Title: EE20A Electromechanical Energy Conversion
1Department of Electrical and Computer Engineering
- EE20A - Electromechanical Energy Conversion
- Induction Machine
2Principle of Operation
- The stator coils, when energised, create a
rotating magnetic field. - Rotating magnetic field cuts through the rotor
inducing a voltage in the rotor bars. - This voltage creates its own magnetic field in
the rotor. - The rotor magnetic field will attempt to line up
with the stator magnetic field. - The stator magnetic field is rotating, the rotor
magnetic field trying to line up with the stator
magnetic field causes the rotor to rotate. - The rotor magnetic field, never catches up, but
follows slightly behind.
3Motor Analysis
- Slip is the difference between the speed of the
stator magnetic field and the speed of the rotor - SLIP,S, (NS - N) / NS
- When motor is stationary, it behaves like a
transformer - At a given Speed, flux cutting rate is reduced gt
thereby reducing output voltage by a factor of
the slip.
4Analysis
Per Phase Equivalent Circuit
5Analysis
Per Phase Equivalent Circuit
6Analysis
7Power per Phase
- Total Torque
- (3Pmech_gross- PFW)/wm
- Pag I12Rr/s
- Pcu sPag
- Pmech_gross (1-s)Pag
8Power per Phase
Pag Power across the air gap
9Power per Phase
P mech_gross (1-s) Pag per phase
10Power per Phase
Pcu_losses_in_rotor Pmech_gross
Pag Pcu Pmech 1s(1-s)
11Power per Phase
Slip is variable and affects only rotor circuit
Ignoring Stator values
12Power per Phase
13Torque
Simple Algebraic manipulations yield
14Torque
15Torque
Since the above calculations was derives as power
per phase, then the total torque for all three
phases would be three times the gross mechanical
torque for each phase calculated above.
16Torque
The maximum torque is obtained when
17Torque Characteristics
18Speed-Torque characteristics
Modifications in the design of the squirrel-cage
motors permit a certain amount of control of the
starting current and torque characteristics.
These designs have been categorised by NEMA
Standards (MG1-1.16) into four main
classifications 1. Normal-torque,
normal-starting current motors (Design A) 2.
Normal-torque, low-starting current motors
(Design B) 3. High-torque, low-starting-current,
double-wound-rotor motors (Design C) 4.
High-slip motors (Design D)
19Design A Motor
- Hp range 0.5 500 hp.
- Starting current 6 to 10 times full-load current.
- Good running efficiency (87 - 89).
- Good power factor (87 - 89).
- Low rated slip (3 5 ).
- Starting torque is about 150 of full load
torque. - Maximum torque is over 200 but less than 225 of
full-load torque. - Typical applications constant speed
applications where high starting torque is
not needed and high starting torque is tolerated.
-
20Design B Motor
- Hp range 0.5 to 500 hp
- Higher reactance than the Design A motor,
obtained by means of deep, narrow rotor bars. - The starting current is held to about 5 times the
full-load current. - This motor allows full-voltage starting.
- The starting torque, slip and efficiency are
nearly the same as for the Design A motor. - Power factor and maximum torque are little lower
than class A, - Design B is standard in 1 to 250 hp drip-proof
motors and in totally enclosed, fan-cooled
motors, up to approximately 100 hp. - Typical applications constant speed
applications where high starting torque is not
needed and high starting torque is tolerated. - Unsuitable for applications where there is
a high load peak
21Design C Motor
- Hp range 3 to 200 hp
- This type of motor has a "double-layer" or double
squirrel-cage winding. - It combines high starting torque with low
starting current. - Two windings are applied to the rotor, an outer
winding having high resistance and low reactance
and an inner winding having low resistance and
high reactance. - Operation is such that the reactance of both
windings decrease as rotor frequency decreases
and speed increases. - On starting a much larger induced currents flow
in the outer winding than in the inner winding,
because at low rotor speeds the inner-winding
reactance is quite high.
22Design C Motor
- As the rotor speed increases, the reactance of
the inner winding drops and combined with the low
inner-winding resistance, permits the major
portion of the rotor current to appear in the
inner winding. - Starting current about 5 times full load current.
- The starting torque is rather high (200 - 250).
- Full-load torque is the same as that for both A
and B designs. - The maximum torque is lower than the starting
torque, maximum torque (180-225). - Typical applications constant speed
loads requiring fairly high starting torque
and lower starting currents.
23Design D Motor
- Produces a very high starting
torque-approximately 275 of full-load torque. - It has low starting current,
- High slip (7-16),
- Low efficiency.
- Torque changes with load
- Typical applications- used for high
inertia loads - The above classification is for squirrel cage
induction motor
24Wound Rotor
- Hp 0.5 to 5000hp
- Starting torque up to 300
- Maximum torque 225 to 275 of full load torque
- Starting current may be as low as 1.5 times
starting current - Slip (3 - 50)
- Power factor high
- Typical applications for high starting torque
loads where very low starting current is required
or where torque must be applied very gradually
and where speed control is needed.
25Current Effects on the Motor
- Induction motor current consists of reactive
(magnetizing) and real (torque) components. - The current component that produces torque (does
useful work) is almost in phase with voltage, and
has a high power factor close to 100 - The magnetizing current would be purely
inductive, except that the winding has some small
resistance, and it lags the voltage by nearly
90. - The magnetizing current has a very low power
factor, close to zero. - The magnetic field is nearly constant from no
load to full load and beyond, so the magnetizing
portion of the total current is approximately the
same for all loads. - The torque current increases as the load
increases
26Current Effects on the Motor
- At full load, the torque current is higher than
the magnetizing current. - For a typical motor, the power factor of the
resulting current is between 85 and 90. - As the load is reduced, the torque current
decreases, but the magnetizing current remains
about the same so the resulting current has a
lower power factor. - The smaller the load, the lower the load current
and the lower the power factor. Low power factor
at low loading occurs because the magnetizing
remains approximately the same at no load as at
full load
27Methods to vary speed of the Induction Motor
An induction motor is a constant-speed device.
Its speed depends on the number of poles in the
stator, assuming that the voltage and frequency
of the supply to the motor remain constant.
- One method is to change the number of poles in
the stator, for example, reconnecting a 4-pole
winding so that it becomes a 2-pole winding will
double the speed. This method can give specific
alternate speeds but not gradual speed changes. - Another method is to vary the line voltage this
method is not the best since torque is
proportional to the square of the voltage, so
reducing the line voltage rapidly reduces the
available torque causing the motor to stall
28Methods to vary speed of the Induction Motor
- Sometimes it is desirable to have a high
starting torque or to have a constant horsepower
output over a given speed range. These and other
modifications can be obtained by varying the
ratio of voltage to frequency as required. Some
controllers are designed to provide constant
torque up to 60 Hz and constant hp above 60 Hz to
provide higher speeds without overloading the
motor. - An excellent way to vary the speed of a
squirrel-cage induction motor is to vary the
frequency of the applied voltage. To maintain a
constant torque, the ratio of voltage to
frequency must be kept constant, so the voltage
must be varied simultaneously with the frequency.
Modern adjustable frequency controls perform this
function. At constant torque, the horsepower
output increases directly as the speed increases.
29NO LOAD TEST
Per Phase Equivalent Circuit
30NO LOAD TEST
- n - ns 0 No load Speed ? Synchronous
Speed - i.e. no power transfer which implies that Torque
0 - I1 0 T 0
- Power Consumed Core Losses Friction
Windage - Measure Vph , IIN and Wph
- ? ? ( Infinite Impedance ) since
I1 0
31NO LOAD TEST
- INL I0 jIm
- ? INL ? ( cos ?NL - jsin ?NL )
- cos ?NL Wph
- Vph ? INL ?
- Ro Vph
Xm Vph - I0
Im
32Lock Rotor Test
33Lock Rotor Test
- In the Lock Rotor test, No Load Speed, n 0
- Slip, s ns 0 1,
s 1 - ns
- Then Rr ?? Rr
- s
- Apply Voltage to Variac, VLR (10 - 25 ) Vph
- Since INLltlt I1
Then INL ? 0 - Measure values VLR , ILR and WLR
34Lock Rotor Test
- Zeq VLR / ILR
- cos ?LR WLR
- VLR ? ILR ?
- Zeq ?Zeq ? cos ?LR - jsin ?LR
- ?Zeq ? cos ?LR - ?Zeq ? jsin
?LR - Rs Rr
Xs Xr
35Lock Rotor Test
- At Standstill Under d.c. conditions ? 0
-
? X ?L -
? X 0 - R1 R2 can be measured using an ohmmeter over
two stator windings, which gives a value of Rs - Rr Zeq cos ?LR - Rs