CHAPTER-1

CENTRAL TESTING LAB (C.T.L.)

1.1) Introduction Central Testing Laboratory, Jodhpur Discom, Jodhpur is situated at the New

Power House at Shastri Nagar, Jodhpur. In this lab various power system equipment

are tested for providing better operation of power system like insulator , transformer ,

cables , conductor etc.

1.2) ConductorA conductor which is an object or type of material that allows the flow of

electrical current in one or more direction.

For example a wire is an electrical conductor that can carry electricity along its

length.

Example- Al, Cu.

1.2.1) Types of Conductor

1. ASCR Conductor (Aluminum Conductor Steel Rein forced)

These conductors are used for river crossing, overhead earth wire, and

installation extra-long span.

The advantage of ACSR is that it has high tensile strength and is light weight.

Fig.1.1 ACSR Conductor

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2. AAC Conductor (All Aluminum Conductor)

AAC Conductor is used mainly in urban areas where the spacing is short and

the supports are closer together.

The advantage of AAC Conductor is that they have a high degree of corrosion

resistance.

Fig 1.2 AAC Conductor

3. AAAC Conductor (All aluminum Alloy Conductor)

AAAC Conductor is used as bare overhead conductor for power transmission

and distribution lines on aerial circuit that require larger mechanical resistance than

AAC.

AAAC cables have lower weight per unit length and slightly lower resistance

per unit length than ACSR.

Types of ACSR Conductor

1. Zebra ACSR Conductor

2. Panther ACSR Conductor

3. Dog ACSR Conductor

4. Raccoon ACSR Conductor

5. Rabbit ACSR Conductor

6. Coyote ACSR Conductor

7. Moose ACSR Conductor

8. Weasel ACSR Conductor

In J.D.V.V.N.L. there are only four conductors are used these are –

Panther, Dog, Rabbit and Weasel Conductor.

1. Weasel Conductor

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Weasel Conductor has 6 wire of aluminum and one wire of steel, these types

of conductors are called Weasel Conductor.

Weasel Conductor has Current Carrying Capacity of 100amp and Tensile

Strength is 0.85KN. Weasel conductor have Lay Ratio is 10-14 and Resistance is

5.94Ω/km.

2. Dog Conductor

Dog Conductor has 6 wire of aluminum wire and 7 steel wire. Current

Carrying Capacity of Dog conductor is 254Amp. And Tensile Strength is 2.64kN for

aluminum and 2.57kN for steel wire.

Diameter of Dog conductor is 1.57mm for steel wire and 4.72mm aluminum

wire.

3. Panther Conductor

Panther Conductor which have 30 wire of aluminum and 7 wire of steel . It’s

Current Carrying Capacity is 427Amp.

Panther Conductor have Tensile Strength is 1.11kN for aluminum and 8.83kN

for steel and diameter of aluminum and steel are 3mm for both.

4. Rabbit Conductor

Rabbit conductors have 6 wire of aluminum and 1 wire of steel. It’s current

carrying capacity148Amp.

Rabbit conductors have Tensile Strength of 1.36KN for aluminum and 11KN

for steel. Diameter of aluminum conductor is 3.55mm.

1.2.2) Test Performed on Conductors1. Resistance Test

2. Tensile Strength Test

3. Lay Ratio Test

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4. Galvanization Test

1. Resistance Test

Resistance Test of conductor is measured by Kelvin Double Bridge Method.

In this method we take 1 meter wire of conductor.

Fig 1.3 Kelvin Double Bridge

2. Tensile Strength Test

Tensile Strength Test is measured by Tensile Machine.

In this machine we put a wire and measured tensile strength of conductor on

meter.

Fig 1.4 Tensile Test Machine

3. Lay Ratio Test

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Ratio of axial length of one complete turn of the helix form by core of cable

to standard mean diameter.

Lay Ratio Test is measured by taking a carbon print of ACSR conductor on

paper.

Lay Ratio=

axial lengthof one completeturn of thehelix formed by core of cablemean diameter of core

4. Galvanization Test

Galvanization test is used to test corrosion strength of the conductor wire in

environment of moisture. For this the conductor wire is dipped (immured) into

CuSO 4 Solution. For 1 minute interval. If the wire surface is not affected by CuSO 4

solution i.e. there is no reddish brown layer on wire then the Galvanization is perfect.

If Cu replace Zn the galvanization is not perfect. In this case there is a reddish

brown layer on wire due to corrosion after dipping the wire into CuSO 4solution.

1.3) Types of Insulation on Power Conductor1. XLPE Insulation

“Cross link Polyethylene is widely used as electrical insulation in power cables

of all voltage ranges but it is especially well suited to medium voltage applications”.

It is the most common polymeric insulation material. The acronym XLPE is

commonly used to denote polyethylene insulation.

2. PVC (Polyvinyl Chloride)

It is the most commonly used thermoplastic insulator for cables. It is cheap,

durable and widely available.

3. PE (Polyethylene)

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It is part of a class of polymers called polyolefin. Polyethylene has lower

dielectric losses than PVC and is sensitive to moisture under voltage stress (i.e. for

high voltage only).

1.4) COMPARISION OF INSULATING MATERIALS

MATERIAL ADVANTAGE DISADVANTAGE

PVC

1. Cheap

2. Durable

3. Widely available

4. Melting point is 600C

1. Highest dielectric losses.

2. Melts at high temp.

3. Contains halogens.

4. Not suitable for MV/HV cables.

PE

1. Lowest dielectric losses.

2. High initial dielectric

strength.

3. Melting point is 1300C

1. Highly sensitive to water treeing

2. Material breaks down at high temp.

XLPE

1. Low dielectric losses.

2. Does not melt but thermal

expansion occurs.

3. Melting point is >1300C

1. Medium sensitivity to water

treeing.

1.5) Underground Cable The underground cable employed for transmission of power at high voltage

consists of core or a number of tinned stranded copper or aluminum conductor

insulated from each other by paper varnished cambric or vulcanized bitumen or

impregnated paper.

A metallic sheath of lead or alloy or of aluminum is provided around the

insulation to protect it against ingress, gases, or other damaging.

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Fig 1.5 Underground Cable

1.5.1) Parts of Underground CableUnderground cables have following parts

Conductor or core

Shield

Insulation

Sheath

Filler

Bedding

Armoring

Serving

1. Conductor or Core

Conductor or Core is the main part of the underground cable. It is a

conducting material generally made up of copper, aluminum or ACSR depending on

many factor like voltage rating, power to be handled, distance between service and

load point.

2. Conductor shield

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Conductor shield is also a conducting material and its purpose is to protect the

conductor against crack or discontinuity.

3. Insulation

Each core is provided with individual insulation and the purpose of this

insulation is to separate the conductor from the other part or other conductor.

4. Insulation sheath

Sheath is a metallic layer provided over the insulation of the core or the

conductor.

5. Filler

Filler materials are used where two or more conductors are there in the cable.

The space between various sheath is covered or filled with the insulating material and

thus the name filler comes.

6. Bedding

Bedding is the insulation layer that the filler material and it holds all cores of

the cable.

7. Armouring

Armouring is a galvanized steel layer for providing mechanical strength to the

cable.

8. Serving

Serving is an insulating layer that protects the cable from corrosion and other

chemical reaction with soil. It prevents moisture being entered in the cable.

1.6) Requirement of Cables The conductor used in cables should be stranded one in order to provided

flexibility to cables and should be of such x-sectional areas that it may carry the

desired load current without overheating and causing excessive voltage drop.

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The insulation provide should be of thickness that it may give high degree of

safety and reliability at the working voltage for what it is designed.

The cable should be provided with a mechanical protection so that it may

withstand the rough usage in laying it.

Material used in manufactured of cables should be such as to give complete

and physical stability throughout.

1.7) Properties of Insulating Material1. High resistivity.

2. High dielectric strength.

3. Low thermal co-efficient.

4. Low water absorption.

5. Low permittivity.

6. Non – inflammable.

7. Chemical stability.

8. High mechanical strength.

9. High viscosity at impregnation temperature.

10. Capability to wish stand high rupturing voltage.

11. High tensile strength and plasticity.

1.8) Testing of Insulating Cable Thickness Test

Tensile Strength Test

Hot Set Test

1. Thickness Test

Thickness test is measured by vernier calipers. Thickness of insulation of

cable is approx 1.2mm.

2. Tensile Strength Test

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Tensile strength is measured by tensile machine .tensile strength of insulation

is greater than 12.5N/mm2 and elongation is >60mm.for XLPE insulation.

In this test sample of insulation cut in dumble shape by dumble cutting

machine. Then this specimen is placed b/w jaw of tensile strength machine. Then

stress is applied till the specimen break.

3. Hot Set Test

In this method the insulation of cable tested. In this method of insulation

testing a short piece of insulation of cable is keep in a temperature of about to 15 to 20

minutes. The temperature is about 100 to 200 degree centigrade. If the length of this

piece is increase more than 0.5mm then cables is not ideal for power system for

transmitting and distributing electrical power.

Fig 1.6 Hot Set Test Machine

Arial Bunched (AB) CableAreal bunched cable are overhead power lines using several insulated phase

conductor bundled tightly together usually with a bare neutral conductor. This

contrasts with the traditional practice of using uninsulated conductor separated by air

gap.

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Advantage of AB Cable

1. Relative immunity to short circuit caused by external force unless they abrade the

insulation.

2. Simpler installation as crossbars and insulator are not required.

3. Less cluttered appearance.

4. Can be installed in a narrower right of way.

5. Electricity theft is made harder and more obvious to detect

Disadvantage of AB Cables:

1. Additional cost for the cable itself.

2. Shorter span and more poles due to increased weight.

1.9) Power Transformer Transformer is a static electrical machine, which works on the principal of

electromagnetic induction. It transfers electrics power from one electric circuit with

the help of magnetic path (flux) on constant frequency but equal or different voltage

and current. For this purpose two set of insulated winding are wounded on a close

terminated silicon steel core. Winding which connected to the supply is called

primary winding and that winding which connected to the load is called secondary

winding.

Fig 1.7 Power Transformer

1.9.1) Main Parts of Power Transformer

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1. Core

It consist of laminated silicon steel in which quantity of silicon is up to 4%

thickness of lamination is 0.35 to 0.50mm. Normally the shape of the core is

rectangular and it has three legs.

2. Winding

Winding of power transformer is an important part. It consist of super

enameled copper wires, the size of wire (diameter) depends on the capacity of

transformer.

3. Tap – Changer

Tap changer is a switching device by which transformation ratio can be

changed the position of tap changing switch.

4. Tank

It is a metallic tank which is filled with insulating oil. The transformer core and

winding Assembly is surrounding by the oil in this tank. It protects the winding. And

core from the external mechanical damages. Rectangular tanks are simpler in

fabrication.

However for large rating power transformer, shaping of tanks becomes

necessary to confirm to transportable profile, shaping is provided by rounded corners

at the ends, truncations of low portion by wall from consideration of loading is well

wages girder and on the covers to reduce the height to minimize the tank oil, tank

profile may closely follow the electrical clearness along the coil. As is evident

shaping gives saving in tank material and oil but increases complexity and fabrication

cost.

Transformer tanks may have be classified as:

Plain tanks

Shaped tanks

Belt shaped tanks

Corrugated tanks

Stub end type tanks

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The transformer tanks are used in GSS. Power transformer is rectangular box

(plain tanks) type shape.

5. Thermal Bushing

It is used to isolate the leads, which is coming from the transformer.

6. Cooling System

In power system transformer, the oil serves a dual purpose, as an insulating

medium as well as a cooling medium. The heat generated in the transformer is

removed by the transformer oil surrounding the source and is transmitted either to

atmospheric air or water.

This transform of heat is essential to control the temperature with in

permissible limits for the class of insulation, thereby ensuring longer life due to less

thermal degradation.

7. Conservator and Air Cell

As the temperature of oil increases or decreases during operation, there is a

corresponding rise in volume. To account for this an expansion vessel (conservator) to

transformer tank.

The conservator has got a capacity between the minimum and maximum oil

level equal to 7.5 and of the oil in transformer.

The atom seal type conservator, it is filled with oil to level appropriate to the

filling temperature and in the remaining portion is air cell, which is connected to

atmosphere through a breather. As the breathing is through air cell, no moisture

comes in contact with oil, this protect the oil from deterioration or contamination.

A. An efficient barrier between oil and air.

B. A protection against water vapor.

C. The suppression of any gas bubbles formation in the Oil.

Air cell is made from coating with external coating resistance to transformer

oil and coating to ozone and weather.

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8. Buchholz Relay

Buchholz relay is a ‘Gas Actuated’ relay. The transformer is fitted with double

float buchholz relay. It is fitted in the feed pipe from conservator to tank. Any internal

fault in transformer is detected by buchholz relay; which give trip signal. Then the gas

liberated in the transformer is diverted by buchholz relay, without being trapped

anywhere.

9. Dehydrating Breather

The conservator is connected to outside through breather filled with

dehydrating material like silica crystal impregnated with cobalt chloride to make sure

that air in conservator is dry. The material is blue when dry and a whitish pink when

damp.

10. Pressure Relieve Valve

In case of server fault in the transformer, the internal pressure may build up to

a very light level which may result in an explosion of tank. To avoid such a

contingency a pressure relief valve is fitted on the transformer. It is spring loaded and

has contact for tripping the transformer.

11. Oil Temperature Indicator

Oil temperature indicator operates on the principle of liquid expansion. The

OTI provided with a maximum pointer and two mercury switches are adjustable to

make contact 500 and 1200 with the fixed differential of 100.

12. Winding Temperature Indicator

The indicator is fitted with four mercury switches 1st is used for alarm, 2nd is

for trip, 3rd is for fans on and 4th for pumps control. All switches are adjustable.

13. Earthing-

Connecting leads from core and end frame are being terminated at the top of

the cover by connecting them to tank cover, and end frame being earthed. For tank

earthing two number studs have been providing on tank.

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14. Thermal Bushing

It is used to isolate the leads that are coming from transformer. The size of the

bussing is justified according to the operating voltage of particular winding consist if

an Oil Impregnated Paper (O.I.P.) condenser core manufactured from superior grade

craft paper wound on aluminum tube. This bushing is voltage grated by suitably

interposed aluminum foils forming condenser layers.

15. Insulating Oil

The insulating oil has three functions;

Provides additional insulation

Protects the paper from dirt and moisture

Carries away the heat generated in the core and coils.

The insulating oil should have the following properties:

i. High dielectric strength.

ii. Free from inorganic acid, alkali and corrosive to prevent injury to the

conductor or insulation.

iii. Low viscosity to provide good heat transfer.

iv. Free from sludge under normal operating conditions.

v. Good resistance to emulsion so that the oil may throw away any moisture that

enters the apparatus.

1.10) Types of Cooling used in G.S.S. Power Transformer (a) ONAN Type Cooling

The generated heat can be dissipated in many ways. In case of smaller rating

of transformer, its tank may be able to dissipate the heat directly to the atmospheric

air whilst bigger rating may require additional dissipating surface in the form of

tubes / radiators connected to tank.

In these cases, the heat dissipation is from transform oil to atmospheric air by

natural means. This form of cooling is known as ONAN (Oil Natural, Air Natural)

type of cooling.

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(b) ONAF Type Cooling:-

For further augmenting the rate of dissipating of heat, other means such as

fans blowing air as the cooling surface are employed. The forced air tanks blows

always the heat at a faster rate, thereby giving better cooling rates than natural air.

This type of cooling is called ONAF (Oil Natural Air Forced) type of cooling.

In this cooling arrangement, additional rating under ONAN condition viz.

either after shutting, is available which is of the order of 70-75%

(c) OFAF Type Cooling:-

This method is used for transformer above 60MVA. In this method the oil is

cooled in external heat exchanger using air blast produced by fans.

1.11) Cooling ArrangementsDepending upon the type of cooling and rating of the transformer, the cooling

equipments can be arranged in various ways.

1.11.1) Arrangements with Radiator

Radiators are commonly used for ONAN type of cooling. Radiator consists of

elements joined to top to bottom headers. Elements in this are made by welding two

previously rolled and pressed thin steel sheets to form a number of channels of flutes

through which oil flows. These radiators can be both mounted directly on the

transformer tank or in the form of a bank and connected to the tank through pipes.

The surface are available for dissipation of heat is multiplied manifolds by using

various elements in parallel. As oil passes downwards either due to natural circulation

or force of a pump in the cooling circuit, heat is carried away by the surrounding

atmosphere air.

1.12) Testing of Transformer

Open Circuit Test

Measurements of NO LOAD LOSS & current:-

The iron losses and no load current are measured in this test. The H.V.

winding is charged at Rated voltage supply & L.V. winding is left open. The power

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consumed by the transformer at no load loss in the transformer. Effect of actual

frequency must be taken into account. Equipment used precision analyzer and variac.

Short Circuit Test

Measurement of LOAD LOSS & IMPEDENCE (EFFICIENCY &

REGULATION):-

This test measures the power by the transformer when the H.V. winding is

short circuited and the current is passed through the L.V. winding. Equipment used

precision power analyzer and variac.

1.13) InsulatorThe insulator serves two purposes. They support the conductor and confine the

current to the conductors. The most commonly used material for the manufacture of

insulator is porcelain. There are several types of insulators and there use in substation

will depend upon the service requirement. For example, post insulator is used for bus

bars. A post insulator consists of a porcelain body, cost iron cap and flanged cost iron

base. The hole in the cap is threaded so that bus bars are directly bolted to the cap.

1.13.1) Testing of Insulators

Tensile Strength test

Puncture test

Porosity test

1. Tensile Strength Test

Tensile strength test is performed by UTM (Universal Tensile Machine). UTM

is based on hydraulic based principle. it is used for T&C (Tongue & clevis) insulators.

In this test insulator is place between jaws of UTM. Then stress is applied on the

insulator. If the insulator is not breaking till the specific stress (in KN) then insulator

is perfect.

2. Puncture Test (HV test)

This test is used to find any puncture present in the insulator. It is carried out

by a transmission transformer whose input is 400V and output is 200KV. The

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insulator is immersed in oil tank then the HV is applied on the upper end of the

insulator and second end is earthed. If the insulator is perfect the there is no leakage

current till specific high voltage.

3. Porosity Test

This test is carried out to check whether the insulator is porous or not. In this

test a piece of a sample insulator is immersed in a specific solution. Then this

specimen is placed in a porosity machine at pressure of about 600KN/cm2 to

1200KN/cm2. After n hour the test specimen is taken out side of the machine and then

it is broken in two pieces. If the colour of the solution is present in the inner side of

the piece then the insulator is porous otherwise the insulator is perfect as there no

colour in the inner side.

Fig1.8 Porosity Test Machine 1.14) IsolatorsWhen carrying out inspection or repair in a substation installation, it is essential to

disconnect reliably the unit or the section, on which the work is to be done, from all

other live parts of the installation in order to ensure complete safety of the working

staff. To guard against mistakes it is desirable that an apparatus, which makes a

visible break in the circuit, should do this apparatus is the isolating switch. It may be

define as a device used to pen (or close) a circuit either when negligible current is

interrupted or when no significant change in the voltage across the terminal e.g. each

pole of the isolator will result from the operation P.A.

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CHAPTER – 2

METER TESTING LAB (M.T.L.)

2.1) IntroductionMeter Testing Laboratory, Jodhpur Discom, Jodhpur is situated at the New

Power House at Shastri Nagar, Jodhpur. In this lab various types of meters are

tested for providing better operation of distribution system like 3-phase meters, single

phase meters, instrument transformers (C.T. & P.T.) etc.

2.2) Instrument TransformerThe line in a section operated at high voltage and carry current of 1000Amp.

The measuring instrument and protective device are designed for low voltage

generally 110V and current about 5A. Therefore, they will not work satisfactorily if

mounted directly on the power lines. This difficulty is overcome by installing

transformer on the power lines. The function of these instrument transformers is to

transfer voltage or current in the power lines to values which are convenient for the

operation of measuring instrument and relays.

2.2.1) Current Transformer

Current transformer is an instrument transformer that is used protection and

metering of high values of current. Current transformer are used for reducing ac

current from higher value to lower value for measurement ,protection, control.

Burden on CT

Rated burden of CT’s and PT’s refers to the maximum load in volt amperes

(VA) which may be applied across secondary terminal.

Construction on CT

A CT has following essential parts-

a) Magnetic core-made up of continuous stirs of nickel iron alloy of CRGO

(Cold Rolled Grain Oriented) material.

b) Insulation over the core by tape.

c) Secondary winding having several turns would on the insulated core.

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d) Bar primary passing through the window of the core and terminals.

e) Support porcelain or epoxy insulator.

f) Synthetic resin or oil insulation.

Fig2.1 Current Transformer

2.2.2) Potential Transformer

These are also instrument transformers and used for measurement and

protection. According they are either single phase or three phase.

Potential transformers are necessary for voltage, directional and distance

protection. The primary of PT is connected directly to power circuit between phase

and ground. The volt-ampere rating of voltage transformer is a few VA to several

hundred KVA.

Types of PT’S

a) Electromagnetic potential transformer in which primary and secondary are

wound on magnetic core like a usual transformer.

b) Capacitor potential transformer, in which the primary voltage is applied to a

capacitor group. The voltage across one capacitor is taken to auxiliary voltage

transformer. The secondary of auxiliary transformer is taken for protection or

measure

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Fig2.2 Potential Transformer

2.3) MetersMeters are the instrument which are used for measurement purpose.

Energy meters are used for measurement of energy. The unit of energy is

KWH (kilo watt hour).

2.3.1) Types of Energy Meter

1. Single Phase Energy Meter

2. Three Phase Energy Meter

2.3.2) Testing of Energy Meter

1. Accuracy Test

2. Meter Counter Test

1. Accuracy Test

Accuracy test is used to check the accuracy of the meters. It checks whether

meter operates fast or slow. In this test energy meters are connected in series. The first

meter is connected to the supply and the last one is connected to load.

Now an optical reader is placed in the front the one meter the beam of the laser

is incident on optical LED of meter. And calibrate with it. The output of the reader is

connected to the output meter in which the error in % is shown.

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All the parameters like current voltage frequency power factor meter constant

is set in the output meter. F may be + or negative.

2. Meter Counter Test

This test is performed with the help of standard meter. The energy meters are

connected in series with standard meter. The supply is connected to standard meter

and the load (200 watt bulb) is connected to the last one meter. The load is connected

for 12 or 24 hour. At the end of the test if the reading of the testing meter are the same

as standard meter then the meters are ok otherwise it have counter problem which

may be solved.

Fig2.3 Three Phase Energy Meter

Fig 2.4 Single Phase Energy Meter

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CHAPTER – 3

H T M – II

3.1) IntroductionH T M II is a unit of JDVVNL. HTM II, is situated at the Shastri Nagar,

Jodhpur. In this Sub Station various types of equipments and devices are connected

for providing better operation of distribution system like 3-phase transformer,

Insulators, Bus Bars, Circuit Breaker, Relay, Isolator, instrument transformers (C.T.

& P.T.) etc.

3.2) Circuit BreakerA circuit breaker can make or break a circuit either manually or automatically

under all condition as no load, full load and short circuit condition.

A circuit breaker essentially consists of fixed and moving contacts. These

contacts can be opened manually or by remote control whenever desired. When a fault

occurs on any part of the system, the trip coils of breaker get energized and the

moving contacts are pulled apart by some mechanism, thus opening the circuit.

When contacts of a circuit breaker are separated, an arc is struck; the current is

thus able to continue. The production of arcs are not only delays the current

interruption, but is also generates the heat. Therefore, the main problem is to

distinguish the arc within the shortest possible time so that it may not reach a

dangerous value.

The general way of classification is on the basis of the medium used for arc

extinction.

3.2.1) Classification of Circuit Breaker

They can be classified into:

1. Oil circuit breaker

2. Air-blast circuit breaker

3. Sulphur hexafluoride circuit breaker (SF6)

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4. Vacuum circuit breakers

1. Oil Circuit Breaker

Fig. 3.1 Oil Circuit Breaker

A high-voltage circuit breaker in which the arc is drawn in oil to dissipate the

heat and extinguish the arc; the intense heat of the arc decomposes the oil, generating

a gas whose high pressure produces a flow of fresh fluid through the arc that furnishes

the necessary insulation to prevent a restrike of the arc.

The arc is then extinguished, both because of its elongation upon parting of

contacts and because of intensive cooling by the gases and oil vapor.

2. Air blast circuit breaker

Fast operations, suitability for repeated operation, auto reclosure, unit type

multi break constructions, simple assembly and modest maintenance are some of the

main features of air blast circuit breakers. A compressors plant necessary to maintain

high air pressure in the air receiver. The air blast circuit breakers are especially

suitable for railways and arc furnaces, where the breaker operates repeatedly. Air blast

circuit breakers are used for interconnected lines and important lines where rapid

operation is desired.

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Fig3.2 Air Blast Circuit Breaker

High pressure air at a pressure between 20 to 30 kg / cm2 stored in the air

reservoir. Air is taken from the compressed air system. Three hollow insulator

columns are mounted on the reservoir with valves at their basis. The double arc

extinguished chambers are mounted on the top of the hollow insulator chambers. The

current carrying parts connect the three arc extinction chambers to each other in series

and the pole to the neighboring equipment. Since there exists a very high voltage

between the conductor and the air reservoir, the entire arc extinction chambers

assembly is mounted on insulators.

3. SF6 Circuit Breaker

Fig3.3 SF6 Circuit Breaker

In such circuit breaker, sulphur hexafluoride (SF6) gas is used as the arc

quenching medium. The SF6 is an electronegative gas and has a strong tendency to

absorb free electrons. The SF6 circuit breakers have been found to a very effective for

high power and high voltage service. SF6 circuit breakers have been developed for

voltage 115 KV to 230 KV, power rating 10 MVA.

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It consists of fixed and moving contacts. It has chamber, contains SF6 gas.

When the contacts are opened, the mechanism permits a high pressure SF6 gas from

reservoir to flow towards the arc interruption chamber. The moving contact permits

the SF6 gas to let through these holes.

4. Vacuum Circuit Breaker

Fig3.4 Vaccum Circuit Breaker

Vacuum circuit breakers are circuit breakers which are used to protect medium

and high voltage circuits from dangerous electrical situations. Like other types of

circuit breakers, vacuum circuit breakers literally break the circuit so that energy

cannot continue flowing through it, thereby preventing fires, power surges, and other

problems which may emerge. These devices have been utilized since the 1920s, and

several companies have introduced refinements to make them even safer and more

effective.

3.3) RelayThe relays detect the fault and supply the information to the circuit breaker.

The electrical quantities which may change under fault condition are voltage,

frequency, current, phase angle. When a short circuit occurs at any point on the

transmission line the current flowing in the line increases to the enormous value. This

result in a heavy current flow through the relay coil, causing the relay to operate by

closing its contacts. This in turn closes the trip circuit of the breaker making the

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circuit breaker open and isolating the faulty section from the rest of the system. In this

way, the relay ensures the safety of the circuit equipment from the damage and

normal working of the healthy portion of the system. Basically relay work on the

following two main operating principles:

Electromagnetic attraction relay

Electromagnetic induction relay

3.3.1) Classification of Relay

1. Differential Relay

Fig3.5 Differential Relay

A differential relay is one that operates when vector difference of the two or

more electrical quantities exceeds a predetermined value. If this differential quantity

is equal or greater than the pickup value, the relay will operate and open the circuit

breaker to isolate the faulty section.

2. Over Current Relay

Fig3.6 Over Current Relay

This type of relay works when current in the circuit exceeds the predetermined

value. The actuating source is the current in the circuit supplied to the relay from a

current transformer. These relay are used on A.C. circuit only and can operate for

fault flow in the either direction. This relay operates when phase to phase fault occurs.

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3. Directional Relay

Fig3.7 Directional Relay

This relay operates during earth faults. If one phase touch the earth due to any

fault. A directional power relay is so designed that it obtains its operating torque by

the interaction of magnetic field derived from both voltage and current source of the

circuit it protects. The direction of torque depends upon the current relative to voltage.

4. Tripping Relay

Fig3.8 Tripping Relay

This type of relay is in the conjunction with main relay. When main relay sense

any fault in the system, it immediately operates the trip relay to disconnect the faulty

section from the section.

5. Auxiliary Relay

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Fig3.9 Auxiliary Relay

An auxiliary relay is used to indicate the fault by glowing bulb alert the employee.

3.4) Capacitor Bank

Fig3.10 Capacitor Bank

The load on the power system is varying being high during morning and

evening which increases the magnetization current. This result in the decreased power

factor. The low power factor is mainly due to the fact most of the power loads are

inductive and therefore take lagging currents. The low power factor is highly

undesirable as it causes increases in current, resulting in additional losses. So in order

to ensure most favorable conditions for a supply system from engineering and

economical stand point it is important to have power factor as close to unity as

possible. In order to improve the power factor come device taking leading power

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should be connected in parallel with the load. One of the such device can be

capacitor bank. The capacitor draws a leading current and partly or completely

neutralize the lagging reactive component of load current.

Capacitor bank accomplishes following operations Supply reactive power

Increases terminal voltage

Improve power factor

3.5) Bus BarWhen numbers of generators or feeders operating at the same voltage have to be

directly connected electrically, bus bar is used as the common electrical component.

Bus bars are made up of copper rods operate at constant voltage. The following are

the important bus bars arrangements used at substations:

Single bus bar system

Single bus bar system with section alisation.

Duplicate bus bar system

In large stations it is important that break downs and maintenance should

interfere as little as possible with continuity of supply to achieve this, duplicate bus

bar system is used. Such a system consists of two bus bars, a main bus bar and a spare

bus bar with the help of bus coupler, which consist of the circuit breaker and isolator.

In substations, it is often desired to disconnect a part of the system for general

maintenance and repairs. An isolating switch or isolator accomplishes this. Isolator

operates under no load condition. It does not have any specified current breaking

capacity or current making capacity. In some cases isolators are used to breaking

charging currents or transmission lines.

While opening a circuit, the circuit breaker is opened first then isolator while

closing a circuit the isolator is closed first, then circuit breakers. Isolators are

necessary on supply side of circuit breakers, in order to ensure isolation of the circuit

breaker from live parts for the purpose of maintenance.

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A transfer isolator is used to transfer main supply from main bus to transfer

bus by using bus coupler (combination of a circuit breaker with two isolators), if

repairing or maintenance of any section is required.

Fig3.11 Bus Coupler

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CHAPTER – 4

SCADA SYSTEM4.1) SCADA System

SCADA (supervisory control and data acquisition) is a system operating with

coded signals over communication channels so as to provide control of remote

equipment (using typically one communication channel per remote station). The

control system may be combined with a data acquisition system by adding the use of

coded signals over communication channels to acquire information about the status of

the remote equipment for display or for recording functions.

It is a type of industrial control system (ICS). Industrial control systems are

computer-based systems that monitor and control industrial processes that

exist in the physical world. SCADA systems historically distinguish

themselves from other ICS systems by being large-scale processes that can

include multiple sites, and large distances.

These processes include industrial, infrastructure, and facility-based processes,

as described below:

Industrial processes include those of manufacturing, production, power

generation, fabrication, and refining and may run in continuous, batch,

repetitive, or discrete modes.

Infrastructure processes may be public or private, and include water treatment

and distribution, wastewater.

Collection and treatment, oil and gas pipelines, electrical power

transmission and distribution, wind farms, civil

Defense siren systems, and large communication systems.

Facility processes occur both in public facilities and private ones, including

buildings, airports, ships, and space stations. They monitor and control

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heating, ventilation, and air conditioning systems (HVAC), access, and energy

consumption.

SCADA system usually consists of the following subsystems

Remote terminal units (RTUs) connect to sensors in the process and convert

sensor signals to digital data. They have telemetry hardware capable of

sending digital data to the supervisory system, as well as receiving digital

commands from the supervisory system. RTUs often have embedded control

capabilities such as ladder logic in order to accomplish Boolean logic

operations.

Programmable logic controllers (PLCs) connect to sensors in the process and

convert sensor signals to digital data. PLCs have more sophisticated embedded

control capabilities (typically one or more IEC 61131-3 programming

languages) than RTUs. PLCs do not have telemetry hardware, although this

functionality is typically installed alongside them. PLCs are sometimes used in

place of RTUs as field devices because they are more economical, versatile,

flexible, and configurable.

A telemetry system is typically used to connect PLCs and RTUs with control

centers, data warehouses, and the enterprise. Examples of wired telemetry

media used in SCADA systems include leased telephone lines and WAN

circuits. Examples of wireless telemetry media used in SCADA systems

include satellite (VSAT), licensed and unlicensed radio, cellular and

microwave.

A data acquisition server is a software service which uses industrial protocols

to connect software services, via telemetry, with field devices such as RTUs

and PLCs. It allows clients to access data from these field devices using

standard protocols.

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A human-machine interface or HMI is the apparatus or device which presents

processed data to a human operator, and through this, the human operator

monitors and interacts with the process. The HMI is a client that requests data

from a data acquisition server.

A Historian is a software service which accumulates time-stamped data,

boolean events, and boolean alarms in a database which can be queried or used

to populate graphic trends in the HMI. The historian is a client that requests

data from a data acquisition server.

A supervisory (computer) system, gathering (acquiring) data on the process

and sending commands (control) to the SCADA system.

Communication infrastructure connecting the supervisory system to the

remote terminal units.

Various processes and analytical instrumentation

4.2) Remote Terminal Unit

A remote terminal unit (RTU) is a microprocessor controlled electronic device

that interfaces objects in the physical world to a distributed control system or

SCADA(supervisory control and data acquisition) by transmitting telemetry data to a

master system and by using messages from the master supervisory system to control

connected objects.

Another terms may be used for RTU is remote terminal unit.

Architecture

An RTU monitor the field digital and analog parameters and transmits data to

the Central Monitoring Station. It contains setup software to connect data input

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streams to data output streams, define communication protocols and troubleshoot

installation problems.

An RTU may consists of one complex circuit card consisting of various

sections needed to a custom fitted functions or may consist of many circuit cards

including CPU or processing with communications interface one or more of

followings:

ANALOG INPUT (AI)

DIGITAL INPUT (DI)

DIGITAL OR CONTROL RELAY OUTPUT (DO/CO)

ANALOG OUTPUT CARDS (AO)

4.3) Applications of SCADA System

Remote monitoring of functions and instrumentation for:

Oil and gas (offshore platforms, onshore oil wells)

Networks of pump stations (wastewater collection, or for water supply)

Environmental monitoring systems (pollution, air quality, emissions

monitoring)

Mine sites

Air traffic equipment such as navigation aids (DVOR, DME, ILS and GP)

Remote monitoring and control of functions and instrumentation for:

Hydro-graphic (water supply, reservoirs, sewerage systems)

Electrical power transmission networks and associated equipments

Natural gas networks and associated equipments

Outdoor warning sirens.

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CHAPTER – 5

INFORMATION TECHNOLOGY (I. T.) WING

5.1) IntroductionI.T. wing, Jodhpur Discom, Jodhpur is situated at the New Power House at

Shastri Nagar, Jodhpur. In this section various computer and IT based systems are

operating for better maintenance of the distribution system. The main unit of IT wing

is DR (Disaster Recovery) Center.

5.2) DR (Disaster Recovery) CENTERDR center recovers the disasters present in distribution system. The main

functions of DR center are:

Reconstruction

Planning

The DR center provides security of data which are feed and stored online at Data

Center (DC) at Jaipur. It stores one copy of data which are sends to the DC.

5.3) Component of DR Center1. Server

2. UPS (Uninterruptible Power Supply)

3. PAC (Precision Air Conditioner)

4. VESDA (Very Early Smoke Detector Alarm)

5. Fire Integration System

6. WLD (water Leak Detector)

7. PDU (Power Distribution Unit)

8. MPCB (Moderate Power Circuit Breaker)

9. Fire Extinguisher

10. PTZ (Penetrate Zoom) Camera

11. Underground Cables

12. Rotating Replicate Alarm

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13. Fire Proof Tiles

14. 500KVA Generators

15. Networking Rack

16. DS (Data Storage ) Rack

17. Controller For DS

Server

Server is the main component of DR center. The functions of server are:

I. Storage of data

II. Rectify data

III. Feed data

IV. Required change in software

UPS (Uninterruptible Power Supply)

It provides required power to server. There are two 160KVA UPS. Battery is

charged by supply of 11 and 33KV supply.

PAC (Precision Air Conditioner)

These are used for humidity and temperature control of UPS and Server

Room. These are alternatively On and OFF. The compressor of PAC is IC based.

PDU (Power Distribution Unit)

The PDU distributes the power supplied by UPS among all servers.

VESDA (Very Early Smoke Detector Alarm)

VESDA is used for security purpose. It contains of VESDA tube which based

on the principle of capillary tube.

Data Storage

The DATA of servers is stored in 60TB DS Rack.

BMS (Building Management System) Room

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The BMS monitors all the PAC, Sensors, Servers, and UPS etc. of the DR

center.

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CONCLUSION

Now from this report we can conclude that electricity plays an important role

in our life. We are made aware of how the Distribution of electricity is done. Now we

have understanding about the various parts of the Sub Station System.

Now we know that how various type of equipments like Transformer,

Insulator, Conductor, Cables, Meters etc. are tested for better operation of

Distribution System.

The training at IT wing helps us to know about how a IT based system is

implemented in distribution system for Data Security.

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REFERENCES & BIBLIOGRAPHY

www.google.com

www.wikipedia.com

Jodhpur Vidhyut Vitran Nigam Ltd.

Ashwaq Hussain

P.S. Bhinbra

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