field single phase IM with auxiliary winding open (Ia = 0)
Ea
From H" (Zf - Zb)Im0 (28.6)
a
with Rrm and Xsm already determined from the shortcircuit test and Im0 and Ea
measured, we need the value of a in Equation 28.6 to determine the
magnetization reactance Xmm
2
Ea R2
rm
Xmm = 2 - - Xrm (28.7)
a2I2 16
m0
A rather good value of a may be determined by running on no load the
machine additionally, with the main winding open and the auxiliary winding fed
from the voltage Va0 H" 1.2Ea. With Em measured, [1]
EaVa0
a = (28.8)
VsEm
Once Xmm is known, from (28.7) with (28.8), we may make use of the
measured Pm0, Im0, Vs (see Figure 28.1) to determine the sum of iron and
mechanical losses
Rrm
ł łI2
pmec + piron = Pm0 - ł ł
Rsm + (28.9)
m0
4
ł łł
The no load test may be performed at different values of Vs, below rated
value, until the current Im0 starts increasing; a sign that the slip is likely to
increase too much.
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
As for the three phase IM, the separation of mechanical and core losses may
be done by taking the ordonate at zero speed of the rather straight line
dependence of (pmec+piron) of Vs2 (Figure 28.2). Alternatively, we may use only
the results for two voltages to segregate pmec from piron.
A standard straight-line curve fitting method may be used for better
precision.
The core loss is, in fact, dependent on the e.m.f. Em (not on input voltage
Vm) and on the magnetic field ellipticity.
The field ellipticity decreases with load and this is why, in general, the core
losses are attributed to the forward component.
Consequently, the core loss resistance Rmiron may be placed in series with
the magnetization reactance Xmm and thus (Figure 28.3)
p iron+ p
mec
x
x
x
x
x
p
iron
x
x
x
x
x
2
p mec
s
(V )
Vsn
1
0.1
Figure 28.2 Mechanical plus core losses at no load (open auxiliary winding)
piron
Rmiron H" (28.10)
2I2
m0
The impedance at no load Zom is
2 2
Vs Rrm Xmm + Xrm
ł ł ł
Zom = = Rsm + Rmiron + + + Xsm ł (28.11)
ł ł ł ł
Im0 ł 4 2
łł ł łł
Equation (28.11) allows us to calculate again Xmm. An average of the value
obtained from (28.7) and (28.11) may be used for more confidence.
Now that all parameters are known, it is possible to refine the results by
introducing the magnetization reactance Xmm in the shortcircuit impedance,
while still Xsm = Xrm, to improve the values of Rrm and Xsm until sufficient
convergence is obtained.
Today numerical methods available through many software programs on
PCs allow for such iterative procedures to be applied rather easily.
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
I
m0
Rsm jXsm
jX
sa
R Z C a= 0
sa I
R
miron
Xmm
ja (R miron 1
+ jX mm I
) m
j
2
2
E
a
V
s
Rrm
4
rm rm
-ja(R4 + j X rm I
)
m
2
X
rm
j
2
Figure 28.3 Simplified no load (S = 0) equivalent circuit with series core loss resistance Rmiron in both
circuits (the auxiliary winding is open)
Example 28.1
A 123 W (1/6 hp), 6 poles, 60 Hz, 110 V, split phase motor was tested as
follows [1]
Rsm = 2.54 &! after locked rotor reading, Rsm = 2.65 &! after no-load single phase
running.
Locked rotor watts at 110 V is Psc = 851 W.
No-load current Im0 at Vs0 = 105 V is Im0 = 2.68 A. Locked rotor current is Isc =
11.65A.
h
Vs0 = Vsn - ImnRsm cos n = 110 - 3.17 2.85 0.588 H" 105V (28.12)
h
where Imn = 3.17 A, Rsm = 2.85&! , cosn = 0.588, full load slip Sn = 0.033. Full
load input P1n = 205 W and rated efficiency n = 60.5 % have been obtained
from a direct load (brake) test.
The no-load power versus applied volts Vs, produces (piron)Vs0 = 24.7 W and
mechanical losses pmec = 1.5 W.
The no-load auxiliary winding voltage Ea = 140.0 V.
The value of turns ratio a is found from an additional no-load test with the
auxiliary winding fed at 1.2 Ea (V). With the measured no-load main winding
voltage Em0 = 105 V, a is (28.8)
1401401.2
a = = 1.46
105105
Let us now find the motor parameters and directly check the efficiency
measured by the loss segregation method.
The rotor resistance (referred to the main winding) Rrm is (28.1)
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
851
Rrm = - 2.54 = 3.73&!
11.652
The stator and rotor leakage reactances Xrm = Xsm from (28.3) are
2
1 105
ł ł 2
Xsm = Xrm =
ł ł - (3.73 + 2.54) = 3.237&!
2
ł11.65 łł
Rrm is getting larger during the no load test, due to heating, to the same
extent that Rsm does
o
Rsm 2.65
Ro = Rrm = 3.73 = 3.89&!
rm
Rsm 2.54
Now the magnetisation reactance Xmm, from (28.7), is
2 2
ł 140.0 3.89
ł ł ł
Xmm = 2
ł ł - ł ł - 3.237 = 77.57&!
4
ł1.46 2.58 łł ł łł
with the core resistance Rmiron (28.10)
piron 24.7
Rmiron = = = 1.87&!
2I2 2 " 2.582
m0
Now from (28.11) we may recalculate Xmm
2 2
105 3.89
ł ł ł2.65 +1.87 + ł
Xmm = 2
ł ł - ł ł - 3.237 = 74.71&!
2.58 4
ł łł ł łł
An average of the two Xmm values would be 76.1235 &!.
By now the parameter problem has been solved. A few iterations may be
used with the complete circuit at S = 1 to get better values for Rrm and Xsm =
Xrm. However,we should note that Xmm / Xrm H" 20, and thus not much is to be
gained from these refinements.
For efficiency checking we need to calculate the winding losses at Sn =
0.033 with the following parameters
h
Rsm 2.85
h
Rsm = 2.85&!, Rh = Ro = 3.89 = 4.1835&!
rm rm
o
Rsm 2.65
Xsm = Xrm = 3.237&!, Xmm = 76.12&!
The core resistance Rmiron may be neglected when the rotor currents are
calculated
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
j" Xmm j" 76.12
Irmf = Im = 3.117 " = 1.586A
Rh
rm
+ j"(Xmm + Xrm)4.1835 + j"(76.12 + 3.237)
0.033
Sn
Irmb H" Im = 3.117A
So the total rotor winding losses pCorotor are
Rh Rh
pCorotor = I2 rm + I2 rm = (3.1172 +1.5862)4.1835 = 25.58W
rmf rmb
2 2 2
The stator copper losses pcos are
h
pcos = I2 Rsm = 3.1172 2.85 = 27.69W
m0
The total load losses Łp from loss segregation, are
"p = pcos + pCorotor + piron + pmec = 27.69 + 25.58 + 24.7 +1.5 = 79.47W
The losses calculated from the direct load test are
("p) = Pin - Pout = 205 -123 = 82W
load
There is a small difference of 2 W between the two tests, which tends to
validate the methods of loss segregation. However, it is not sure that this is the
case for most designs.
It is recommended to back up loss segregation by direct shaft loading tests
whenever possible.
It is possible to define the stray load losses as proportional to stator current
squared and then to use this expression to determine total losses at various load
levels
2
stray load losses = (Łp) - Łpsegregation H" Rstray[I2 + (Iaa) ]
load m
Rstray may then be lumped into the stator resistances Rsm and Rsa / a2.
28.3 THE CASE OF CLOSED ROTOR SLOTS
In some single phase IMs (as well as three phase IMs) closed rotor slots are
used to reduce noise.
In this case the rotor slot leakage inductance varies with rotor current due to
the magnetic saturation of the iron bridges above the rotor slots.
The shortcircuit test has to be done now for quite a few values of voltage
(Figure 28.4)
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
A'
Vsc
V
sc
j(X +X )Imsc
sm rm
sc E0sc
E0sc
0sc A
Imsc (R sm
Imsc
+R rm)Imsc
Figure 28.4 Shortcircuit characteristics
In this case, the equivalent circuit should additionally contain a constant
e.m.f. E0sc, corresponding to the saturated closed rotor upper iron bridge (Figure
28.5).
Only the segment AA2 -E0sc (on Figure 28.5) represents the voltage drop on
the rotor and stator constant leakage reactances.
Vsc sin sc - E0sc
Xsm + Xrm = (28.13)
Imsc
28.4 LOSS SEGREGATION THE PERMANENT CAPACITOR IM
The loss segregation for the permanent capacitor IM may be performed as
for the single phase IM, with only the main winding (Ia = 0) activated.
The auxiliary winding resistance and leakage reactance Rsa and Xsa may be
measured, in the end, by a shortcircuit (zero speed) test performed on the
auxiliary winding
2
Psca H" (Rsa + Rra )Isca (28.14)
2
ł ł
Vsca
2
ł ł - (Rsa + Rra )
Xsa + Xra = (28.15)
ł ł
Isca
ł łł
When Xra = a2Xrm (with a and Xrm known, from (28.13)) it is possible to
calculate Xsa with measured input power and current. With Rsa d.c. measured,
Rra may be calculated from 28.14.
The capacitor losses may be considered through a series resistance RC (see
Figure 28.1). The value of RC may be measured by separately supplying the
capacitor from an a.c. source.
The active power in the capacitor PC and the current through the capacitor
IC are directly measured
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
PC
RC = (28.16)
2
IC
R
rm
Rrm
2 2 (2 - S)
jX
mm
jXmm
X
rm
X
rm
j j
2
2
E
E 0sc
0sc
2 2
Zf
Z
b
Figure 28.5 The forward (f, b) impedances for the closed slot rotor
Once all parameters are known, the equivalent circuit in Figure 28.1 allows
for the computation of both stator currents, Im and Ia, under load with both
phases on, and given slip value, S. Consequently, the stator and rotor winding
losses may then be determined.
From this point on, we repeat the procedure in the previous paragraph to
calculate the total losses by segregation method and from direct input and output
measurements, with the machine shaft loaded.
28.5 SPEED (SLIP) MEASUREMENTS
One problem encountered in the load tests is the slip (speed) measurement.
Unless a precision optical speedometer (with an error in the range of 2 rpm
or less) is available, it is more convenient to measure directly the slip frequency
Sf1.
The  old method of using a large diameter circular shortcircuited coil with
a large number of turns-to track the axial rotor leakage flux by a current Hall
probe (or shunt), may be used for the scope.
The coil is placed outside the motor frame at the motor end which does not
hold the cooling fan. Coil axis is concentric with the shaft.
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
The acquired current signal contains two frequencies Sf1 and (2-S)f1. An
off-line digital software (or a low pass hardware) filter may be applied to the
current signal to extract the Sf1 frequency component.
The slip computation error is expected to be equivalent to that of a 2 rpm
precision speedometer or better.
28.6 LOAD TESTING
There are two main operation modes to test the single phase IM on load the
motor mode and the generator mode.
Under the motor mode the electric input power, P1e, and the output
mechanical power, P2m, are measured. P2m is in fact calculated indirectly from
the measured torque Tshaft and speed n
P2m = Tshaft " 2Ąn (28.16)
The torque is measured by a torquemeter (Figure 28.6). Alternatively the
load machine may have the losses previously segregated such that at any load
level the single-phase IM mechanical power P2m may be calculated
P2m = P3e - (28.17)
"p
loadmachine
The load machine may be a PM d.c. or a.c. generator with resistive load, a
hysteresis or an eddy current d.c. brake.
~
P1e
Łp load
machine
P3e
P2m
Single
Torque dc or ac Resistive
phase
tranducer generator load
I.M.
Figure 28.6 Load tests with a torquemeter
28.7 COMPLETE TORQUE-SPEED CURVE MEASUREMENTS
Due to magnetic saturation m.m.f. space harmonics, slotting, and skin effect
influences on harmonic rotor currents, it seems that direct torque measurements
at various speeds (below rated speed) is required.
Such a measurement may be performed by using a d.c. or an a.c. generator
with power-converter energy retrieval to the power grid (Figure 28.7).
Alternatively a slow acceleration test on no load may be used to calculate
the torque speed curve. For slow acceleration, the supply voltage may be
lowered from Vsn to Vs.
The core losses are considered proportional to voltage squared. They are
measured by the loss segregation method.
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
2
ł ł
Vs
ł ł
piron = (piron )Vsn (28.18)
Vsn
ł ł
ł łł
static
Single 3 ~
Torque dc or ac
power
phase
tranducer generator
converter
I.M.
~
Torque
generator
Single phase I.M.
speed
Figure 28.7 Torque/speed measurements with a torquemeter
The mechanical losses proportional to speed squared
2
ł ł
ł ł
pmec = (pmec)n (28.19)
n0
ł ł
n0
ł łł
With Rsm, Rrm, Rsa, Xsm, Xra, Xrm, Xmm known and with Im and Ia and input
power measuredm P1, torque may be calculated as for steady state around rated
speed.
2 2
pmec [P1 - piron - RsmI2 - RsaIa - Rrm(I2 + I2 )- RCIa](28.20)
m rmf rmb
Te = + Tshaft =
2Ąn 2Ąn
The computation of Tshaft is to be done offline. An optical speedometer
could be used to measure the speed during the slow acceleration test and during
a free deceleration after turn-off.
With pmec(n) known, the free deceleration test yields
pmec(n)
J = - (28.21)
dn
2Ą
dt
The moment of inertia J is thus obtained.
With J known and speed n acquired during the no-load slow acceleration
test, the torque is
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
dn pmec
Te(n)= J2Ą + (28.22)
dt 2Ąn
The torque for rated voltage is considered to be
2
ł ł
Vsn
ł ł
(Te(n)) H" (Te(n)) (28.23)
Vsn Vs
ł ł
Vs
ł łł
The speed derivative in (28.22) may be obtained offline, with an appropriate
software filter, from the measured speed signal.
The two values of torque, (28.20) and (28.22), are then compared to
calculate a measure of stray losses
2
ł ł
Vsn
ł ł
pstray H" [(Te) - (Te (n)) ]" 2Ąn (28.24)
Equation(28.22) Equation(28.20)
ł ł
Vs
ł łł
Temperature measurements methods are very similar to those used for three
phase IMs. Standstill d.c. current decay tests may also be used to determine the
magnetization curve mm(Imm) and even the resistances and leakage reactances,
as done for three phase IMs.
28.8 SUMMARY
" The single phase IM testing aims to determine equivalent circuit parameters
to segregate losses and to measure the performance on load; even to
investigate transients.
" Due to the backward field (current) component, even at zero slip, the rotor
current (loss) is not zero. This situation complicates the loss segregation in
no load tests.
" The no load test may be done with the auxiliary phase open Ia = 0, after the
motor starts.
" The shortcircuit (zero speed) test is to be performed, separately for the main
and auxiliary phases, to determine the resistances and leakage reactances.
" Based on these results the no load test (with Ia = 0) furnishes data for loss
segregation and magnetization curve (Xmm(Imm)), provided it is performed
for quite a few voltage levels below rated voltage.
" The calculation of rotor resistance Rrm from the zero speed test (at 50 (60)
Hz) produces a value that is acceptable for computing on load performance,
because it is measured at an average of forward and backward rotor current
Sf1 + (2 - S)f1
frequencies = f1 .
2
" The difference between total losses by segregation method and by direct
input / output measurements under load is a good measure of stray load
losses. The stray load losses tend to be smaller than in three phase motors
because the ratio between full load and no load current is smaller.
2002 by CRC Press LLC
Author Ion Boldea, S.A.Nasar& & & & ..& & & ..
" Instead of single (main) phase no load and shortcircuit tests, symmetrical
two voltage supplying for same tests has also been proved to produce good
results.
" The complete torque-speed curve is of interest also. Below the breakdown
torque speed value there may be a deep in the torque speed curve around 33
% of no load ideal speed (f1 / p1) due to the third space m.m.f. harmonic. A
direct load method may be used to obtain the entire torque versus speed
curve. Care must be exercised that the load machine had a rigid torque /
speed characteristic to handle the statically unstable part of the single-phase
IM torque-speed curve down to standstill.
" To eliminate direct torque measurements and the load machine system, a
slow free acceleration at reduced voltage and a deceleration test may be
performed. With the input power, speed and stator currents and voltage
measured and parameters already known (from the shortcircuit and single
phase no load tests), the torque may be computed after loss subtraction
from input at every speed (slip). The torque is also calculated from the
motion equation with inertia J determined from free deceleration test. The
mechanical power difference in the two measurements should be a good
measure of the stray load losses caused by space harmonics. The torque in
the torque / speed curve thus obtained is multiplied by the rated to applied
voltage ratio squared to obtain the full voltage torque-speed. It is
recognized that this approximation underestimates the influence of
magnetic saturation on torque at various speeds. This is to say that full
voltage load tests from S = 0 to S = 1 are required for magnetic saturation
complete consideration.
" DC flux (current) decay tests at standstill, in the main and auxiliary winding
axes, may also be used to determine resistances, leakage inductances and
the magnetization curve. Frequency response standstill tests may be applied
to single phase IM in a manner very similar to one applied to three phase
IMs (Chapter 22).
" Temperature measurement tests are performed as for three phase IMs, in
general (Chapter 22).
28.9 REFERENCES
1. C. G. Veinott, Segregation of Losses in Single Phase Induction Motors,
Trans AIEE, Volume 54, December 1935, pp. 1302-1306.
2. C. Van der Merwe and F. S. Van der Merwe, Study of Methods to Measure
the Parameters of Single Phase Induction Motors, IEEE Trans. vol. EC-10,
no. 2, 1995, pp. 248-253.
2002 by CRC Press LLC


Wyszukiwarka

Podobne podstrony:
0004 PDF?3
r05 0004
obraz 0004
0004 PDF?5
0004 131105 Ustawa pragmatyczna 14
r04 0004
0004 PDF?6
Photo 0004
darmowy pdf8
r02 0004
0004 PDF TOC
ORT w5s4 0004

więcej podobnych podstron