The document discusses induction motors, also known as asynchronous motors. It describes their construction, including the stator, rotor, and rotating magnetic field produced. Squirrel cage and wound rotors are covered. Formulas for synchronous speed, slip, and rotor frequency are provided. Examples calculations are given to demonstrate determining speeds and frequencies under different operating conditions. The per-phase equivalent circuit of an induction motor is also mentioned.
Infinite bus bar is one which keeps constant voltage and frequency although the load varies. Thus it may behave like a voltage source with zero internal impedance and infinite rotational inertia.
Infinite bus bar is one which keeps constant voltage and frequency although the load varies. Thus it may behave like a voltage source with zero internal impedance and infinite rotational inertia.
An induction is an AC electric motor in which the electric current in the rotor needed to produce torque is obtained by electromagnetic induction from the magnetic field of the stator winding. An induction motor therefore does not require mechanical commutation, separate-excitation or self-excitation for all or part of the energy transferred from stator to rotor, as in universal, DC and large synchronous motors. An induction motor's rotor can be either wound type or squirrel-cage type.
he main purpose of transient stability studies is to determineThe main purpose of transient stability studies is to determine
whether a system will remain in synchronism following major
disturbances such as transmission system faults, sudden load
changes, loss of generating units, or line switching.
A synchronous motor is electrically identical with an alternator or AC generator.
A given alternator ( or synchronous machine) can be used as a motor, when driven electrically.
Some characteristic features of a synchronous motor are as follows:
1. It runs either at synchronous speed or not at all i.e. while running it maintains a constant speed. The only way to change its speed is to vary the supply frequency (because NS=120f/P).
2. It is not inherently self-starting. It has to be run up to synchronous (or near synchronous) speed by some means, before it can be synchronized to the supply.
3. It is capable of being operated under a wide range of power factors, both lagging and leading. Hence, it can be used for power correction purposes, in addition to supplying torque to drive loads.
The motor which runs at synchronous speed is known as the synchronous motor. The synchronous speed is the constant speed at which the motor generates the electromotive force. The synchronous motor is used for converting the electrical energy into mechanical energy.
he stator and rotor are the two main parts of the synchronous motor. The stator is the stationary part, and the rotor is the rotating part of the machine. The three-phase AC supply is given to the stator of the motor.
This presentation provides information about Synchronous Motor.
Transient stability analysis on a multi machine system in psateSAT Journals
Abstract
Modern power system are subject to large disturbances such as three phase short circuit faults. When a fault occurs on a system
the generators rotor angle becomes unstable and thus it losses synchronism with the system and it becomes unstable. Thus
transient stability analysis can be performed on a system in order to understand the generators performance when subjected to a
short circuit fault. When the system is subjected to a fault the generator experiences transient oscillations in rotor speed and
angle which can be effectively suppressed with the incorporation of Automatic Voltage Regulator (AVR) and Power System
Stabilizer (PSS). The simulations have been performed using the MATLAB/PSAT software.
Keywords—Transient stability, Three phase fault Faults, AVR, PSS.
Objectives: This course will provide a comprehensive overview of power system stability and control problems. This includes the basic concepts, physical aspects of the phenomena, methods of analysis, the integration of MATLAB and SINULINK in the analysis of power system .
Course Content: 1. Power System Stability: Introduction
2. Stability Analysis: Swing Equation
3. Models for Stability Studies
4. Steady State Stability
5. Transient Stability
6. Multimachine Transient Stability
7. Power System Control: Introduction
8. Load Frequency Control
9. Automatic generation Control
10. Reactive Power Control
Physical Description
Mathematical Model
Park's "dqo" transportation
Steady-state Analysis
phasor representation in d-q coordinates
link with network equations
Definition of "rotor angle"
Representation of Synchronous Machines in Stability Studies
neglect of stator transients
magnetic saturation
Simplified Models
Synchronous Machine Parameters
Reactive Capability Limits
Consists of two sets of windings:
3 phase armature winding on the stator distributed with centres 120° apart in space
field winding on the rotor supplied by DC
Two basic rotor structures used:
salient or projecting pole structure for hydraulic units (low speed)
round rotor structure for thermal units (high speed)
Salient poles have concentrated field windings; usually also carry damper windings on the pole face.Round rotors have solid steel rotors with distributed windings
Nearly sinusoidal space distribution of flux wave shape obtained by:
distributing stator windings and field windings in many slots (round rotor);
shaping pole faces (salient pole)
Functions and Performance Requirements
Elements of an Excitation System
Types of Excitation Systems
Control and Protection Functions
Modeling of Excitation Systems
The functions of an excitation system are
to provide direct current to the synchronous generator field winding, and
to perform control and protective functions essential to the satisfactory operation of the power system
The performance requirements of the excitation system are determined by
Generator considerations:
supply and adjust field current as the generator output varies within its continuous capability
respond to transient disturbances with field forcing consistent with the generator short term capabilities:
rotor insulation failure due to high field voltage
rotor heating due to high field current
stator heating due to high VAR loading
heating due to excess flux (volts/Hz)
Power system considerations:
contribute to effective control of system voltage and improvement of system stability
The frequency of a system is dependent on active power balance
As frequency is a common factor throughout the system, a change in active power demand at one point is reflected throughout the system
Because there are many generators supplying power into the system, some means must be provided to allocate change in demand to the generators
speed governor on each generating unit provides primary speed control function
supplementary control originating at a central control center allocates generation
In an interconnected system, with two or more independently controlled areas, the generation within each area has to be controlled so as to maintain scheduled power interchange
The control of generation and frequency is commonly known as load frequency control (LFC) or automatic generation control (AGC)
An induction is an AC electric motor in which the electric current in the rotor needed to produce torque is obtained by electromagnetic induction from the magnetic field of the stator winding. An induction motor therefore does not require mechanical commutation, separate-excitation or self-excitation for all or part of the energy transferred from stator to rotor, as in universal, DC and large synchronous motors. An induction motor's rotor can be either wound type or squirrel-cage type.
he main purpose of transient stability studies is to determineThe main purpose of transient stability studies is to determine
whether a system will remain in synchronism following major
disturbances such as transmission system faults, sudden load
changes, loss of generating units, or line switching.
A synchronous motor is electrically identical with an alternator or AC generator.
A given alternator ( or synchronous machine) can be used as a motor, when driven electrically.
Some characteristic features of a synchronous motor are as follows:
1. It runs either at synchronous speed or not at all i.e. while running it maintains a constant speed. The only way to change its speed is to vary the supply frequency (because NS=120f/P).
2. It is not inherently self-starting. It has to be run up to synchronous (or near synchronous) speed by some means, before it can be synchronized to the supply.
3. It is capable of being operated under a wide range of power factors, both lagging and leading. Hence, it can be used for power correction purposes, in addition to supplying torque to drive loads.
The motor which runs at synchronous speed is known as the synchronous motor. The synchronous speed is the constant speed at which the motor generates the electromotive force. The synchronous motor is used for converting the electrical energy into mechanical energy.
he stator and rotor are the two main parts of the synchronous motor. The stator is the stationary part, and the rotor is the rotating part of the machine. The three-phase AC supply is given to the stator of the motor.
This presentation provides information about Synchronous Motor.
Transient stability analysis on a multi machine system in psateSAT Journals
Abstract
Modern power system are subject to large disturbances such as three phase short circuit faults. When a fault occurs on a system
the generators rotor angle becomes unstable and thus it losses synchronism with the system and it becomes unstable. Thus
transient stability analysis can be performed on a system in order to understand the generators performance when subjected to a
short circuit fault. When the system is subjected to a fault the generator experiences transient oscillations in rotor speed and
angle which can be effectively suppressed with the incorporation of Automatic Voltage Regulator (AVR) and Power System
Stabilizer (PSS). The simulations have been performed using the MATLAB/PSAT software.
Keywords—Transient stability, Three phase fault Faults, AVR, PSS.
Objectives: This course will provide a comprehensive overview of power system stability and control problems. This includes the basic concepts, physical aspects of the phenomena, methods of analysis, the integration of MATLAB and SINULINK in the analysis of power system .
Course Content: 1. Power System Stability: Introduction
2. Stability Analysis: Swing Equation
3. Models for Stability Studies
4. Steady State Stability
5. Transient Stability
6. Multimachine Transient Stability
7. Power System Control: Introduction
8. Load Frequency Control
9. Automatic generation Control
10. Reactive Power Control
Physical Description
Mathematical Model
Park's "dqo" transportation
Steady-state Analysis
phasor representation in d-q coordinates
link with network equations
Definition of "rotor angle"
Representation of Synchronous Machines in Stability Studies
neglect of stator transients
magnetic saturation
Simplified Models
Synchronous Machine Parameters
Reactive Capability Limits
Consists of two sets of windings:
3 phase armature winding on the stator distributed with centres 120° apart in space
field winding on the rotor supplied by DC
Two basic rotor structures used:
salient or projecting pole structure for hydraulic units (low speed)
round rotor structure for thermal units (high speed)
Salient poles have concentrated field windings; usually also carry damper windings on the pole face.Round rotors have solid steel rotors with distributed windings
Nearly sinusoidal space distribution of flux wave shape obtained by:
distributing stator windings and field windings in many slots (round rotor);
shaping pole faces (salient pole)
Functions and Performance Requirements
Elements of an Excitation System
Types of Excitation Systems
Control and Protection Functions
Modeling of Excitation Systems
The functions of an excitation system are
to provide direct current to the synchronous generator field winding, and
to perform control and protective functions essential to the satisfactory operation of the power system
The performance requirements of the excitation system are determined by
Generator considerations:
supply and adjust field current as the generator output varies within its continuous capability
respond to transient disturbances with field forcing consistent with the generator short term capabilities:
rotor insulation failure due to high field voltage
rotor heating due to high field current
stator heating due to high VAR loading
heating due to excess flux (volts/Hz)
Power system considerations:
contribute to effective control of system voltage and improvement of system stability
The frequency of a system is dependent on active power balance
As frequency is a common factor throughout the system, a change in active power demand at one point is reflected throughout the system
Because there are many generators supplying power into the system, some means must be provided to allocate change in demand to the generators
speed governor on each generating unit provides primary speed control function
supplementary control originating at a central control center allocates generation
In an interconnected system, with two or more independently controlled areas, the generation within each area has to be controlled so as to maintain scheduled power interchange
The control of generation and frequency is commonly known as load frequency control (LFC) or automatic generation control (AGC)
Coal Fired Power Plant
-Types of coal
-Traditional coal-burning power
plant
-Emission control for traditional
coal burning plant
-Advanced coal-burning power
plant
-Environmental effects of coal
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1. CHAPTER 3
INDUCTION MACHINE
3.1 INTRODUCTION
• Induction motor is the common type of AC motor.
• Induction motor was invented by Nicola Tesla (1856-1943) in 1888.
• Also known as asynchronous motor.
• It has a stator and a rotor mounted on bearings and separated from the stator by an air
gap.
• It requires no electrical connection to the rotating member.
• Such motor are classified induction machines because the rotor voltage (which
produce the rotor current and the rotor magnetic field) is induced in the rotor winding
rather than being physically connected by wires.
• The transfer of energy from the stationary member to the rotating member is by
means of electromagnetic induction.
• This motor is widely used by the industries because:
- Rugged. - Simple construction.
- Robust. - Reliable.
- High efficiency. - Good power factor.
- Require less maintenance - Easy to start.
- Rotates itself without external assistant.
- Less expensive than direct current motor of equal power and speed.
• The weaknesses of this machine are:
- Low starting torque if compared to dc shunt motor.
- Speed will be reduced when load increased.
- Speed can’t be changed without reducing efficiency.
• Small single phase induction motors (in fractional horsepower rating) are used in
many household appliances such as:
- Blenders
- Lawn mowers
- Juice mixers
- Washing machines
- Refrigerators
• Two phase induction motors are used primarily as servomotor in control system.
49
2. • Large three phase induction motors (in ten or hundreds of horsepower) are used in:
- Pumps - Fans
- Compressors - Paper mills
- Textile mills, and so forth.
3.2 INDUCTION MOTOR CONSTRUCTION
• Unlike dc machine, induction machine have a uniform air gap.
• Composed by two main parts:
- Stator
- Rotor
• Figure 4.1 and 4.2 show the inside of induction machine.
Figure 3.1
50
3. Figure 3.2
Stator Construction
The stator and the rotor are electrical circuits that perform as electromagnets. The stator
is the stationary electrical part of the motor. The stator core of a NEMA motor is made up
of several hundred thin laminations.
Figure 3.3:Stator core
Stator Windings
Stator laminations are stacked together forming a hollow cylinder. Coils of insulated wire
are inserted into slots of the stator core.
51
4. Figure 3.4:Stator winding
Each grouping of coils, together with the steel core it surrounds, form an electromagnet.
Electromagnetism is the principle behind motor operation. The stator windings are
connected directly to the power source.
Rotor Construction
• The rotor also consists of laminated ferromagnetic material, with slot cuts on the
outer surface.
• The rotor are of two basic types :
- Squirrel cage
- Wound rotor
Squirrel cage rotor
• It consist of a series of a conducting bars laid into slots carved in the face of the rotor
and shorted at either ends by large shorting ring.
• This design is referred to as squirrel cage rotor because the conductors would look
like one of the exercise wheels that squirrel or hamsters run on.
• Small squirrel cage rotors use a slotted core of laminated steel into which molten
aluminums cast to form the conductor, end rings and fan blades.
• Larger squirrel cage rotors use brass bars and brass end rings that are brazed together
to form the squirrel cage.
52
5. • Skewing the rotor slots help to:
- Avoid crawling (locking in at sub-synchronous speeds)
- Reduce vibration
• Squirrel cage rotor is better than wound rotor because it is:
- Simpler
- More rugged
- More economical
- Require less maintenance
Figure 3.5:Squirrel cage Rotor
Figure 3.6 : Rotor core
53
6. Figure 3.7
Wound rotor
• Has a complete set of three phase insulated windings that are mirror images of the
winding on stator.
• Its three phase winding are usually wye connected and ends of three rotor wires are
tied to a slip rings on the rotor shaft.
• The rotor winding are shorted through carbon brushes riding on the slip rings.
• The existence of rheostat enable user to modify the torque speed characteristic of the
motor. It is used to adjust the starting torque and running speed.
• The three phase rheostat is composed of three rheostat connected in wye with a
common lever.
• Lever is used to simultaneously adjust all the three rheostat arms. Eg: Moving
rheostat to the zero resistance position shorts the resistor and simulates a squirrel
cage motor.
• Are rarely used because:
- More expensive than squirrel cage induction motor.
- Larger than squirrel cage induction motor with similar power.
- Require frequent maintenance due to wear associates to brushes and slip ring.
54
7. Figure 3.8 Wound rotor induction motor showing rheostat connections
Figure 3.9:Wound rotor
3.3 ROTATING MAGNETIC FIELD
• When a three phase stator winding is connected to a three-phase voltage supply,
three-phase currents will flow in the winding which induce three-phase flux in the
stator.
• These flux will rotate at a speed called as Synchronous Speed, ns.
• The flux is called as rotating magnetic field.
55
8. 120 f
• The equation is:- n s = where f = supply frequency , p = no. of poles
p
• Rotating magnetic field will cause the rotor to rotate the same direction as the stator
flux.
• Torque direction is always the same as the flux rotation.
• At the time of starting the motor, rotor speed is 0.
• The rotating magnetic field will cause the rotor to rotate from 0 speed to a speed that
is lower than the synchronous speed.
• If the rotor speed is equal to the synchronous speed, there will be no cutting of flux
and rotor current equals zero. Therefore, it is not possible for the rotor to rotate at ns.
3.4 SLIP AND ROTOR SPEED
• Slip is defined as :
ns − n
s=
ns
where ns = synchronous speed in rpm
n = rotor speed in rpm
• Slip can also represented in percent.
• The frequency of the rotor, fr is:
f r = sf
where s = slip
f = supply frequency
Example 1
Calculate the synchronous speed of a 3-phase induction motor having 20 poles when it is
connected to a 50 Hz source.
Solution
120 f 120(50)
ns = = = 300rpm
p 20
Example 2
56
9. A 0.5 hp, 6-pole induction motor is excited by a 3 –phase, 60 Hz source. If the full-load
speed is 1140 rpm, calculate the slip.
Solution
120 f 120(60)
ns = = = 1200rpm
p 6
n − n 1200 − 1140
s= s = = 0.05 = 5%
ns 1200
Example 3
The 6-pole,wound-rotor induction motor is excited by a 3-phase, 60 Hz source. Calculate
the frequency of the rotor current under the following conditions:
(i) at standstill
(ii) motor turning at 500 rpm in the same direction as the revolving field
(iii) motor turning at 500 rpm in the opposite direction to the revolving field
(iv) motor turning at 2000 rpm in the same direction as the revolving field
Solution
ns = 120f / p = 120(60/6) = 1200 rpm
(i) n=0
ns − n 1200 − 0
s= = =1
ns 1200
fr = sf = 1 x 60 = 60Hz
(ii) n = +500
ns − n 1200 − 500
s= = = 0.583
ns 1200
fr = sf = 0.583 x 60 = 35 Hz
(iii) n = -500
ns − n 1200 − (−500)
s= = = 1.417 (s>1 motor is operating as a brake)
ns 1200
fr = sf = 1.417 x 60 = 85 Hz
57
10. (iv)n = +2000
ns − n 1200 − 2000
s= = = −0.667
ns 1200
fr = sf = -0.667 x 60 = -40 Hz (-ve means that the phase sequence of the voltages induced
in the rotor winding is reversed)
Example 4
A 3-phase, 4 pair of poles, 400kW,400V,60Hz induction motor is 780 rpm full-load
speed. Determine the frequency of the rotor current under full load condition.
Solution
f rotor = sf
120 f 120(60)
n s= = = 900rpm
p 8
ns − n 900 − 780
s= = = 0.133
ns 900
f r = sf = 0.133(60) = 8Hz
3.5 PER-PHASE EQUIVALENT CIRCUIT OF THREE-PHASE INDUCTION
MOTOR
The per-phase equivalent circuit of a three-phase induction motor is just like a single –
phase transformer equivalent circuit.
The difference is only that the secondary winding is short-circuited unlike in the
transformer it is open-circuited as a load is to be connected later.
Complete Equivalent Circuit For Induction Machine Referred To The Stator Circuit
58
11. I1 R1 X1 I2 X2
1,0k
Rm Xm R2
1,0m
V input 1,0m
1,0k
1,0m
s
Figure 3.10
The subscript ‘1’ is refering to the stator side while ‘2’ is referring to the rotor side
R1, X1, R2, Rm , Xm are value perphase
Input Power, Pin = 3V1I1cosθ
Stator copper loss, Pscl = 3I12R1
Core Loss, Pcl = 3V12/Rm (always neglected because too small)
Power across the air-gap, Pag = 3I22R2 /s
= Pin - Pscl - Pcl
Rotor copper loss, Prcl = 3I22R2
Mechanical power/gross output power/converted power,
P mech = Pag – Prcl
= 3I22R2 /s - 3I22R2
= Pag (1-s)
Net power output, Poutput = P mech – P friction & windage loss
For Torque:
60 Pm Pm Pag
Tmechanical / induced = Tm = = =
2πn wr ws
60 P0 Pout
Toutput / load = To = =
2πn wr
59
12. 3(Vsup ply − p ) 2 R2
Tstarting =
ws [ (R
1 + R2 ) 2
+ (X1 + X 2 )2 ]
3(Vsup ply − p ) 2 1
Tmax =
2 ws [ 2
R1 + R1 + ( X 1 + X 2 ) 2 ]
R2
Maximum Slip: S max = 2
R1 + ( X 1 + X 2 ) 2
3.6 POWER FLOW OF AN INDUCTION MOTOR
P CONV = P MECH
PAG=(3I22R2)/s
=PAG-PRCL
= Pin-PSCL-PCL
PRCL=3I22R2
PSCL=3I12R1 PCL= = sPag
3V12/RM
Figure 3.11
60
13. Example 5
A 10 poles, 50 Hz, Y connection 3-phase induction motor having a rating of 60kW and
415V. The slip of the motor is 5% at 0.6 power factor lagging. If the full load efficiency
is 90%, calculate:
(i) Input power
(ii) Line current and phase current
(iii) Speed of the rotor (rpm)
(iv) Frequency of the rotor
(v) Torque developed by the motor (if friction and windage losses is 0)
Solution
Pout
(i) η =
Pin
Pout 60kW
Pin = = = 66666.7W
η 0.9
VL
(ii) Y connection, IΦ = IL, VΦ=
3
P in =3VΦIΦcos= 3VLIL cos θ
Pin 66.67 kW
IL = = = 154.59 A
3VL cos θ 3 (415)(0.6)
IΦ = IL=154.59 ∠ cos −1 0.6 = 154.59∠ − 53.13° A
120 f 120(50)
(iii) n s = = = 600rpm
p 10
ns − n
s=
ns
n = n s (1-s) = 600 (1-0.05) = 570 rpm
(iv) fr = sf = 0.05(50) = 2.5Hz
Pm Pout 60kW
(v) T = = = = 1005.2 Nm
wm 2πnm / 60 2πnm / 60
Or
2πf 2πf
ws= = = 62.83rad / s
p/2 5
wm = ws(1-s) = 62.83(1-0.05) = 59.69 rad/s
60kW
T= = 1005.2 Nm
59.69rad / s
61
14. Example 6
A 3-phase, delta connection, 4 pole, 440V, 60 Hz induction motor having a rotor speed
1200rpm and 50kW input power at 0.8 power factor lagging. The copper losses and iron
losses in the stator amount to 2kW and the windage and friction losses are 3kW.
Determine:
(i) Net output power
(ii) Efficiency
(iii) Input current
Solution
(i) ns = 120f/p = 120(60)/4 = 1800 rpm
ns − n 1800 − 1200
s= = = 0.33
ns 1800
P input(to stator) P input rotor /Pag Pmech=Pout rotor P out net
=50kW =50kW-2kW =(48-16)kW =(32-3)kW
=48kW =32kW =29kW
P stator losses P rotor losses P wind and fric
=2kW =s(P input rotor) losses
= 0.33(48kW) =3kW
=16kW
P net output = 29kW
Pout 29kW
(ii) η = = = 58%
Pin 50kW
(iii)Δ connection
Pin = 3V p I p cos θ
Pin 50kW
Ip = = = 47.35∠ cos −1 0.8 = 47.35∠ − 36.87° A
3V p cos θ 3( 440)(0.8)
I L = 47.35 3 = 82 A
62
15. Example 7
A 3-phase induction motor, delta connection,5 pair of poles, 60 Hz is connected to a
440V source.The slip is 3% and the windage and friction losses are 3kW. The
equivalent circuit perphase referred to the stator circuit is:-
R1 = Stator resistance = 0.4Ω
X1 = Stator leakage inductance = 1.4Ω
R2’ = Rotor resistance = 0.6Ω
X2’ = Rotor leakage inductance = 2Ω
Rm = no-load loses resistance = 150Ω
Xm = magnetizing reactance = 20Ω
Calculate:
(i) Input power
(ii) Speed of the rotor
(iii) Mechanical power
(iv) Developed torque
(v) Efficiency
Solution
0.4Ω j1.4Ω j2Ω
I1 I2
60Hz,
1.0m
1.0k
440v, V2 1.0k
1.0m
1.0m
10 S j20Ω R2/s=0.6/0.03=20Ω
poles,
Δ
(i) P in =3VIcosθ
V = 440V
20 j ( 20 + 2 j )
Z total = 0.4 + 1.4 j + = 9.45 + 11.45 jΩ
20 j + 20 + 2 j
V 440
I1 = = = 18.87 − 22.86 j = 29.64∠ − 50.46° A
Ztotal 9.45 + 11.45 j
Pin = 3(440)(29.64)cos(-50.460) = 24907.5W
120 f 120(60)
(ii) ns = = = 720rpm
p 10
ns − n
s= ,
ns
n = ns(1-s) , n = 720(1-0.03) = 698.4 rpm
63
16. (iii) Pm = 3(I22R2/s – I22R2)
V2 = 440 – I1Z1
= 440 – (18.87-22.86j)(0.4+j1.4)
= 400.45-17.27j V
V 2 400.45 − j17.27
I2 = = = 19.74 − j 2.84 = 19.94∠ − 8.19° A
Z2 20 + j 2
0.6
Pm = 3 [19.942 - 19.942(0.6)] = 23140.5W
0.03
Pag Pm
(iv) T dev = =
ws wm
Pag = 3I22R2/s = 3(19.94)2(0.6)/(0.03) = 23856.2W
2πf 2π (60)
ws = = = 75.4rad / s
p 2 5
23.856.2
T = = 316.4 Nm
75.4
Poutput 23140.5W − 3kW
(v) η = = = 81%
Pin 24901.5W
Example 8
A 3-phase induction motor, wye connection, 60 Hz is connected to a 220V source.The
slip is 5% and rotor speed is 855 rpm. The equivalent circuit perphase is:-
R1 = Stator resistance = 0.4Ω
X1 = Stator leakage inductance = 1Ω
R2’ = Rotor resistance = 0.8Ω
X2’ = Rotor leakage inductance = 3.5Ω
Rm = no-load loses resistance = 150Ω
Xm = magnetizing reactance = 10Ω
Calculate:
(i) Number of poles
(ii) Input power
(iii) Mechanical power
(iv) Developed torque
(v) Efficiency
64
17. Solution
0.4Ω j1Ω j3.5Ω
60Hz,
1.0m
1.0k
220V, 1.0k
1.0m
1.0m
S j10Ω R2/s=0.8/0.05=16Ω
Y
(i) n = 855rpm
s = 0.05
ns = 120f/p
ns − n
s= , sns = ns – n , n = ns – sns
ns
= ns(1-s)
n
ns =
1− s
855
= = 900rpm
1 − 0.05
ns = 120f/p
120 f 120(60)
p= = = 8 pole
ns 900rpm
(ii) Pin = 3V L I L cos θ
(16 + j 3.5)( j10)
Z total = 0.4 + j1 + = 4.05 + j 7.9 Ω
16 + j 3.5 + j10
220 3
I1 = = 6.53 − j12.73 = 14.3∠ − 62.84° A
4.05 + j 7.9
Pin = 3 (220)(14.3)(cos− 62.84°) = 2487.36W
(iii) Pm = 3(I22R2/s – I22R2)
220
V2 = – I1Z1
3
220
= – (6.53-j12.73)(0.4+j1)
3
= 111.68-1.438j V
V 2 111.68 − j1.438
I2 = = = 6.64 − j1.54 = 6.8∠ − 13° A
Z2 16 + j 3.5
65
18. 0.8
Pm = 3 [6.82 - 6.82(0.8)] = 2108.54W
0.05
Pag Pm
(iv) T dev = =
ws wm
Pag = 3I22R2/s
2πf 2π (60)
ws = = = 94.25rad / s
p 2 4
T = (3I22R2/s) / ws =[3(6.8)2(0.8)/(0.05)] / 94.25 = 23.55Nm
Poutput 2108.54
(v) η= = = 0.85 = 85%
Pin 2487.36
3.7 TORQUE SPEED CHARACTERISTICS
Figure 3.12
There are 3 regions involve in a 3-phase induction motor:-
(i) Braking/Plugging
Braking process occurs at s>0(positive slip). In this case the motor acts as a brake
where it rotates in opposite direction respect to the rotor.(2<slip<1).
66
19. (ii) Motoring
Motoring is the region where induction motor acts as a motor. Slip is reducing
from 1 into 0. Slip equals to 0 at synchronous speed,ns.(1<slip<0).
(iii) Generating
Generating region is a region where motor acts as a generator. During this time
the slip is negative. At this time, the motor acts as a generator.(slip<0)
3.8 DETERMINATION OF CIRCUIT MODEL PARAMETER
The parameter of the equivalent circuit can be determined from the results of a:
- No load test
- Blocked rotor test
-.DC test
The blocked rotor test:
- To determine X1 and X2
- When combines with DC test, it also determines R2
- Test is performed by blocking the rotor so that it cannot turn and measuring the line
voltage, line current and three phase power input to the stator
- Connection for the test is shown in Figure 4.13
Figure 3.13 Basic circuit for blocked rotor test and no load test
The no load test:
- To determine magnetizing reactance, Xm, and the combined core, friction and windage
losses (these losses are essentially constant for all load condition)
- The connection for the no load test are identical to those shown in Figure 12
- However, the rotor is unblocked and allowed to run unloaded at rated voltage and rated
frequency
67
20. DC test:
- To determine R1
- Accomplished by connecting any two stator leads to a variable voltage DC source as
shown in Figure 4.14.
- The DC source is adjusted to provide approximately rated stator current, and the
resistance between two stator leads is determined from voltmeter and ammeter reading
Figure 3.14 Basic circuit for DC test
Example 9
The following test data were taken on a 7.5hp, four pole, 208 V, 60 Hz Y connected
design A induction motor having a rated current of 28A.
DC test : Vdc = 13.6V Idc = 28 A
No-load test: Vt = 208 V f = 60 Hz
Ia = 8.12 A P in = 420 W
Ib = 8.2 A
Ic = 8.18 A
Locked rotor test: Vt = 25 V f = 15 Hz
Ia = 28.1 A P in = 920 W
68
21. Ib = 28 A
Ic = 27.6 A
Sketch the per-phase equivalent circuit for this motor.
Solution
From the DC test,
VDC 13.6V
R1 = = = 0.243Ω
2 IDC 2( 28.0 A)
From the no-load test,
8.12 A + 8.2 A + 8.18 A
IL = = 8.17 A
3
208
Vφ = = 120V
3
120V
Z= = 14.7Ω = X 1 + X 2
8.17 A
Pscl = 3I12R1 = 3(8.17A)2(0.243Ω) = 48.7W
Pag = Pin –Pscl = 420W- 48.7W = 371.3W
From the locked-rotor test,
28.1A + 28 A + 27.6 A
IL = = 27.9 A
3
Vφ 25 3
Z= = = 0.517Ω
I 27.9 A
Pin = 3VLIL cos θ
Pin 920W
θ = cos-1 = = 40.4°
3VLIL 3 (25V )(27.9 A)
R1 + R2 = 0.517(cos 40.4°) = 0.394Ω
69
22. DC test, R1 = 0.243Ω, R2 = 0.394Ω – 0.243Ω = 0.151Ω
At 15 Hz, X = 0.517(sin 40.4°)=0.335Ω
60 Hz
At 60 Hz, X = (0.335Ω) = 1.34Ω = X1 + X2
15Hz
For class A induction motor, this reactance is assumed to be divided equally between the
rotor and stator,
X1 = X2 = 0.67 Ω
Xm = 14.7 -0.67 = 14.03Ω
3.9 STARTING OF INDUCTION MOTOR
(i) Direct On Line Starter(DOL)
- A widely-used starting method of electric motors.
- The simplest motor starter.
- A DOL starter connects the motor terminals directly to the power supply.
- Hence, the motor is subjected to the full voltage of the power supply.
- Consequently, high starting current flows through the motor.
-This type of starting is suitable for small motors below 5 hp (3.75 kW).
- Most motors are reversible or, in other words, they can be run clockwise and anti-
clockwise.
- A reversing starter is an electrical or electronic circuit that reverses the direction of a
motor automatically.
- Logically, the circuit is composed of two DOL circuits; one for clockwise operation and
the other for anti-clockwise operation.
- It takes a starting current 6(six) times the full load current.
- For large motor the high starting current causes voltage drop in the power system which
may trip other motors in the systems.
(ii)Star-Delta Starter
- For star-delta connection the motor windings are connected in star during starting.
- The connection is changed to delta when the motor starts running.
- The starting current and starting torque of DOL started and start-delta connected motors
are as follows:
Example:
DOL -6I and 2T
Star-delta - 2I and 2T/3
70
23. - Thus it can be seen that the starting current and starting torque are both reduced.
- The motor should be capable to start at such reduced torque with load.
- The Star Delta starter can only be used with a motor which is rated for connection in
delta operation at the required line voltage
(iii)Autotransformer starter
- An Auto transformer starter uses an auto transformer to reduce the voltage applied to a
motor during start.
- The auto transformer may have a number of output taps and be set-up to provide a
single stage starter, or a multistage starter.
- Typically, the auto transformer would have taps at 50%, 65% and 80% voltage,
enabling the motor to be started at one or more of these settings.
- As the motor approaches full speed, the auto transformer is switched out of the circuit
71
24. Tutorial 3
1. A 3 phase induction machine 373kW, 6 poles is connected to a 440V, 50 Hz, has a full
load speed of 950 rpm. If the machine is comprised of 6 poles, calculate the frequency of
the rotor current during full load.
2. Determine the synchronous speed of a six pole 460V 60 Hz induction motor if the
frequency is reduced to 85 % of its rated value.
3. A 4 pole induction machine is supplied by 60 Hz source and having 4% of full load
slip. Calculate the rotor frequency during:
(i) Starting
(ii) Full load
4. A 3-phase induction motor, delta/star connection, 2 poles, 50 Hz is connected to a
410V
source .The rotor speed is 2880 rpm and the windage and friction losses are 600 W. The
equivalent circuit perphase referred to the stator circuit is:-
R1 = 0.4Ω X2 =2Ω
X1 =2Ω Rm = 150Ω
R2 =2Ω Xm = 20Ω
Calculate:
(i) Input power
(ii) Air-gap power
(iii) Mechanical power
(iv) Developed torque/torque induced
(v) Efficiency
5. A 440V, 50Hz, 10 pole, delta/Y connected induction motor is rated at 100kW. The
equivalent parameter for the motor are:
Rs = 0.08Ω / phase RR = 0.1Ω / phase
'
X s = 0.3Ω / phase X R = 0.2Ω / phase
'
X m = 6Ω / phase Rc = ∞
At full load condition , the friction and windage losses are 400W, the miscellaneous
losses are 100W and the core losses are 1000W. The slip of the motor is 0.04.
(i) Calculate the input power
(ii) Calculate the stator copper loss
(iii) Calculate the air gap power
(iv) Calculate the converted power
(v) Calculate the torque induced by the motor
(vi) Calculate the load torque
(vii) Calculate the starting torque
(viii) Calculate the maximum torque and slip
(ix) Calculate the efficiency of the motor
72
25. 6. Squirrel cage and wound rotors are the two common types of rotor used in
induction machines. Give four(4) advantages of squirrel cage rotor.
7. A 4 pole induction machine is supplied by 50 Hz source and having 4% of full load
slip. Find the rotor frequency during:
(i) Starting
(ii) Full load
8. A 3-phase, Y-connected, 50 Hz, 4 pair of poles, induction motor having 720 rpm full
load speed. The motor is connected to a 415 V supply. The machine has the following
impedances in ohms per phase referred to the stator circuit:
R1 = 0.2 Ω X1 = 2.0 Ω
R2 = 0.9 Ω X2 = 4.0 Ω
Xm = 60 Ω
If the total friction and windage losses are 200 W,
(i) Find the slip, s.
(ii) Find the input power, Pin.
(iii) Find the air gap power, Pag.
(iv) Find the mechanical power, Pm.
(v) Find the torque induced by the motor, τ ind.
(vi) Find the efficiency of the motor.
9. Induction machine is a common type of AC machine. State three weaknesses of the
induction machine.
10. A 3-phase, delta-connected, 50 Hz, 2 pair of poles, induction motor having 1455
rpm full load speed. The motor is connected to a 415 V supply. The machine has the
following impedances in ohms per phase referred to the stator circuit:
R1 = 0.2 Ω X1 = 0.6 Ω
R2 = 0.9 X2 = 0.4 Ω
Xm = 20 Ω
If the total friction and windage losses are 1000 W, calculate:
(i) Slip
(ii) Input power, Pin
(iii)Air gap power, Pag
(iv) Mechanical power, Pconv
(v) Torque induced by the motor, τ ind
(vi)Efficiency of the motor
11. A 3-phase, Y-connected, 6 poles, 415 V, 50 Hz induction motor having a rotor speed
950 rpm. The input power is 100 kW at 0.85 power factor lagging. The copper and iron
losses in the stator are 4 kW and the windage and friction losses are 4 kW. Determine the
output power of the motor.
73