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INDEX
S.NO. TOPIC
1. INTRODUCTION
2. THE YARD
3. LIGHTINING ARRESTOR 4. WAVE TRAP 5. ISOLATOR 6. INSTRUMENT TRANSFORMER 7. POTENTIAL TRANSFORMER 8. CURRENT TRANSFORMER 9. POWER TRANSFORMER 10. INSULATOR 11. CIRCUIT BREAKER 12. EARTHING 13. POWER LINE CARRIER COMMUNICATION 14. PROTECTION RELAY 15. CONTROL ROOM 16.BATTERY ROOM
17. CONCLUSION
1
ACKNOWLEDGEMENT
This is my first practical training which has taken at 220 KV GSS, Sanganer.
I would like to express my sincere thanks to Ms. Tarannum Khan , Who
have given his excellent guidance and shared his experience with me using en-
tire course of this training report.
We are thanks to other staff member which are guided me. Finally I would
like to say this summer training has been a valuable part in my life.
At last but not least I am thankful to the all the staff member of
“YAGYAVALKYA INSTITUTE OF TECHNOLOGY”, department of Electri-
cal Engineering.
Pawan Kumar Gupta
B.TECH. IV YEAR (EE)
2
PREFACE
This is training of 30 days my training place was 220 KV ,GSS, San-
ganer, Jaipur (rajasthan). GSS is the mean of connection between generat-
ing station and consumer by providing safety and reliability of system in case of
default.
This sub station step down the incoming voltage power transmission to the
required valve and then is supplied to the consumer feeder or GSS done by
connecting auto transformer operation and requirement of various equipment
have been include in detail , further in case of report is the bus bar.
Arrangement of different feeder level and switch yards included informa-
tion of bus bar arrangement of different level isolator and growing substation
also power transformer circuit breaker oil, filtration plant, and compression pro-
tection control room and place are leveled.
3
CHAPTER-1
INTRODUCTION
When India becomes independent its overall installed capacity was hardly
1900 mw. During first year plan (1951-1956) this capacity was only 2300 mw.
The contribution of Rajasthan state was negligible during 1&2 year plans the
emphases was on industrialization for that end it was considered to make the
system of the country reliable. Therefore Rajasthan state electricity board came
into existence in July 1957.
In India electrical power is generated at a voltage of 11KV to 33 KV .
which is taken stepped up to the transmission level in the range of 66 KV to
400 KV
Member of transmission and switching have to be created. These are
known as “SUB STATION”.
Along these transmission lines secondary substation are created where volt-
age is further stepped down to sub transmission and primary distribution volt-
age.
A substation is an assembly of apparatus, which transform the characteristics
of electrical energy from one form to another say from one voltage level to an-
other level. Hence a substation is an intermediate link between the generating
station and consumer.
For economic transmission the voltage should be high so it is necessary to
step up the generated voltage for transmission and step down transmitted volt-
age for distribution. For this purpose substations are installed. The
4
normal voltages for transmission are 400kv, 220kv, 132kv and for distribution
33kv, 11kv etc.
Electricity boards are setup in all states of India which are responsible for
1. Generation
2. Transmission
3. Distribution
They also construct, install and maintain all the station made for these pur-
pose. In Rajasthan ,R.R.V.P.N.L. is responsible for transmission and distribu-
tion of electrical power all over Rajasthan. It has its own generating station and
it’s also gets power from various other stations also. It gets power from follow-
ing stations:-
1. Badarpur Thermal Power Station Delhi
2. Bhakara Nangl Project (at satlaj in Punjab)
3. Gandhi Sagar Dam Kota
4. Jawahar Dam Kota
5. Rana Pratap Sagar Dam Kota
6. Rajasthan Atomic Power Plant (RAPP) Kota
7. Kota Super Thermal Power Station (KSTPS) Kota
8. Anta Gas Power Plant Anta
9. Rajasthan share in Bhakara Beas Management Board (BBMB)
Power obtain from these stations is transmitted all over Rajasthan with the
help of grid stations. Depending on the purpose, substations may be classified
as:-
1. Step up substation
2. Primary grid substation
3. Secondary substation
4. Distribution substation
5. Bulky supply and industrial substation
6. Mining substation
5
7. Mobile substation
8. Cinematograph substation
Depending on constructional feature substation are classified as:-
1. Outdoor type
2. Indoor type
3. Basement or Underground type
4. Pole mounting open or kilos type
Any substation has many types of civil and electrical works. Main compo
nents are:-
Bus bar
Power transformers
Isolators
Circuit breaker
Lightening arrester
Insulators
Instrument transformers
The control room is equipped with protective relays, ammeters, voltmeters,
energy meters and frequency and power factor meters
D.C. supply is heart of GSS batteries are used for this purpose. They have
separate charging circuit also. For communication purpose P.L.C.C. is used
which has its various components.
220 KV GSS, Sanganer is the part of the transmission system.
6
INCOMING FEEDER:
400 KV Heerapura- Sanganer,
220 KV Kota –Sanganer
220 KV Heerapura-Sanganer
OUTGOING FEEDER:-
132 K.V.
1. Balawala
2. Heerapura
3. Mansrovar
4. SMS Stadium
5. Chaksu
6. Sitapura
33 K.V.
1. Durgapura I & II
2. Sanganer
3. Sitapura
4. Muhana Mandi
5. Malpura Gate
6. Vatika
7. Phagi
8. IOC
11 K.V.
1. Tajawal
2. muhana
3. Prem Nagar
4. Industrial
CHAPTER-2
7
THE YARD The yard is spread in very long area. The yard of 220 KV GSS at Sanganer
has various equipment installed at the yard of 220 KV GSS, Sanganer are:-
Lighting Arrester
Wave Trap
Current Transformer
Circuit Breaker
Bus Bars
Power Transformer
Insulator
Potential Transformer
Static earthling system
PLCC equipment including coupling capacitance
Bushing
Isolator
Figure-2.1 Switch Yard
BUS BAR SYSTEM
8
This bus bar arrangement is very useful for working purpose as every GSS.
It is a conductor to which a number of cut .Are connected in 220 KV GSS there
are two bus running parallel to the each other, one is main and another is auxil-
iary bus is only for stand by, in case of failure of one we can keep the supply
continues.
If more loads are coming at the GSS then we can disconnect any feeder
through circuit breaker which is connected to the bus bar. This remaining all the
feeders will be in running position .if we want to work with any human damage.
In this case all the feeders will be on conditions.
According to bus voltage the material is used .Al is used because of the
property & features and it is cheap.
With the help of bus bar arrangement we can connect all the incoming sup-
ply which is coming from different higher order GSS.
9
LIGHTEN - ING AR-
RESTER
Lightening arrester is first
equipment of GSS. It is pro-
tecting all the equipment
against the HV. The ground wire
or earthing does not provide pro-
tection against the high voltage
waves reaching the terminal
equipment .so some protective
device is neces- sary to produce
power station ,sub-sta-
tion and trans- mission lines
against the high voltage wave
reaching here. Which is connected between line and earth it acts as a safty
10
PROPERTIES
COPPER ALUMINIUM
1. Electricity resistively at 20 c
0.017241
0.00403
2. Temp coff. Of resistively
0.00411
0.00403
3. Softening tem.
200
180
4. Thermal conductivity
.932
.503
5. Meting point
1083
657
valve. .
Through the surge impedence of line limits the amplitude of the line to
earth over voltage to a value which wills safe guard the insulation of the pro-
tected equipment.
An ideal L.A should have following characteristics:-
1. It should not take any current under normal condition .i.e. its spark
over voltage must be higher then the system voltage.
2. Any abnormal transient voltage above the break down voltage must
caused it to break as quick as possible in order to provide an alternate path to
earth.
3. It must be able to carry the resultant discharge current without
causing damage to itself.
For high voltage system the thirties type L.A are used .The value type is
also known as non linear diverter .These arrester consist of a spark gape and a
non linear resistance. Both resistance and spark gape are accommodated in se-
ries with a completely light porcelain condition humidity etc.
SPARK GAPE:-
They include a number of identical elements connected in series .Each ele-
ment consist of with pre ionization device between each grounding resistance of
high ohmic value connected in parallel.
11
3.3 NON LINEAR RESISTER:-
The resister disc comprises inorganic material having a silicon carbide base
in a clay board. These discs form a block. The ohmic value of which decreases
rapidly when the applied voltage and current increases as soon as the current
wave resulting from the over voltage has been discharged. The resister block
subjected to the sole. Alternating Voltage and resistance assumes great
value .So that the amplitude of the resulting current becomes zero.
12
Figure-3.1 Lighting Arresters
WAVE TRAP
It is used to trap the communication signals & send PLCC room through
CVT.
Rejection filters are known as the line traps consisting of a parallel resonant
circuit ( L and C in parallel) tuned to the carrier frequency are connected in se-
ries at each and of the protected line such a circuit offer high impedance to the
flow of carrier frequency current thus preventing the dissipation. The carrier
current used for PLC Communication have to be prevented from entering the
power equipments such as attenuation or even complete loss of communication
signals. For this purpose wave trap or line trap are used between transmission
line and power station equipment to-
Avoid carrier power dissipation in the power plant reduce cross talks with
other PLC Circuits connected to the same power station.
Ensure proper operating conditions and signal levels at the PLC transmit re-
ceive equipment irrespective of switching conditions of the power circuit and
13
equipments in the stations.
Line Matching Filter & Protective Equipments
For matching the transmitter and receiver unit to coupling capacitor and power
line matching filters are provided. These flitters normally have air corral trans-
formers with capacitor assumed.
The matching transformer is insulated for 7-10 KV between the two windings
and perform two functions. Firstly, it isolates the communication equipment
from the power line. Secondly, it serves to match .
Figure-4.1 Line Matching Filter & Protective Equipments
Transmitter
The transmitter consists of an oscillator and a amplifier. The oscillator gener-
ates a frequency signal with in 50 to 500 HZ frequency bands the transmitter is
provided so that it modulates the carrier with protective signal. The modulation
14
process usually involves taking one half cycle of 50 HZ signal and using this to
create block to carrier.
Receivers
The receivers usually consist of and alternate matching transformer band
pass filter and amplifier detector.
The amplifier detector converts a small incoming signal in to a signal capa-
ble of operating a relatively intensive carrier receiver relay. The transmitter and
receiver at the two ends of protected each corresponds to local as far as trans-
mitting.
ISOLATOR :-
When carrying out inspection or maintains work in substation ,it is essential
to disconnect reliability the unit of other station on which the work is done from
all other parts on installation in order to ensure full safety of working staff .So
guard against mistake it is desirable that should be done by an apparatus is
called “ISOLATOR”. In other words a device which is used to open or close the
circuit either when negligible current is interrupted or when no significant
change in voltage across the terminal of each pole of the isolator will result
from operation .they must only be opened or closed when current is zero. There
is single ear thing Isolator used .
Isolator is switching device used to open (or close) a circuit either when a
negligible current exists or when no significant change in voltage across the ter-
minal of each pole of the isolator, will result from the operation.
15
Broadly speaking isolator are the switches which’s operate under "No cur-
rent” condition. Thus, isolator is an apparatus which makes a visible and reli-
able disconnection of the unit or the section after opening the circuit breaker.
Isolators are file with earthing blades as an integral part of it. They may be
isolators with single ear thing blades or two earthling blades on either side of it.
The isolators used at 220 KV GSS, Sanganer have single earthing blades either
side of it.They must only be opened or closed when current is zero. Isolators are
classified into following categories.
1. Bus isolator
2. Line isolator
3. Transformer isolating switch
From constructional point of view the isolator may be classified as-
1.The post- centre post rotating part, double post break type.
2.Two post single type.
3.Base: - Each pipe phase isolator is mounted on a robust base of steal construc-
tion.
16
Figure- 5.1 Isolator
MOUNTING: -
The central post rotates in gun metal bushing and tapered roller bearing pro-
vided with grease nipples for lubrication required to be alone at regular’s inter-
vals during routine check up.
17
EARTH SWITCH :-
(For line side insulation only ) Earthling is achieved by means of an earthed
blade pivoted at the base steady operation mechanism .the earth contacts are
fixed either at the back or left or right side of main contact and interlocked with
them by mechanism interlock.
OPERATING MECHANISM:-
1.Hand operated: - It consists of a fulcrums and level system for easy operation
of isolators.
2.The isolators used in G.S.S Sanganer at are three post types. Each isolator has
three insulators post per phase mounted on a phase of steal construction.
INSTRUMENT TRANSFORMER
The transformers which are used in A.C. system for the measurement of current,
voltage, power and energy are called Instrument transformer. These are also
used in connection with the measurement of power factor, frequency and for in-
dication of synchronism.They are two types namely:
18
1.Current transformer
2.Potential transformer.
Figure-7.1 POWER X-MER
(1) Core type
(2) Shell type
The x-mer used substation is auto-transformer which employed only single
winding per- phase. A part of winding is common to both of sides. In addition
to primary and secondary winding known as tertiary winding is also provided
19
the power transformer required at substations contain following additional part
–
1. HV winding bushing
2. LV winding bushing
3. Tertiary winding bushing
4. Jucking plate
Transformer used in conjunction with measuring are ‘INSTRUMENT
TRANSFORMER’. According to the quality measured. These may be di-
vided as
1. Current transformer
2 Potential transformer
20
These instrument transformers are used to step down these current and voltage.
So that they would be metered with instrument of moderate size.
CURRENT TRANSFORMER
The current transformers are kept in the category of the instrument trans-
former. The C.T. are used to reduce/ stepping down A.C form high value to
lower value for measurement / protection / control.
21
They are usually installed in the out door switch. The primary conductor at
high voltage with respect to earth. The secondary of C.T. is just like the ring
type C.T. the primary winding consists of a very few turns , and therefore there
is no. appreciation volt drop across injection . Current is transformed by C.T.
the current transformer is used with primary winding , connected in series with
the line carrying the current to be measured and therefore primary current is de-
pendent upon load connected in the system.
Measurement of alternating current is one of the most frequent operation not
only because of it’s inheriant but a also because it is necessary in determining
other parameters of electrical circuit. A current transformer value of current is
used for Indication of current kwh and kw meters Telementry Protective relay
etc
A current transformer is intended to operate normally with rated current of
the system flowing through the primary winding which is increased in the series
with the network .Secondary winding of current transformer Connected to mea-
suring instruments and relay supplies currents circulating in the design of cur-
rent transformer.
22
POTENTIAL TRNASFORMER
Similar to CT it is another type of instrument type of instrument
transformer .Transformer used for voltage measurements are called voltage
transformer or Potential transformer. it may be of 1 phase or 3
phase
These transformers make the instruments suitable for measurement of high
voltage and isolating then from high voltage. these transformer are connected in
parallel and secondary winding is always open ckt.
The primary winding of the potential transformer is connected to the main
GSS LINE DIAGRAM. the primary has large no of turn in secondary,which
provided step down of voltage , and then the voltmeter is connected across sec-
ondary terminal the high voltage line.
Some terms related to PT :-
A. RATED VOLTAGE :- the capacity voltage of the PT
which it can stand
B. RATED TRARNSFORMER RATIO:- The ratio of the rated
primary voltage to the rated second voltage.
C. RATED SECONDARY VOLTAGE:- 130 / root (3) = 63.3
VAR.
Voltage transformer which step down system voltage to sufficient form
high value to low value are necessary in every system for
Induction of d.c supply voltage conduction.
Metering of the supply of energy.
23
Relaying
Syncronizing.
Design and ranges are selected according to the secondary size of potential
transformer for indicating instruments, meter and relays. But calibration of these
instruments is done according to the primary voltage .
`
POWER TRANSFORMER
24
GENERAL:-
The transformers are used to step down or step-up the incoming line voltage
but at grid substation for the purpose of distribution. it is the main & major re-
quirement of GSS for step down the supply voltage .The rating of transformer is
taken according to the load .
There are two power transformers of 100 MVA . They are used convert 220
KV/132 KV. And two power transformers are used of 20/25 MVA .which con-
vert 132KV/33KV. Which transforms e/e energy from one voltage level to an-
other desired level with corresponding change in current value and with out any
change in frequency value.
The physical basis of a transformer is mutual induction between the circuits
linked by a common magnitude pulse voltage supplied to one set of winding
called primary switch builds up a magnitude flux through the iron.
A transformer in simplest form consist of two magnetic coil, which are
electrically separated from each other but magnetically linked through path of
reluctance .
In brief a transformer is a device that
1. Transform electric power from the one circuit to another.
2. It does not so without a change of frequency.
3. It accomplishes this by electromagnetic induction.
25
The magnetic core is built up of laminations of high –grade section or other
steel which are insulated from each to other by varnish or other insulation mate-
rials.
According to the number of winding placed around the core. The trans-
former are classified as
5. Earthing terminals the trank
6. Cooling systems
7. Pressure relief value
8. Bush hold relay
9. Dehydration breather
10. Rollers
11. Filters
26
Automatic control:-
The automation required use of automatic voltage control of substation so
that a predetermined bus- bar voltage can maintained. In general a tap changer
is provided on a transformer for a maintaining a pre determine outgoing voltage
where the incoming voltage may be subjected to voltage variations. The output
of P.T. connected to controlled voltage side of the power of transformer is used
to energize the automatic voltage regulating relays. The voltage to be controlled
remains with in prescribed limits.
GAS OPERATED RELAY:-
The relay is located in the pipe between the main tank and conservator. In
case of fault such as insulation was creating impulse failures fall of oil level
produces gases. This rises and accumulated in the upper part of the housing con-
sequently the oil level falls down and the float sinks thereby tilling the mercury
switch. The conducts are closed and alarm circuit is energized. Bachholz protec-
tion is always used in conjunction with some other forms of electricity operated
protective gears as it can unity operate for truly internal transformer faults and
does not respond to external bushings or cable faults.
SILICA GEL BREATHER:-
A silica gel breather is employed as a measurement of preveusing moisture
in gress. It is connected to the conservator tank which is filled to transformer to
allow for changes in volume due to temperature variation.
27
FILTER: - Filter is intended for prolonging like water acid etc from oil. .
TRANSFORMER OIL:-
In transformer, the insulating oil provides an insulating medium as well as a
heat transferring medium that carry away heat produced in the winding and iron
core.
The life of the transformer depends chiefly upon the quality of the insulat-
ing oil. So high quality insulating oil are used. It should meet the following re-
quirements:-
It should be provide good transfer of heat.
It should provide high electric strength.
It should have low velocity.
Flash point of the oil must be high.
Also fire point should be high.
28
INSULATORS
In order to avoid current leakage to the Earth, through the supporting struc-
ture provide to the conductor of overhead transmission lines, insulators are
used. The conductors are secured to the supporting structures by means of insu-
lating feature, which do not allow current to flow through these support and
hence finally to the earth . Bus support insulators are porcelain or fiberglass in-
sulators that serve to the bus bar switches and other support structures and to
prevent leakage current from flowing through the structure or to ground. These
insulators are similar in function to other insulator used in substations and trans-
mission poles and towers.
An Insulator should have following characteristic:-
1. High Insulation resistance.
2. High mechanical strength
3. No internal impurity or crack Disc
Generally Porcelain or glass is used as material for insulators. Porcelain be-
cause of its low cost. is more common.
Insulators can be classified in following ways :-
Pin Type: - These are designed to be mounted on a pin, which in turn is in-
stalled on the cross arm of a pole.
29
Figure-8.1 INSULATORS
Suspension Type:-These insulators hang from the cross arm, there by forming
a string.
The centre post carries the moving contact assembled at the extremities the
moving contact engages the fixed contacts are generally in the form of spring
loaded finger contact.
30
The insulator consist of following parts -
1. Contacts :- The contacts are rated for line current and designed to with-
stand electromagnetic strains and prevent charging at rated shortly time current
the contact are made of electrolytic fixed in housing.
2. Switching blade:- The blade is made of electrolytic copper.
3. Tandom pipe:-All three phases are opened or closed simultaneously with a
tandem pipe this is dipped galvanized and provided with on or off insulators and
pad locking.
4. Motor operated:-This is meant rotary motion of the linear operating pipe for
either of opening or closing for remote level local operation. Hand operation is
also provides with detectable handle that can be fitted and square.
31
CHAPTER-9
CIRCUIT BREAKERS:-
Breakers are switching and current interrupting devices. Basically a cir-
cuit breaker comprises a set of fixed and movable contacts. The contacts can be
separated by means of an operating an arc. The arc is extinguished by a suitable
medium such as dielectric oil vacuum, SF6 gas.
The circuit breakers play an important role in the design and performance
of a power system, in that these are the key pieces of apparatus protecting the
system and thus ensure continuity of supply from consideration of cost, the cir-
cuit breakers represent a major items, and are, next only to the generator and
transformer, since their quantity is greater than that of generators/transformer in
a power system owing to the services required for control of transmission lines,
bus-bar etc. in addition to control of transformers and generator.
Figure-9.1 CIRCUIT BREAKERS.
FUNCTION OF CIRCUIT BREAKER
The expected functions of a circuit breaker are: -
32
i. It must be capable of closing on to and carrying full load currents for long
period of time.
ii. Under proscribed condition, it must open automatically to disconnect the
load or some small overload.
iii. It must successfully and rapidly interrupt the heavy current, which flow
when a short circuit has to be cleared from the system.
iv. It must be capable of closing on to a circuit in which a fault exists and im-
mediately re-opening to clear the fault from system
v. It must be capable of carrying current of short circuit magnitude until,
and for such time as, the fault is cleared by another breaker nearer to the pint of
fault.
Circuit Breaker Types
i. Bulk oil Circuit Breakers
ii. Minimum oil Circuit Breakers.
iii. Air blast Circuit Breakers
iv. Sulphur hexafluoride (SF6) Circuit Breakers.
v. Vacuum Circuit Breakers
AIR BLAST CIRCUIT BREAKER
This type of breaker find application operating system from 132 kv and
these are meant for outdoor used and based on the multiple interception. Princi-
pal using compressed air as a medium for quenching the arc. The compressed
air acts as a medium of high dielectric strength which present flashover across
the writers in case of over voltage when the contacts are in open position. The
33
breaker can be opened or closed pneumatically from the control cabin or by pro-
tective relay or electrically fault occuring the operating pressure used at G.S.S
Sanganer is 12 kg/cm.
AIR BLAST C.B. HAS FOLLOWING ADVANTAGES:-
1. No fire hazards caused by oil.
2. The C.B operates at hogs speeds.
3. The duration of arc is possible.
4. Frequent operation of C.B’s is possible.
5. Almost no maintenance is needed.
6. Facility of high speed recoding.
TYPES OF AIR BLAST C.B’s:-
There are three types of air blast circuit breaker:-
1. Axial blast C.B.
2. Axial blast air C.B. and with side moving contact.
3. Cross blast air circuit breaker.
OPERATION:-
In the closed position of air blast circuit breaker. There is no com-
pressed air in arc chamber hallow calcium insulator. When fault occurs on the
line CB operates and compressed air quenches the arc into no of section.
34
VACUUM CIRCUIT BREAKER
FUNCTION OF SF6 GAS IN SF6 CIRCUIT BREAKERS
The density of SF6 Gas is about five times that of air and heat dissipation in it
is also much more than in air.
Air atmospheric pressure dielectric strength of SF6 gas is about 2.4 times
that of air and at about 3-Kg/cm2 it is same as that of oil. Table no. D1 gives
physical properties of SF6 gas.
There is some decomposition of the gas long periods of arcing. However
such decompositions very little and has no effect upon dielectric strength and
interrupting capability. The solid are product formed by arcing metallic fluoride,
which appears in the form of fine gray powder. This are generated power has
high dielectric strength under dry conditions existing in the breaker. A good
quality absorbent is used so that the level of the gaseous by products is kept
very low. Certain impurities such as air result in the dilution of SF6 gas in the
field as long as the process recommended is followed. While releasing the arced
gas into atmosphere, international sniffing of gas should be avoided. The rela-
tion between SF6 gas pressure and temperature is given in fig. 4.13, which is a
very useful date at the tie filling of SF6 in circuit breaker.
35
Figure-9.2 SF6 CIRCUIT BREAKERS
36
CHAPTER -10
EARTHING
Earthing is the provision of a surface under the sub station, which has a
uniform potential as nearly as zero or equal to Absolute Earth potential. The
provision of an earthing system for an electric system is necessary by the fol-
lowing reason.
1. In the event of over voltage on the system due to lighting discharge or other
system fault. These parts of equipment which are normally dead as for as volt-
age, are concerned do not attain dangerously high potential.
2. In a three phase, circuit the neutral of the system is earthed in order to stabi-
lize the potential of circuit with respect to earth.
The resistance of earthing system is depending on shape and material of
earth electrode used.
The earthing is of two principal types :-
Neutral Earthing
Equipment Body Earthing
37
Neutral Earthing:-
Neutral Earthing also known as System Neutral Earthing (or Grounding)
means connecting the neutral point i.e. the star point of generator,transformer
etc. to earth. In rotating machines, generator, transformer circuit etc., the neutral
point is always connected to earth either directly or through a reactance. The
neutral point is usually available at every voltage level from generator or trans-
former neutral. If neutral point is not available, then the most common method
used is using a Zigzag transformer. Such a transformer has no secondary. Each
phase of primary has two equal parts. There are 3 limbs and each limb has two
winding, providing flux density under normal condition. Since the fluxes are
opposite, the transformer takes very small magnetizing current under normal
conditions. During fault, the circuit is primary side,
which provides very less impedance to the current. The grounding trans-
formers are short time rating. Their size is almost one tenth as compared to
power transformer.
38
Electrical Earthing:-
Electrical Earthing is different from neutral earthing. During fault condi-
tion, the metallic parts of an electrical installation which do not carry current
under normal conditions, may attain high potential with respect to ground. As
human body can tolerate only I=0.165A/T current for a given time t so to ensure
safety we connect such metallic parts to earth by means of Earthing
system ,which comprises of electrical conductor to send fault current to earth.
The conductor used is generally in the form of rods, plates, pipes etc.
Earthing system ensures safety in following ways :-
1. The potential of earthen body does not reach dangerously high value
about earth, since it is connected to earth.
2. Earth fault current flows through earthing and readily causes the opera-
tion of fuse or an earth relay.
39
Connection of Electrical Equipment to Substation:-
S.NO. Apparatus Path to be connected
1. Supporting of bus insu-
lator
Base plate
2. High voltage circuit
breaker
Operating mechanism
frame
3. Isolator Operating mechanism
frame bed
4. Potential transformer Transformer tank LV
5. Power transformer Core tank
Merits of neutral Earthing:-
1. Arcing grounding is reduced.
2. Voltage of heating with respect to earth remains at harmless value they don't
increase to root 3 times of normal value.
3. Suitable neutral point.
4. The earth fault relaying is relatively simple useful amount of earth fault cur-
rent is available to operate earth fault relay.
5. The over voltage due to lightening are discharged to earth.
6. Improved service reliability due to limitation of arcing ground and improved
of unnecessary fringing of CB.
At GSS the neutral point of power transformer is connected solidly to earth gen-
erally the earth connection are provided which leads reliability.
40
CHAPTER-11
Power Line Carrier Communication :-
Introduction
Power Line Carrier Communication (PLCC) provides for signal transmis-
sion down transmission line conductors or insulated ground wires. Protection
signaling, speech and data transmission for system operation and control, man-
agement information systems etc. are the main needs which are met by PLCC.
PLCC is the most economical and reliable method of communication be-
cause of the higher mechanical strength and insulation level of high voltage
power line which contribute to the increased reliability of communication and
lower attenuation over the larger distances involves.
High frequency signals in the range of 50 KHZ to 400 KHZ commonly
known as the carrier signal and to result it with the protected section of line suit-
able coupling apparatus and line traps are employed at both ends of the pro-
tected section. Here in Sanganer and also in other sub-station this system is
used. The main application of power line carrier has been from the purpose of
supervisory control telephone communication, telemetering and relaying.
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PLCC Equipment
The essential units of power line carrier equipment consists of :-
a. Wave trap
b. Coupling Capacitor
c. LMU and protective equipments.
MERITS AND DEMRITS OF PLCC
Merits
The severity that a power line can withstand is much more than that odd com-
munication line due to higher mechanical strength of transmission line power
lines generally provide the shortest route between the Power Station and the Re-
ceiving Stations.
The carrier signals suffer less attenuation, owing to large cross sectional area of
power line
Larger spacing between conductors reduces the capacitances which results in
lesser attenuation of higher frequencies.
Large spacing also reduces the cross talk to a certain extent.
The construction of a separate communication line is avoided.
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Demerits
Utmost care is required to safeguard the carrier equipment and persons using
them against high voltage and currents on the line.
Noise introduced by power line is far more than in the case of communication
line. This is due to the discharge across insulators and corona etc.
Induced voltage surges in the power line may affect the connected carrier equip-
ment.
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CHAPTER-12
PROTECTIVE RELAY
The purpose of protective relay and protective system is to operate the
correct CB‘s as to disconnect only the faulty equipment from the system as
quickly as possible. Thus minimizes the trouble caused by fault by they do oc-
cur. The protective relay does not operate possibility of the fault on the system.
Their active starts only after the faults have occurred. It could be idea led if the
protection could anticipate and peasant faults because it is impossible to except
where original case of fault create some effects which can operate a protective
relay. These are two groups of protective relay.
1. Primary relaying equipments.
2. Back-up relaying equipments.
Primary relaying is the first line of difference whereas back up protection
relaying works. Only when the primary relaying equipments fails and also back
up relays are slow in motion condition. Another job of back relay is to act as
primary relay in case of where this is out work.
Relay must operate when it is required. Since relay remains ideal. Most of
the time proper maintenance also plays important role in improving reliability.
Relay should select fault region and isolate that section from circuit. It should
also operate required speed. It should neither be slow which may not result in
damage to the equipment nor it should too fast which may result undesired op-
eration during transient faults and should be sensitive to faults.
OPERATION:-
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The protective relay serves for preventing tap changers and transformer
from being damage which is the part of delivering the protective relay as to be
connected in away that transformer immediately switched off captions oil im-
mersed transformer. Transformer break down are always precede by more or
less violent generation of gas. A broking joints produce local arc and vaporize
in the vicinity. As earth faults has the some results sudden short circuit rapidly
increased the temperature of the winding particularly the inner layer and packed
oil in vaporize. Discharge due to insulation weaken i.e. by the dehydration of
the oil produce local heating and generate gas. The generation of oil vapour or
gas in utilize to actuate a relay the relay is arranged between the transformer
tank and the separate oil conservator. The vessel is normally is full of oil. It
contains two floats if the gas bubbles are generated in transformer due to faults.
They will be rise and transfers the conservator and will trap in the upper part of
the relay chamber. Thereby displacing the oil and lowering the faults. This sinks
and eventually closes and external contacts which operates an alarm over other
protection and flashover at the bushing are not at adequately covered by other
protective scheme also unless it improves ground.
The differential scheme detects such faults and also on the leads between
CTs are power transformer provided ct’s are not mounted separately on trans-
former bushing. In service internal faults operate when the relay is energizes.
The protective relay reenergized only by oil flow from the tap changer heat to
the conservator. The oil flow operates the flap value which is trapped into the
“off” position by timing mechanism. Thus the trapping switch is energized the
CB’s are operated the transformer off the line.
45
CHAPTER-13
CONTROL ROOM
To remote control of power switch gear requires the provision of suitable
control plates located at a suitable point remote from immediate vicinity of
CB’s and other equipments.
At "GSS SANGANER" the separate control room provided for remote pro-
tection of 220KV switch yards transformer incoming feeder, outing feeders. Bus
bar has their own control plant in their control rooms. The control panel carrier
the appropriate relays. Necessary meters indicating lamp control switches and
fuses. There are meters for reading purpose. A circuit concerning the panel is
shown on the panel with standard co lour.
On each panel a control switch is provided for remote operation of circuit
breaker. There are two indicators which show that weather circuit breaker is
closed or open. A control switch for each insulator is also provided. The posi-
tion indicator of isolator is also done with the help of single lamp and indicator.
The colour of signal lamps are as follows :-
RED:- For circuit breaker or isolator is close option
GREEN:-For CB or isolator in open position.
In addition to used indication an alarm is also providing for indicating ab-
normal condition when any protective relay or tripping relay has operated. Its
constants energies on auxiliary alarm. Relay which on operation completes the
alarm belt circuit.
46
Synchronizing:-
There is a hinged Synchronizing panel mounted at the end of control panel.
Before coupling any incoming feeders to the bus bar. It just be Synchronized
with switches. When the synchronous copy shows zero we close the circuit
breaker.
Synchronoscope:-
Synchronoscope is used to determine the correct instant of closing the
switch which connect the new supply to bus bar. The correct instant of syn-
chronizing when bus bar incoming voltage.
a. Are in phase
b. Are equal in magnitude
c. Are in some phase sequence
d. Having same frequency
e. The voltage can be checked by voltmeter the function of syn-
chronoscope is to indicate the difference in phase and frequency.
Energy Meter:-
These are fitted on different panel to record transmitted energy and recorded
in energy hours. For this purpose MWH meter have been provided.
Watt Meter:-
This is mounted on each feeder panel to record import or export power.
Frequency Power:-
47
Provided to each feeder to measure frequency which analog or digital.
Volt Meter :-
Provided on each panel or the purpose of indication of voltage.
Ammeter:-
These are used to indication the line current.
MVAR Meter:-
Provided for indicating power factor of import and export.
Maximum Indicator Demand :-
Chief requirement of these indicators to record the minimum power factor
taken by feeder during a particular period. This record the average power suc-
cessive predetermined period.
48
CHAPTER-14
BATTERY ROOM
There is a battery sexton or battery room which has 55 batteries of 2 volt
each for 132KV section and 110 batteries for 220KV section. Therefore D.C.
power available is for functioning of the control panels. A battery charger to
charge the battery.
Various parts of lead acid batteries:-
o Plates
o Separators
o Electrolyte
o Container
o Terminal port
o Vent plugs
Charging of batteries:-
Initial charging-:
It is the first charging given to batteries by which the positive plates are
converted to “lead peroxide”, where as the –ve plates will converted to spongy
lead.
Also in a fully charged battery the electrolyte specific gravity will be at its
highest venue or 1.2 and its terminal voltage will be 24 volts
49
Discharging:-
When a fully charged battery delivers its energy out by meeting a load the
lead peroxide of the +ve plates slowly gets converted to lead sulphate and the
spongy lead of the –ve plates also gets converted into lead sulphate during this
time the specific gravity of the electrolyte also decreases the value around 1.00
and the terminal voltage also decreases from its initial to a lower value which
may be around 1.85 or 1.8.
50
CHAPTER-15
CONCLUSION
The training at grid substation was very helpful. It has improved my theo-
retical concepts of electrical power transmission and distribution. Protection of
various apparatus was a great thing. Maintenance of transformer, circuit
breaker, isolator, insulator, bus bar etc was observable.
I had a chance to see the remote control of the equipments from control
room itself, which was very interesting.
So the training was more than hope to me and helped me to understand
about power system more.
51
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