Novel setting and design of relay for protection of 3 phase induction motor using pscad

IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
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Volume: 04 Issue: 02 | Feb-2015, Available @ http://www.ijret.org 554
NOVEL SETTING AND DESIGN OF RELAY FOR PROTECTION OF 3-
PHASE INDUCTION MOTOR USING PSCAD
Pathik N. Shah1
, Smith N. Patel2
, Jay A. Patel3
, Umang S. Wani4
1
Student, B.Tech Electrical Engineering, C. G. Patel Institute of Technology, Gujarat, India
2
Student, B.Tech Electrical Engineering, C. G. Patel Institute of Technology, Gujarat, India
3
Assistant Professor, Department of Electrical Engineering, C. G. Patel Institute of Technology, Gujarat, India
4
Assistant Professor, Department of Electrical Engineering, C. G. Patel Institute of Technology, Gujarat, India
Abstract
This paper is designed to protect an Induction Motor from different types of abnormalities. Providing protection for motors is very
important in industries, power plants etc. such that production is not hampered owing to failure of any motor. Purpose of motor
protection is to limit the effect of disturbances and stress factors to a safe level. If a motor failure takes place, the protection is
needed to disconnect the motor from the supply network in due time. Here we have described different abnormal conditions in
three phase induction motors and designed a protective scheme to protect it from different abnormalities. We have also described
the method which shows how to set electromagnetic relay for large motor and also described the same method in case of
numerical relay. Here we have shown one of the faulty condition with the help of PSCAD (student version).
Keywords: Induction motor, Relay, PSCAD student version.
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1. INTRODUCTION
Electric motors are exposed to many kinds of disturbances
and stresses. Part of the disturbances is due to imposed
external conditions such as over-voltage and undervoltage,
over-frequency and under-frequency, unbalanced system
voltages and supply interruptions. Other possible causes of
external disturbances are dirt in the motor, cooling system
and bearing failures or increase of ambient temperature and
humidity. Stress factors due to abnormal use of the motor
drive are frequent successive startups, stall and overload
situations including mechanical stress. The above stress and
disturbances deteriorate the winding insulation of the motor
mechanically and may eventually lead to an insulation
failure.
1.1 Introduction to Motors
There are many different types and sizes of motors used in
practice. This paper deals with protection arrangement for
large 3-phase induction motors. The motor rated upto 415
volts can be protected by starters of various kinds having in-
built thermal overload relays and no-volt release facility,
and very often protection for short circuits can be provided
by switch-fuse units. Large and medium range 3-phase
induction motors are used for running power station
auxiliaries and in large industries for various purposes.
These motors are controlled by circuit breakers and
associated protective relay. Such motors need
comprehensive protective arrangement to achieve the
desired degree of security and dependability.
1.2 Introduction to Relays
A relay is an electrically operated switch. Relays are used
wherever it is necessary to protect equipment which plays a
vital role in industries. There are different types of relays
according to their principles and construction. Majorly they
can be classified as electromagnetic relay, static relays and
numerical relay. Electromagnetic relays contain the moving
parts due to which its construction becomes difficult so
static relays are used which does not contain any moving
parts, they are usually made up of active semiconductor
devices such as diodes, transistor, IC’s etc. which process
the electrical inputs to get desired relay or the numerical
relay has many advantages compared to other two types of
relays. From storing of historical data to group settings, it
also gives us the facility such as flexibility, compactness,
self-checking facility, simplicity of interfacing with CT and
PT, time synchronization with GPS system and many more
facilities.
2. TYPES OF ABNORMALITIES IN MOTORS
There are different types of abnormalities because of which
the motor fails to start or behaves abnormally. Some of the
abnormalities can be explained as below.
2.1 Overloading
Motor overload condition is mainly a result from abnormal
use of motor, harmonics or unbalanced supply voltages. The
load on the motor is mechanical load. When mechanical
load on the motor is gradually increased, the speed of the
motor gradually decreased and slip is increased. With
increase in the slip the current increases. The heat generated
goes on increasing the temperature of the winding and with

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increase in the temperature, the rate of heat dissipation also
increases. In this manner when the load is increased beyond
the rated load the current will increase to subsequently very
high level. The conductors of stator and rotor are not
affected in due to this increase in the temperature but the
insulation around these conductors is certainly affected. The
insulation can get detoriated due to temperature rise and can
eventually fail. The curve plotted below shows the
maximum allowable time v/s multiples of rated current of
induction motor. If the motor is overloaded in cold
condition, the time ordinate will be higher than when motor
is overloaded to the same level from the hot condition. So
accordingly, we get two almost parallel curves namely ‘Cold
curve’ and ‘Hot curve’.
Fig -1: Thermal withstand characteristics of induction motor
2.2 Single Phasing
Single phasing can occur as a result of fuse blowing or one
phase conductor develops an open circuit fault or in case
one pole of a circuit breaker not making contact while an
induction motor is running. If the motor is loaded more than
it’s rated full load, the torque produced by the remaining
two positive rotating fields continues to rotate the motor and
develops the torque demanded by the load. Due to this
voltage may be nearly equal to phase voltage that was lost
but it will draw excessive current, due to this, motor will
heat up quickly. Due to single phasing, an unbalance current
also takes place. The negative sequence component of this
unbalance current causes the rotor to overheat. The motor
becomes noisy and starts vibrating due to uneven torque
produced in the motor. The windings may melt due to
overheating and can give a fatal shock to the personnel.
2.3 Unbalanced Current
Unbalanced phase currents are the source of negative
sequence current in the motor. Unbalanced voltage causes
negative phase sequence voltage to be developed and the
negative sequence currents generated will be approximately
6 times the negative sequence voltage. Form the utility
perspective, unbalance voltages may be caused by
frequently increase or decrease in the load or possibly by
fuses being blown on distribution capacitors. For the
costumer, current unbalance can cause adverse effects on
motor including the damaging of motors.
2.4 Stalling
When the heavy load is thrown on the motor abruptly the
will stall. If there is heavy load on the motor at the time of
starting, the motor cannot start and the rotor gets blocked. In
such a condition the motor is said to be stalling. The rotor of
induction motor may be locked because of gear drive
jamming or bearing failure. Under the condition of stalling
or locked rotor, the speed of the rotor will be very small or
most often zero. In this condition, the motor will draw a
very high current of order of 15 – 20 times the rated current.
2.5 Undervoltage
If the voltage drops when the motor is running at the full
rated load, the current taken by the motor increases. This is
because the power to be delivered remains constant and the
voltage is reduced from the normal rated voltage. The effect
of an increased motor current can cause damage to the
insulation of the motor windings.
Fig -2: Voltage dip
2.6 Reversed Phase Sequence
If the phase sequence in the supply circuit of an induction
motor is reversed only the negative sequence currents are
taken by the motor and the motor will run in the opposite
direction when started. The loads like fan, pump etc cannot
be run in the other direction than the one which they are
meant to run. Hence, reverse rotation will damage the load.

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Fig -3: Phase Sequence reversal
3. PROTECTION FROM ABNORMALITIES
As shown above, the motor suffers from many abnormal
conditions in the field due to which the capital cost of
replacing the motor may be costly. It is better to prevent the
fault but in case if the system fails to prevent the fault, a
protective scheme must be approached.
3.1 Thermal Overload Protection
The majority of winding failures are either indirectly or
directly caused by overloading operation on unbalanced
supply voltage, or single phasing, which all leads through
excessive heating to the deterioration of the winding
insulation until an electrical fault occurs. The generally
accepted rule is that insulation life is halved for each 10°C
rise in temperature above the rated value, modified by the
length of time spent at the higher temperature. As an
electrical machine has a relatively large heat storage
capacity, it follows that infrequent overloads of short
duration may not adversely affect the machine.
However, sustained overloads of only a few percent may
result in premature ageing an insulation failure.
Furthermore, the thermal withstand capacity of the motor is
affected by heating in the winding prior to a fault. It is
therefore important that the relay characteristics takes
account of the extremes of zero and full load pre-fault
current known respectively as the ‘Cold’ and ‘Hot’
conditions. Below figure shows that the thermal relay shall
not to be operated when the motor is started. If relay
operates during starting of motor, the hot characteristic gets
overlapped with the motor characteristic which is shown
below. This condition should be avoided.
Fig -4: Incorrect selection of thermal relay
3.2 Short Circuit Protection
Motor short-circuit protection is often provided to avoid
major stator winding faults and terminal flashovers. As the
stator windings are completely enclosed in grounded metal,
the fault would very quickly involved earth, which would
then operate the instanteous earth fault protection. A single
definite time overcurrent relay element is all that is required
for protection. The time delay is required to prevent
spurious operation due to CT spill currents. The normal
definite time overcurrent protection would not be
sufficiently sensitive, and sensitive earth fault protection
may not be provided. An instanteous overcurrent relay can
be used for protecting the motor against such conditions
with pick-up setting equal to a value of starting current at
75% of the rated voltage can be selected.
3.3 Negative Phase Sequence Protection
Negative phase sequence is generated from any unbalanced
voltage condition, such as unbalanced loading, loss of a

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single phase, or single-phase faults. The latter will normally
be detected by earth fault protection; however, a fault
location in a motor winding may not result in the earth fault
protection operating unless it is of the sensitive variety.
There are two strategies for this purpose, one uses definite
time overcurrent relay. Time delay is kept of 6 to 10 cycles,
high current drawn during starting of the motor i.e. 15 to 20
times the rated current can bypassed. Thus, for some time,
current seen by relay is zero. The pick-up ratio of definite
time overcurrent relay is normally set on 50% of starting
current of an induction motor.
Another purpose is better practice as the tripping time is
inversely proportional to the square of negative phase
sequence current of the stator. This setting is based on Z2/Z1
ratio and is normally set at 20-80% of the relay setting.
3.4 Protection against Stalling
In certain cases of heavy overloading, the motor may not
fully stop running but speed variations may be found around
a lower steady-state speed. If these variations are at a safer
limit with respect to electrical and mechanical stresses on
the motor insulation and rotor parts respectively, and the
motor has not lost synchronism, certain time is needed by
the motor to gain a steady and stable state. This time is
called safe stalling time. In such cases, immediate tripping is
not required but the scheme should be made such that it
restrains for some time and a situation still persists, tripping
occurs.
Motor stalling can be recognized by the motor current
exceeding the start current threshold after a successful start
– i.e. a motor start has been detected and the motor current
has dropped below the start current threshold within the
motor safe stall time. A subsequent rise in the motor current
above the motor starting current threshold is then indicative
of a stall condition, and tripping will occur if this condition
persists for greater than the setting of a stall timer. A
definite time overcurrent relay element provides protection.
Fig -5: Safe stalling time
3.5 Earth Fault Protection
One of the most common faults to occur on a motor is a
stator winding fault. Whatever the initial form of the fault or
the cause, presence of surrounding metallic frame and
casing will ensure that it rapidly develops into a fault
involving earth. Therefore, providing earth fault protection
is very important.
Earth fault protection is usually provided by a simple
instantaneous overcurrent relay and is normally set at 20%
of the full load current of the motor. In this scheme,
operation of the relay due to saturation of the CT during
initial high starting current should be avoided. This can be
achieved by increasing the voltage setting of the relay by
inserting a stabilizing resistor in series with it.
3.6 Under Voltage Protection
When a specific undervoltage trip is required in the industry
or at power stations, a definite time overvoltage element is
used. If two elements are provided, alarm and trip settings
can be used. The voltage and time delay settings will be
system and motor dependent. They must allow for all
voltage dips likely to occur on the system during transient
faults, starting of motor, etc. to avoid spurious trips. As
motor starting can result in a voltage depression to 80% of
nominal, the voltage setting is likely to be below this value.
4. SETTING FOR ELECTROMAGNETIC
RELAY
Rating of an Induction Motor
Output Power (Pa) = 1200W
Efficiency = 90%
Power factor = 0.8
Rated voltage= 6.6kV
Starting time at 100% voltage = 10 seconds
Starting time at 80% voltage = 15 seconds
Rating of the Relay
Staring Current = 6 times rated current
Safe stalling time= 20 seconds
CT ratio = 200/1 A
Permissible continuous overload withstand = 110% of rated
current
Negative sequence impedance Z2 = 20%
Positive sequence impedance Z1 = 80%
Setting of the Relay
Thermal Overload Relay 70-130%
Instanteous Overcurrent Relay 400-2000%
Negative Phase Sequence
current relay
10-40%
Under voltage relay 70-110%
Definite time overcurrent
(Stalling) Relay
150-600%

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Efficiency = Output
Input
Input = Output = 1200 = 1333.33 kW
Efficiency 0.9
P = √3VIcosƟ
I= 1333.33 X 103
√3 X 6.6 X 103
X 0.8
I = 145.79 A
CT ratio = 200/1 A
If 200A passes through the CT primary and 1A from CT
secondary, then for 145.79A then 0.7289A passes through
the CT secondary.
For Thermal Overload Relay
This relay picks up at the 105% and trips at 110% of relay
setting.
Therefore,
0.7289 X 1.1 = 0.763
1.05
0.763 X 100% = 76.3%
The thermal overload relay has the range of 70-130% for 1A
in steps of 5%.
So, the Thermal Overload relay is kept at 80% setting.
For Short Circuit Protection
Starting current is 6 times the rated current
Rated current = 145.79 A
Starting current = 6x145.79 = 874.79 A
Here the starting current is 75% of the rated voltage.
874.79 = 1130.38 A
0.75
5.691A passes through the CT secondary
100% of 5.651A = 565.1%
The instanteous overcurrent relay has the range of 400-
2000% for 1A in steps of 50%
So, the Instanteous Overcurrent relay is kept at 600%
setting.
For Negative Phase Sequence Protection
Here the relay is set at half of the starting current
Starting current = 874.79 A
874.79 = 437.37 A
2
Z2/Z1 = 20%/80% = 25%
The Negative Phase Sequence current relay has the range of
10-40% for 1A in 7 equal steps.
So, the Negative Phase Sequence current relay is kept at
25% setting.
For under Voiltage Protection
Primary Voltage = 6.6kV
For under voltage protection the voltage is 70% of primary
voltage
70% of 6.6kV = 4620V
PT ratio = 6600/110 V
77 V Passes through the PT secondary
The under voltage relay has the range of 70-110% of rated
voltage.
So, for the Under Voltage relay 70% of 110V is selected
for setting.
For stalling protection
The fault current is 1/3 starting current
Starting current = 847.79 A
874.79 = 291.59 A
3
1.457 A passes through the CT secondary
100% of 1.457 A = 145.7%
The stalling relay has the range of 150-600% in steps of
30%
So, the Stalling relay is kept at 150% setting.
5. SETTING FOR NUMERICAL RELAY
Table 1: Settings for numerical relay
Parameters Range Steps Settings
Thermal
Overload
Protection
5%-250% 1% 77%
Instantaneous
Overcurrent
Protection
50%-1500% 50% 600%
Negative
Phase
sequence
Protection
0.2 – 10sec 0.1sec 0.2sec
Stalling
Protection
200% -
1500%
50% 200%

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6. PSCAD AND SIMULATIONS
6.1 Simulation and Results
6.1.1 Model for Effect of Torque on Speed
Fig -6: Simulation model for effect of torque on speed
From the above figure, an induction motor is given a supply of 11kV at 50Hz. An ammeter and voltmeter is kept in series with
motor to measure the current and voltage of motor respectively. The motor is started in the speed mode and then it is switched to
torque mode after 0.1 seconds. From the figure shown below it can seen that as the motor switches to torque mode, the speed
gradually decreases.
Fig -7: Output waveform

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6.1.2 Model for Overcurrent Protection
Fig -8: Simulation for overcurrent protection
In this simulation the switching from speed mode to torque mode is done at 0.2 seconds. The ratings of the motor are kept same
with a 3-phase supply of 415V at 50Hz. The fault block is used to apply a line to ground fault on line A after 0.3 seconds.
The graph below shows that as soon as the fault is applied, a tripping signal is generated which opens the circuit breakers.
Fig -9: Output waveform before and after tripping
Figure 9 shows that when the source current raises to its peak value due to fault in line, the trip signal is generated by the relay and
the breaker opens isolating the motor from the faulty section and source current becomes zero.

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Fig -10: Behavior of source current
7. CONCLUSION
By setting relays as per this paper, many motors which are
used for different purposes in industries can be protected
from various abnormalities and faults. The proper setting of
the relay is done which is attached with the motor so that
they operate as per their characteristic and the system can be
saved, thus proper task is completed without any
interruption. By doing this, eventually maintenance of the
power station or industry can be decreased.
ACKNOWLEDGEMENTS
We would like to acknowledge all the faculties of Electrical
Department of CGPIT, Uka Tarsadia University, Bardoli
those who always extended their hands in all kind of
problems regarding this project. We would also like to thank
our family and friends who supported us to led this paper
towards success.
REFERENCES
[1]. “A Novel Protecting Method for Induction Motor
against Faults Due to Voltage unbalance and Single
Phasing” – Mrs. M. SUIDHA, Dr. P. ANBALAGAN.
[2]. “Stall protection of large Induction motors” – Jose
DeCastro, Roy Beck, Charles Cai, Luke Yu.
[3]. “Behaviour of Induction Motor due to Voltage Sag and
Short Interruptions.” – Juan C. Gomez, Medhat M. Morcos,
Claudio A. Reineri Gabriel N. Campetelli.
[4]. “Thermal overload protection of Induction motors under
waveform distortion”- MojtabaKhederzadeh.
[5]. “Simulating Voltage Sag Using PSCAD Software “-
Kang Chia Yang, Hushairi HJ Zen , Nurlkhmar, Najemeenb
Binti Ayob.
[6]. “Power System Protection and Switch Gear” –
Bhuvanesh A Oza Nirmal-Kumar C Nair, Rashesh P Mehta,
Vijay H Makwana.
[7]. “Principles of Electrical Machines”- V.K. Mehta.
[8]. “Fundamental of Power System Protection”- Y.G.
Paithankar S.R. Bhide.
BIOGRAPHIES
Pathik N. Shah, pursuing B.Tech in
Electrical Engineering at CGPIT, Uka
Tarsadia University, Bardoli, Surat
E-Mail ID: pathikshah05@gmail.com
Smith N. Patel , pursuing B.Tech in
Electrical Engineering at CGPIT, Uka
Tarsadia University ,Bardoli, Surat
Email ID: smithpatel55@gmail.com
Jay A. Patel, Assistant Professor in
Department of Electrical Engineering at
CGPIT,
Uka Tarsadia University, Bardoli, Surat
E-Mail ID: jay.patel@utu.ac.in
Umang S. Wani, Assistant Professor in
Department of Electrical Engineering
at CGPIT, Uka Tarsadia University,
Bardoli, Surat
E-Mail ID: umang.wani@utu.ac.in

Novel setting and design of relay for protection of 3 phase induction motor using pscad

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Novel setting and design of relay for protection of 3 phase induction motor using pscad