1.1 1.1 Definition:Definition:Transformers :transfer electrical energy at system voltage to electrical Transformers :transfer electrical energy at system voltage to electrical energy at the required voltage or higher voltage.energy at the required voltage or higher voltage.

- Current transformers Current transformers - Voltage transformersVoltage transformers

- Oil – immersed transformers Oil – immersed transformers

- Askarel immersed transformers Askarel immersed transformers - Dry type transformersDry type transformers

•Instrument transformer Instrument transformer •Distribution transformers:-Distribution transformers:-

1.2 Types of transformers1.2 Types of transformers

1.2.1 1.2.1 Oil immersed transformers :Oil immersed transformers :Oil immersed transformers have their cores & windings Oil immersed transformers have their cores & windings

immersed in mineral oil.immersed in mineral oil.

1.2.21.2.2 Askarel immersed transformers Askarel immersed transformersAskarel Oil immersed transformers have their cores and winding Askarel Oil immersed transformers have their cores and winding immersed in the synthetic cooling & insulating fluid Askeral immersed in the synthetic cooling & insulating fluid Askeral normally .normally .These transformers refferred to under the trade name of the fluid , These transformers refferred to under the trade name of the fluid , e.g “ colophon – immersed transformers “ or “ Pyroclor/Aroclor e.g “ colophon – immersed transformers “ or “ Pyroclor/Aroclor immersed transformers”immersed transformers”Askeral is a colourless , flame – resistant & explsion proof fluid , it Askeral is a colourless , flame – resistant & explsion proof fluid , it is made of chlorinated aromatic hydrocarbons . this density is is made of chlorinated aromatic hydrocarbons . this density is approx. 1.569 cm at 15.5 C° ambient temperature .approx. 1.569 cm at 15.5 C° ambient temperature .The electrical properties are a good as these of mineral oil The electrical properties are a good as these of mineral oil (transformer oil ) but Askarel – immersed transformers can be (transformer oil ) but Askarel – immersed transformers can be installed without special measures of fire protection .installed without special measures of fire protection .For chemichal reasons , mineral transformer oil & Askaral must For chemichal reasons , mineral transformer oil & Askaral must not be mixed .not be mixed .An oil immersed transformer cannot therefore be refilled with An oil immersed transformer cannot therefore be refilled with Askaral or an Askaral immersed transformer be refilled with oil .Askaral or an Askaral immersed transformer be refilled with oil .

1.2.31.2.3 Dry type transformers: Dry type transformers:Dry type transformers have no insulating & cooling fluid they are designed Dry type transformers have no insulating & cooling fluid they are designed according to the type of insulation of the windings into varnish – insulated & according to the type of insulation of the windings into varnish – insulated & silicon insulated dry type transformers.silicon insulated dry type transformers.

Self Cooling :Self Cooling :Distribution transformers are mainly manufactured with self cooling , with Distribution transformers are mainly manufactured with self cooling , with this kind of cooling the heat generated is dissipated by the natural air flow this kind of cooling the heat generated is dissipated by the natural air flow and by radiation .and by radiation .With forced air cooling the cooling air is circulated by fans . subsequent With forced air cooling the cooling air is circulated by fans . subsequent addition of fans to the transformer is only possible after consulting the addition of fans to the transformer is only possible after consulting the manufacturer . manufacturer . The limits of temperature rise permitted for various insulating materials are The limits of temperature rise permitted for various insulating materials are specified in ( VDE-0532 ) and these are based on the following limits of specified in ( VDE-0532 ) and these are based on the following limits of cooling air temperature : -cooling air temperature : -

Maximum temperature of air 40h C .Maximum temperature of air 40h C . Daily mean temperature of the air 30h C .Daily mean temperature of the air 30h C . Yearly mean temperature of the air 20h CYearly mean temperature of the air 20h C . .

The temperature of the ambient air is measured at a distance of 1-2 m The temperature of the ambient air is measured at a distance of 1-2 m from the transformer .from the transformer .

1.2.41.2.4 Instrument transformers : Instrument transformers :- Current transformers- Current transformers- Voltage transformers- Voltage transformers

•Current transformers: Current transformers: Current transformer is transformer with small rate power (burden) , Current transformer is transformer with small rate power (burden) , whose primary windings are in series with the line circuit , and whose primary windings are in series with the line circuit , and secondary windings are connected to measuring instruments , secondary windings are connected to measuring instruments , electricity meters relays or control devices , current transformers electricity meters relays or control devices , current transformers isolate the measuring of protection circuits from the primary voltage isolate the measuring of protection circuits from the primary voltage and also protect the apparatus corresponding to the over current and also protect the apparatus corresponding to the over current response of the current .response of the current .

1.2.51.2.5 Voltage transformers : Voltage transformers : Voltage transformers are also of small power rate and operate at Voltage transformers are also of small power rate and operate at almost no – load . they isolate the primary high voltage from the almost no – load . they isolate the primary high voltage from the connected measuring or protected circuits.connected measuring or protected circuits.

TRANSFORMERSTRANSFORMERSDefinition :Definition : Transformers can be defined as a static electric machine which converts Transformers can be defined as a static electric machine which converts electric energy from one potential to another at the same frequency .electric energy from one potential to another at the same frequency .

It can also be defined as consists of two electric circuits linked by a It can also be defined as consists of two electric circuits linked by a common variable flux.common variable flux.

Theory of operation :Theory of operation :

The primary coil of the transformer is connected to a supply of sine The primary coil of the transformer is connected to a supply of sine wave voltage . an alternating sine wave current will flow in the wave voltage . an alternating sine wave current will flow in the primary . thus the primary m.m.f ( N.I ) will produce a common primary . thus the primary m.m.f ( N.I ) will produce a common

flux ( g ) which is also alternating and in phase with the current flux ( g ) which is also alternating and in phase with the current according to Faradayaccording to Faraday′′ s law the common flux interesting two coils s law the common flux interesting two coils will induce in them an alternating e.m.f ( e1 , e2 ) .will induce in them an alternating e.m.f ( e1 , e2 ) .

e1e1 is an e.m.f of self induction is an e.m.f of self induction e2e2 is an e.m.f of Mutual inductionis an e.m.f of Mutual induction

from 1,2 from 1,2 ∴∴ the transformation ratio the transformation ratio

( )1 dt

dN - e 1

1

φ=

( )2 dt

d N- e 21

φ=

2

1

2

1

N

N

e

e K ==

Applying Kirchoff′ s law on the primary circuit.V = - e1 V+ e1 = 0

From the secondary circuit e2 = v2

Equivalent circuit :

V.D ∑=∑e.m.f

2

1

2

1

2

1

V

V

N

N

e

e ===K

Io = 10 : 15 % of rated current .

111111 1 XIJ rI V ++−= E

22222 2 XIJ rI V ′′+′′+′−=′ E

Tansformer testing :Tansformer testing :

Determination of parameters :Determination of parameters :

Connect the primary to a source of alternating current at nomial voltage the Connect the primary to a source of alternating current at nomial voltage the secondary is open circuit – read the magnitude of ( Io , V1 , Po ) at no load .secondary is open circuit – read the magnitude of ( Io , V1 , Po ) at no load .

The impeadence of the circuit at no load .The impeadence of the circuit at no load .

01

o

1 Z Z I

V +=

I

V Z

o

10 ≅

Z Z o1 <<

Z Z o1 < <

Z1 can be neglected Z1 can be neglected

( ) I

p r 2

o

oo =

2

oo2

o Xr Z +=

2

o

2

oo r Z X −=

-Another method:Another method:

Io1

o V

Po cos ≅φ

Po = V1 Io is Po = V1 Io is ggo o

0

1o I

V Z ≅

Io1

1-

o V

Po cos =φ

oo os Z Ro φc=

ooo sin Z x φ=

For parallel circuit rm & JXm : Neglect Zm relation to Z1

ooo cos I I φ=a

ooo sin I rI φ=

V

Pcos

1

o1-

o

=φ

ma Io

V1

2r = Ior

V X 1

m =

-Short circuit test:Short circuit test:

Connect the primary to a reduced voltage ( from 15 – 20 % of V1 ) until the Connect the primary to a reduced voltage ( from 15 – 20 % of V1 ) until the primary current becomes near to the value of the full load current of the primary current becomes near to the value of the full load current of the primary .primary .

Short circuit the secondary winding .Short circuit the secondary winding .

Measure ; ( V1 ) sh.c ( I1 ) sh.c ( P1 ) sh.c Measure ; ( V1 ) sh.c ( I1 ) sh.c ( P1 ) sh.c

In the circuit ZIn the circuit Z′′ 2 2 , Z, Z′′ o are connected in parallel o are connected in parallel

Zo is of the order of ( 10 )Zo is of the order of ( 10 )-2-2 relative to Zrelative to Z′′ 22

eqZ sh.cI

sh.cV

1

1 =

So the effect of Zo can be simplified to the show So the effect of Zo can be simplified to the show figure ( c ) . figure ( c ) .

Where ; Where ; Zeq = Req + Jxeq Zeq = Req + Jxeq

Req = r1 + r2Req = r1 + r2′′ xxeqeq = x = x

11 + x + x′′ 22

( ) 1 sh.c ) cos ( )sh.c I ( )sh.c V1 ( sh.c P1 φ=

V

P

P 1-cos sh.c

.I11

1

1

csh

=φ

φsin eqZ eqx =

cos Z R eqeq φ=

2

22 K

rr

′=

2

X X X

eq

21′≅

21 r r ′≅

2

22 k

x x

′=

•D.C Test :D.C Test :

Connect the primary coil with a direct current supply . measure Connect the primary coil with a direct current supply . measure the applied voltage and the current . the applied voltage and the current .

ohmsr 1=I

E

The effect of X1 , XThe effect of X1 , X00 will not appear when using direct current will not appear when using direct current

→dt

Ldi X

I is the const. relative to timeI is the const. relative to time[ [ also the effect of ro will not appear also the effect of ro will not appear because it represent the eddy and hysteresis losses which are not existing because it represent the eddy and hysteresis losses which are not existing in the case of direct current they appear only when there is varialable flux in the case of direct current they appear only when there is varialable flux in the core . in the core . Similarly we can determine the resistance of the secondary ( r2 ) by Similarly we can determine the resistance of the secondary ( r2 ) by connecting the battery to the terminals of the secondary coil . connecting the battery to the terminals of the secondary coil .

Voltage regulation : Voltage regulation :

The voltage regulation is defined as the change in the secondary The voltage regulation is defined as the change in the secondary voltage of a loaded transformer when the load is removed . while the voltage of a loaded transformer when the load is removed . while the primary voltage is constant at itprimary voltage is constant at it′′ s nominal value .s nominal value .E = ( VE = ( V

22 ) ) n.ln.l – V – V

2 2 load load

In order to enable the comparison between transformers of different In order to enable the comparison between transformers of different working voltages , the voltage regulation in usually expected as percent working voltages , the voltage regulation in usually expected as percent or a per unit value related to the secondary voltage at load . or a per unit value related to the secondary voltage at load . usually the voltage regulations is determined for full load conditions . so usually the voltage regulations is determined for full load conditions . so to simplify equivalent circuit to simplify equivalent circuit

( )( ) % 100

2V

2V - .2V V.Rε =×=

L

LLn

( )( ) unit per

2V

2V - .2V V.Rε ==

L

LLn

calculation the effect of I0 is neglected and we get the following simplified calculation the effect of I0 is neglected and we get the following simplified equivalent circuit and the corresponding to it vector diagram ( Kapp vector equivalent circuit and the corresponding to it vector diagram ( Kapp vector diagram ) diagram )

•Io neglected :

eq1 Req21 X IJ I1 V V ++′=

eq1 eq112 X IJ RI V V ++=′

II1= 1= II ′′ 22

ZZq q = Req + JX= Req + JXeqeq = ( r = ( r

1 + 1 + rr′′ 2 2 ) + J( X) + J( X11 + X + X′′ 22 ) )

To calculate the voltage regulation the following value must be To calculate the voltage regulation the following value must be determined .determined .VV11,I,I11 cos cos gg11 and Z and Zeqeq . .

( ) ( ) ReqI cosV V Xeq I1112

1112 - sin V φφ +−=

l

lln

)(V

)(V .)V (

2

22 −=ε

Note: Note: ( V( V′′ 22 ) )n.ln.l = V = V

11

l

lln

)(KV

)(KV .)V(K

2

22 −=ε

2

21

2

22

V

VV

)V(

)V( .)V ( ′

′−=′

′−′=l

llnε

where Vwhere V′′ 2 is calculated by eq ( 1 ) 2 is calculated by eq ( 1 )

some times the quantities known are V2 , I2 Cos some times the quantities known are V2 , I2 Cos gg2 , Zeq 2 , Zeq in this case To find the voltage regulation V1 we can calculated from the in this case To find the voltage regulation V1 we can calculated from the geometry as geometry as Note :Note :Parameters rParameters r′′ 2 , X2 , X′′ 2 , I2 , I′′ 2 , E2 , E′′ 2 as follows : 2 as follows :

( ) ( ) I cosV V eq XI sin VR 2222

eq2221 - ′′+′−′= φφ

K

I I 2

2 =′Where ;Where ;

r′ 2 = k2 r2 , x′ 2 = k2 x2 E′ 2 = kE2

1

2

2

1

1

1

2

1

I

I

V

V

E

E

N

N k ≅≅==

in

in

input

output

PP

P

Pη losses - ==

( ) req2

2 req 12 1212cu I I r r I IP ′==′+=∴ ∝ cup

( )( )

( )( )b

a

bcu

acu

PP

2

2

I

I =

Transformer efficiency (η ) :

This means that if the cu losses are known at a certain load ( current ) , This means that if the cu losses are known at a certain load ( current ) , then the copper losses can be determined at another load .then the copper losses can be determined at another load .

I1 : nominal value ( full load value ) usually the copper losses are I1 : nominal value ( full load value ) usually the copper losses are determined from a short circuit test at a current equal to the full load or determined from a short circuit test at a current equal to the full load or nominal value , accordingly the equation can be written as :nominal value , accordingly the equation can be written as :

( )( )

( ) lflfcu

cu

PP

.I

I

. 2

2

=

( ) ( )2

II

.

=

f.lcucu lfrequired pp

X I

I =

f.l

let

f.lcucu PP ) ( X required 2 =

loss loss const.

cuout

out

PPη

++= ( )

( ) cuP Pout

out

cos K.V.A

cos K.V.A

o ++=

φφ

( )( ) cuP Pout

out

o cos K.V.A

cos K.V.A

++=

φφ ::ىىىى ىىىىىى ىىىى ىىىىىى ) ) ηηوعموما الكفاءة عند أى حمل ( وعموما الكفاءة عند أى حمل (

in

losses -in p

pη =

f.lo cu )(

ppη

f.l

f.l

X cos )K.V.A ( X

cos )K.V.A ( X

2++=

φφ

cos )K.V.A ( X

X cos )K.V.A ( X

2

φφ

f.l

f.l cu )( f.lo ppη −−=Χ

average efficiency for the transformer during 1 day ;average efficiency for the transformer during 1 day ;

hours 24ough energy thrinput Total

hours 24ough energy throutput Total =η

the input energy of the transformer through the day is equal to the Total the input energy of the transformer through the day is equal to the Total out put + Total losses per/day . out put + Total losses per/day . losses are const. or magnetic ( Plosses are const. or magnetic ( P

oo ) and are constant through the day . ) and are constant through the day .

the ( electrical orthe ( electrical or cu ) losses are variable according to the load ( cu ) losses are variable according to the load ( QQII22 ) . ) .

E.X : E.X : 100 K.V.A lighting transformer has a full load loss of 3 K.V.A , the 100 K.V.A lighting transformer has a full load loss of 3 K.V.A , the losses being equally devided between iron and copper . During a day the losses being equally devided between iron and copper . During a day the transformer operates , on full load for 3 hours , one half for 4 hours , the transformer operates , on full load for 3 hours , one half for 4 hours , the output being negligible for the reminder of the day calculate the all day output being negligible for the reminder of the day calculate the all day efficiency . efficiency .

SolutionSolution : : It should be noted that lighting transformers are taken to have a load p.f It should be noted that lighting transformers are taken to have a load p.f of unity iron losses for 24 hours = 1.5 x 24 = 36 K.W.h ( const. losses ) of unity iron losses for 24 hours = 1.5 x 24 = 36 K.W.h ( const. losses ) FL.cu losses = 1.5 K.W FL.cu losses = 1.5 K.W Cu loss for 3 hours on F.L = 1.5 x 3 = 4.5 k.w.hCu loss for 3 hours on F.L = 1.5 x 3 = 4.5 k.w.hCu loss for half F.L = 1.5 /4 k.w.h Cu loss for half F.L = 1.5 /4 k.w.h Cu loss for 4 hours at half the load = ( 1.5 / 4 ) x 4 = 1.5 k.w.h Cu loss for 4 hours at half the load = ( 1.5 / 4 ) x 4 = 1.5 k.w.h Total losses = 36 + 4.5 + 1.5 = 42 k.w.h Total losses = 36 + 4.5 + 1.5 = 42 k.w.h Total output = ( 100 x3 ) + ( 50 x 4 ) = 500 k.w.h Total output = ( 100 x3 ) + ( 50 x 4 ) = 500 k.w.h ηη all day = 500 x 100 / 542 = 92.26 %all day = 500 x 100 / 542 = 92.26 %

Group numbers : Group numbers : The group number indicates the phase differience between primary and The group number indicates the phase differience between primary and secondary ( H.T and L.T ) line voltages in electrical degrees . It is secondary ( H.T and L.T ) line voltages in electrical degrees . It is sometimes determined as a clock reading each hour is equivalent to sometimes determined as a clock reading each hour is equivalent to 30° phase difference . 30° phase difference .

Y-Y connectios : Y-Y connectios :

( ( ∆∆ Y ) Y )

Parallel operation :Parallel operation :

1.1.the transformations ratios must be the the transformations ratios must be the same same

2.2.the group number must be the same the group number must be the same 3.3.the phase connection must be in same the phase connection must be in same

sequence sequence 4.4.short circuit impendence ( Zeq ) must be short circuit impendence ( Zeq ) must be

the same the same

In power station transformers are usually In power station transformers are usually working in parallel in order to enable the working in parallel in order to enable the connections or disconnection of any number connections or disconnection of any number of them according to their required load :-of them according to their required load :-The following conditions must be fulfilled The following conditions must be fulfilled for correct parallel operation : for correct parallel operation :

Transformers are produced locally as , three phase immersed in oil , Transformers are produced locally as , three phase immersed in oil , natural cooling , in door & outdoor ,with power rate from 50 up to natural cooling , in door & outdoor ,with power rate from 50 up to 10.000 K.V.A & voltages up to 22 K.V.A under licence of Siemens 10.000 K.V.A & voltages up to 22 K.V.A under licence of Siemens A.B.B & France TransfoA.B.B & France Transfo2.12.1 General characteristics : General characteristics :

the transformers described have the following general characteristics :the transformers described have the following general characteristics :Three – phase .Three – phase .Connection D/Y11Connection D/Y11 Frequency 50 Hz .Frequency 50 Hz .Natural cooling in oil or silicon .Natural cooling in oil or silicon .Continuous service .Continuous service .Indoor or out door installation .Indoor or out door installation .

Rated power :Rated power :

Normal rated power in KVA as follows . ( 25- 50- 100 – 160 – 250 – 400 – Normal rated power in KVA as follows . ( 25- 50- 100 – 160 – 250 – 400 – 500- 630 – 800 – 1000 – 1250 – 1600 – 2000 – 2500 – K.V.A -………. ) 500- 630 – 800 – 1000 – 1250 – 1600 – 2000 – 2500 – K.V.A -………. )

2.2.2 Formation of distribution 2 Formation of distribution transformers :transformers :

مكونات محولت التوزيعمكونات محولت التوزيع

•2.2.1 Iron core:2.2.1 Iron core: القلب الحديدى :القلب الحديدى :* *

Made of cold rolled silicon steel sheets 0.3mm Made of cold rolled silicon steel sheets 0.3mm to minimize losses to minimize losses

يصنع القلب الحديدى من رقائق الصلب السيليكونى المسحوب يصنع القلب الحديدى من رقائق الصلب السيليكونى المسحوب مم لتقليل الفقد فى الفيض المغناطيسىمم لتقليل الفقد فى الفيض المغناطيسى0.30.3على البارد بسمك على البارد بسمك

2.2.2 –Windings:2.2.2 –Windings:

High tension turns are made of copper High tension turns are made of copper wires of either circular cross sections wires of either circular cross sections varnish isolated or rectangular cross varnish isolated or rectangular cross sections isolated by sililose paper. Low sections isolated by sililose paper. Low tension turns are made of either tension turns are made of either noninsulated copper foils with insulating noninsulated copper foils with insulating paper in between or of rectangular wires paper in between or of rectangular wires insulated by cylindrical paper sheetsinsulated by cylindrical paper sheets

الملفات :الملفات :

تصنع ملفات الجهد العالى من أسلك نحاسية ذات مقطع تصنع ملفات الجهد العالى من أسلك نحاسية ذات مقطع

مستدير معزول بالورنيش أو مقطع مستطيل معزول بالورق مستدير معزول بالورنيش أو مقطع مستطيل معزول بالورق

شرائح ممن المنخفمض الضغمط ملفات وتصمنع شرائح السميليوزى ممن المنخفمض الضغمط ملفات وتصمنع السميليوزى

بشرائح معزولمة نحاس أسملك أمو بالورق المعزول بشرائح النحاس معزولمة نحاس أسملك أمو بالورق المعزول النحاس

الورق السطوانية .الورق السطوانية .

2.2.3-Tank :2.2.3-Tank :The transformer tank is made of The transformer tank is made of

corrugated steel .corrugated steel .The corrugated tank surface is itself the The corrugated tank surface is itself the

cooling surface. The tank is provided with an cooling surface. The tank is provided with an additional steel reservoir for oil expansion, additional steel reservoir for oil expansion, on which a piping device is installed to on which a piping device is installed to transmit oil cock ,a hole for silicagel transmit oil cock ,a hole for silicagel apparatus,and an oil level indicatorapparatus,and an oil level indicator..

التنك الخارجى :التنك الخارجى :

يصنع التنك من ألواح الصاج المعرج ليكون جسم التنك يصنع التنك من ألواح الصاج المعرج ليكون جسم التنك

هو المسسطح المبرد للمحول ويزود التنك بخزان لتمدد هو المسسطح المبرد للمحول ويزود التنك بخزان لتمدد

الزيت مصنع من الصاج ويركب عليه مواسير توصيل الزيت مصنع من الصاج ويركب عليه مواسير توصيل

الزيست وفتحة نقسص لتعويسض فتحسة وبسه للتنسك الزيست وفتحة الزيست نقسص لتعويسض فتحسة وبسه للتنسك الزيست

لتركيب جهاز السيلكاجل وكذلك مبين الزيتلتركيب جهاز السيلكاجل وكذلك مبين الزيت

2.2.4- Terminals :2.2.4- Terminals :

H.V.and L.V. terminals are brought out H.V.and L.V. terminals are brought out through porcelain bushings according to the through porcelain bushings according to the rated voltage. The insulators are fixed to the rated voltage. The insulators are fixed to the tank cover in such a way to ensure replacement tank cover in such a way to ensure replacement without dismantling the transformer cover. without dismantling the transformer cover. Cable end boxes on either H.T. or L.T. side or Cable end boxes on either H.T. or L.T. side or

both can be made if requiredboth can be made if required..

أطراف التوصيل :أطراف التوصيل :توصل أطراف الضغط العالى والمنخفض الى عوزال توصل أطراف الضغط العالى والمنخفض الى عوزال من الصينى مناسبة لجهد التشغيل وتثبت هذه العوازل من الصينى مناسبة لجهد التشغيل وتثبت هذه العوازل فتح بدون بتغييرهسا تسسمح بطريقسة التنسك غطاء فتح فى بدون بتغييرهسا تسسمح بطريقسة التنسك غطاء فى نهاية بصسناديق تزويدهسا يمكسن الطلسب وعنسد نهاية الغطاء بصسناديق تزويدهسا يمكسن الطلسب وعنسد الغطاء العالى الضغسط جهتسى مسن الطلسب حالسة فسى العالى للكابلت الضغسط جهتسى مسن الطلسب حالسة فسى للكابلت

والمنخفض أو احداهما فقط.والمنخفض أو احداهما فقط.

2.2.5 –Tapchangers :2.2.5 –Tapchangers : or distribution transformers , tap or distribution transformers , tap

changers are externally for allowing changers are externally for allowing voltage regulation with ±5 % of the rated voltage regulation with ±5 % of the rated value in 5 equal steps of ± 2.5 % each , value in 5 equal steps of ± 2.5 % each , the tap changer is manually operated the tap changer is manually operated while current is offwhile current is off

منظمات الجهد :منظمات الجهد :

يركب على محولت التوزيع منظمات للجهد ذات خمس يركب على محولت التوزيع منظمات للجهد ذات خمس % كل منها % كل منها 55 ++مراحل تسمح بتغيير الجهد فى حدود مراحل تسمح بتغيير الجهد فى حدود

% ويعمل يدويا من خارج المحول بعد فصل % ويعمل يدويا من خارج المحول بعد فصل 2.52.5 ++المحول عن الكهرباء تماما أى أن المنظم يعمل على المحول عن الكهرباء تماما أى أن المنظم يعمل على

اللحمل .اللحمل .

2.2.6- Oil :2.2.6- Oil :

transformers are filled with special oil transformers are filled with special oil ( Diala ( 5 ) or equal ) of high insulating ( Diala ( 5 ) or equal ) of high insulating grade according to IEC specificationsgrade according to IEC specifications

زيت التبريد :زيت التبريد : ..

تملم المحولت بزيمت محولت ذو درجة عزل عالية تملم المحولت بزيمت محولت ذو درجة عزل عالية IECIEC(ديالة ب أو ما يماثلها ) طبقا لمواصفات (ديالة ب أو ما يماثلها ) طبقا لمواصفات

2.2.7 – Main accessories of distribution 2.2.7 – Main accessories of distribution transformers : transformers :

Oil expansion reservoir . Oil expansion reservoir . Thermometer pocket Thermometer pocket Oil drain cock Oil drain cock Oil level indicator Oil level indicator Lifting chackles Lifting chackles Four two – directional adjustable wheels Four two – directional adjustable wheels Earth screw Earth screw Name plateName plate

الملحقات الساسية لمحولت التوزيع :الملحقات الساسية لمحولت التوزيع :

خزان تمدد الزيتخزان تمدد الزيتجراب الترمومترجراب الترمومتر صمام تصريف الزيت أو أخذ عينات منه صمام تصريف الزيت أو أخذ عينات منهمبين مستوى الزيتمبين مستوى الزيتحلقات لرفع المحولحلقات لرفع المحول أربع عجلت أربع عجلتمسمار توصيل الرضىمسمار توصيل الرضىلوحة البيانلوحة البيان

2.2.8 – Additional accessories :2.2.8 – Additional accessories : Dehydrating breather Dehydrating breather Buchholz relay Buchholz relay Ordinary mercury thermometerOrdinary mercury thermometer

الملحقات الضافيةالملحقات الضافيةجهاز السيلكاجل لمتصاص الرطوبةجهاز السيلكاجل لمتصاص الرطوبةجهاز البوخهلز لحماية المحولجهاز البوخهلز لحماية المحولترمومتر عادىترمومتر عادى

) رقم شكككل يلككى ( وفيمككا رقم شكككل يلككى ) ) 11وفيمككا نموذج نموذج يوضح لمكونات لمكونات يوضح

المحولت المصنعة محليًاالمحولت المصنعة محليًا

3.1 The general data of transformers are: 3.1 The general data of transformers are: المواصفات العامة المواصفات العامة للمحولتللمحولت

يجب تحديد ما إذا كانت المحولت المطلوبه تعمل يجب تحديد ما إذا كانت المحولت المطلوبه تعملمنفرده أوعلسى التوازى مع بعضها أو مع محولت منفرده أوعلسى التوازى مع بعضها أو مع محولت أخرى موجودة وفى هذه الحاله يجب بيان المعاوقه أخرى موجودة وفى هذه الحاله يجب بيان المعاوقه

الكليه للمحولت الموجودة .الكليه للمحولت الموجودة .

Determine wheather the ransformer will Determine wheather the ransformer will work in parallel or individual In case of work in parallel or individual In case of parallel work with old transformers, the parallel work with old transformers, the voltages and impeadance of them must be voltages and impeadance of them must be mentioned . mentioned .

. نسبة التغيير منظم الجهد .نسبة التغيير منظم الجهد Percentage regulation of tap changer .Percentage regulation of tap changer .

مكان تركيب المحول وهل يركب داخل المبنى أم مكان تركيب المحول وهل يركب داخل المبنى أمخارجة .خارجة .

The place in which the transformer will be The place in which the transformer will be installed and wheather indoor or outdoor . installed and wheather indoor or outdoor .

. رقم مجموعة التوصيل .رقم مجموعة التوصيل Connection group ( e.g DY II ) Connection group ( e.g DY II )

. جهد الدخول , وجهد الخروج , والذبذبة بالهرتز .جهد الدخول , وجهد الخروج , والذبذبة بالهرتز Input voltage , output voltage in volts and Input voltage , output voltage in volts and cycle in Hertz . cycle in Hertz .

ك.ف.أك.ف.أ . . قدرة المحولقدرة المحول Power of transformer in K.V.A Power of transformer in K.V.A

3.2 Selection3.2 Selection: : كيفية تحديد مواصفات المحولتكيفية تحديد مواصفات المحولت3.2.1 Rated values :3.2.1 Rated values :

The rated values of the transformer such as power , voltage , The rated values of the transformer such as power , voltage , transformation ratio and impendence ratio are selected according to transformation ratio and impendence ratio are selected according to the requirements of the system .the requirements of the system .

تتحدد القيم السمية كالقدرة والجهد ونسبة التحويل والمقاومة الكلية طبقًا لمتطلبات نظام التغذية تتحدد القيم السمية كالقدرة والجهد ونسبة التحويل والمقاومة الكلية طبقًا لمتطلبات نظام التغذية الكهربائيةالكهربائية

3.2.2 Rated power :3.2.2 Rated power :

The rated power is found first by determining the peak effective power The rated power is found first by determining the peak effective power demand designed or measured , usually a margin is added to provide demand designed or measured , usually a margin is added to provide for the regular increase in power demand .for the regular increase in power demand .

( ) ( ) تتحد القدرة السمية عن طريق التصميم أو القياس لقصى قدرة فعاله مطلوبة مع إضافة نسبة تتحد القدرة السمية عن طريق التصميم أو القياس لقصى قدرة فعاله مطلوبة مع إضافة نسبة ..من القدرة لحتمالت الزيادة المستقبلية العادية فى الطاقة الكهربائية المطلوبة من القدرة لحتمالت الزيادة المستقبلية العادية فى الطاقة الكهربائية المطلوبة

When calculate the rated power (PN) we must take in consideration the When calculate the rated power (PN) we must take in consideration the anticipated power factor (COS anticipated power factor (COS ) )

. . ويجب عند حساب هذة القدرة السمية مراعاة قيمة معامل القدرة المتوقع ويجب عند حساب هذة القدرة السمية مراعاة قيمة معامل القدرة المتوقع

3.2.3 The impendence voltage(UK) :3.2.3 The impendence voltage(UK) :

the impeadence voltage the impeadence voltage UKUK is the voltage necessary at the input terminals at is the voltage necessary at the input terminals at rated frequency to cause the rated current to flow in the primary when the rated frequency to cause the rated current to flow in the primary when the terminals on the secondary are short circuited terminals on the secondary are short circuited

3.2.4 The rated impeadence voltage(UkN) :3.2.4 The rated impeadence voltage(UkN) :

the rated impeadance voltage (UKN) is the value of the impedance voltage the rated impeadance voltage (UKN) is the value of the impedance voltage on the principal tap when related to the rated voltage (UN) it is called UKN on the principal tap when related to the rated voltage (UN) it is called UKN and given in percentand given in percent

UkNUkN UNUNWhere ;Where ;

UKN = rated impeadence voltage % .UKN = rated impeadence voltage % .UKN = rated impeadence voltage in V.UKN = rated impeadence voltage in V. U.N = reated voltage in V.U.N = reated voltage in V.

X 100%X 100%UkN =UkN =

3.2.5 Selection of rated impeadence voltage :3.2.5 Selection of rated impeadence voltage :

In distribution system a rated impeadence voltage UKN= 4 % is preferred in order to keep In distribution system a rated impeadence voltage UKN= 4 % is preferred in order to keep the voltage drop small .the voltage drop small .

For larger industrial systems with greater power demand transformers with a rated For larger industrial systems with greater power demand transformers with a rated impeadence voltage of 6 % are used in order to limit the short – circuit stresses on the impeadence voltage of 6 % are used in order to limit the short – circuit stresses on the switch gear of the plant . switch gear of the plant .

3.2.6 Transformers loss PK:3.2.6 Transformers loss PK:

For transformers losses include no-load losses Po and load losses ( Pk ) the no load losses For transformers losses include no-load losses Po and load losses ( Pk ) the no load losses resulting from the continious magnetic flux reversal in the iron are practically constant resulting from the continious magnetic flux reversal in the iron are practically constant voltage impeadence of load .voltage impeadence of load .

The load losses ( copper losses ) constant of resistive losses in the windings and losses due The load losses ( copper losses ) constant of resistive losses in the windings and losses due to stray fields , the load losses vary with the square of the load . the total losses of a to stray fields , the load losses vary with the square of the load . the total losses of a transformer are :-transformer are :-

Pk a P P 2

OV +=

)K.V.A in Ppower rated

K.V.A in pa loadpart (factor load a =

Pv = total losses in watt .Pv = total losses in watt ...Po = no-load in watt.Po = no-load in watt.

PK = load losses in W PK = load losses in W

3.2.7 3.2.7 ηη - Efficiency : - Efficiency : the efficiency the efficiency ηη of a distribution transformer can be calculated of a distribution transformer can be calculated

with reasonable accuracy from the following ; with reasonable accuracy from the following ; NN

where ; where ; ηη = efficiency in % .= efficiency in % .PN PN = rated power in K.V.A .= rated power in K.V.A .Po Po = no-load losses in K.W ,= no-load losses in K.W ,Pk Pk = load losses in K.W .= load losses in K.W . = power factor . = power factor . a a = load factor . = load factor .

% 100 Po cos Watt P a

Pa Po - % 100

N

k2

×+

+=φ

η

φ Cos

* Example :-* Example :-

calculate efficiency (calculate efficiency (ηη ) of a transformer at full load given the ) of a transformer at full load given the following information :following information :

PN = 500 K.V.A., Po = 1.1 K.W , Pk = 5.5 K.W , PN = 500 K.V.A., Po = 1.1 K.W , Pk = 5.5 K.W , Cos Cos = 0.8 , a = 1.0 = 0.8 , a = 1.0

ηη = 98.36 %= 98.36 %

% 100 Po cos P a

P a Po - % 100

N

K2

×+

+=φ

η

% 100 K.W 1.1 8.0K.V 500 1

K.w 5.5 (1) K.W 1.1 - % 100

2

×+××

×+=η

=

Pk

Po a

447.05.5(k.w)

(k.w) 1.1 a ==

( )% 100

K.W 1.1 8.0KVA 500 447.0

K.w 5.5 0.447 K.W 1.1 - % 100

2

×+××

×+=η

3.2.8 Maximum efficiency: 3.2.8 Maximum efficiency:

the load factor ( a ) for the maximum efficiency of a transformer is defined as the load factor ( a ) for the maximum efficiency of a transformer is defined as follows ;follows ;

For the transformer in the above example this becomes ;For the transformer in the above example this becomes ;

Therefore maximum efficiency occurs with a load of ;Therefore maximum efficiency occurs with a load of ;Pa = PN.a Pa = PN.a Pa = 500 K.V.A Pa = 500 K.V.A ×× 0.447 = 224 K.V.A 0.447 = 224 K.V.A And for this load the efficiency is ;And for this load the efficiency is ;

ηη = 98.36 %= 98.36 %ηη = 98.78 % .= 98.78 % .

3.2.9 Insulation class :3.2.9 Insulation class :

the insulation rating of a transformer is designed by numerals indicating the the insulation rating of a transformer is designed by numerals indicating the insulation voltage class in K.V & a letter insulation voltage class in K.V & a letter NN indicating that the transformer is indicating that the transformer is designed for use no a system where a neutral is not solidly earthed . designed for use no a system where a neutral is not solidly earthed . the insulation class corresponds to the values given in table no (1)* the insulation class corresponds to the values given in table no (1)*

Table no (1)* Table no (1)*

3.2.10 Maximum continuous operating voltage ( U.b) :3.2.10 Maximum continuous operating voltage ( U.b) :

transformers must be selected with an insulation class such that the voltage on which transformers must be selected with an insulation class such that the voltage on which

they are continuously used does not exceed the allocated operating voltage ( Ub ) .they are continuously used does not exceed the allocated operating voltage ( Ub ) .

Rated voltages (UN): Rated voltages (UN):

The rated voltages ( UN ) is the voltage present , at rated load , The rated voltages ( UN ) is the voltage present , at rated load , at the input windings and for which the transformer is at the input windings and for which the transformer is designed .designed .

The rated voltage ( UN ) on the output side is the voltage which The rated voltage ( UN ) on the output side is the voltage which appears at no load ( no load voltage Uo ) with rated voltage appears at no load ( no load voltage Uo ) with rated voltage and rated frequency on the input side .and rated frequency on the input side .

3.2.11 Adjustment of transformer ratio steps :3.2.11 Adjustment of transformer ratio steps :

to compensate for voltage fluctuations due to load variations in systems , the high voltage to compensate for voltage fluctuations due to load variations in systems , the high voltage windings of distribution transformers have tapping brought out to terminals ( as windings of distribution transformers have tapping brought out to terminals ( as normally used on dry-type transformers ) or to a tap changer ( as normally used on oil – or normally used on dry-type transformers ) or to a tap changer ( as normally used on oil – or Askeral – immersed transformers ) the tapping corresponding to the nominal voltage is Askeral – immersed transformers ) the tapping corresponding to the nominal voltage is normally situated in the middle of the tapping range and is referred to as the principal tap .normally situated in the middle of the tapping range and is referred to as the principal tap .

Rated tapping range :Rated tapping range :

the rated tap voltage range of a winding is the range between the highest tap voltage and the rated tap voltage range of a winding is the range between the highest tap voltage and nominal or similary the lowest tap voltage and nominal under no load condition with an nominal or similary the lowest tap voltage and nominal under no load condition with an excitation corresponding to the rated voltage on the principal tapexcitation corresponding to the rated voltage on the principal tap

Tap voltage range :Tap voltage range :

tap voltage ranges are laid down in DIN standard and expressed as a percentage rated tap voltage ranges are laid down in DIN standard and expressed as a percentage rated voltage ( e.g ± 4% ) V.D.E 0532 specifies that rated voltages and the adjustable voltages voltage ( e.g ± 4% ) V.D.E 0532 specifies that rated voltages and the adjustable voltages are shown in Volts in the rating plate . for a transformer with rated voltage on the input are shown in Volts in the rating plate . for a transformer with rated voltage on the input side of 20.000 volt and a rated tap voltage range of ± 5% , the rating plate would show the side of 20.000 volt and a rated tap voltage range of ± 5% , the rating plate would show the values 21.000 V, 20.000 V and 19.000 Voltvalues 21.000 V, 20.000 V and 19.000 Volt . .

3.2.12 vector group number :3.2.12 vector group number :

The vector group symbol indicates the respective connections of the high voltage and low The vector group symbol indicates the respective connections of the high voltage and low voltage transformer windings their relative phase displacement expressed as a clock – hour voltage transformer windings their relative phase displacement expressed as a clock – hour figure. figure. the identification letters of the method of connection are given for the high voltage the identification letters of the method of connection are given for the high voltage winding ( OS ) in capital letters and for low voltage side ( us ) in small letters see table no winding ( OS ) in capital letters and for low voltage side ( us ) in small letters see table no (2)* (2)*

Table no (2)Clock – hour number :Clock – hour number :

the clock hour number indicate the multiple of 30° with which the vector of the low the clock hour number indicate the multiple of 30° with which the vector of the low voltage side is lagging when moving anti-clock wise in comparison to the high voltage side is lagging when moving anti-clock wise in comparison to the high voltage side of the corresponding terminal this angle between the voltage vectors can voltage side of the corresponding terminal this angle between the voltage vectors can have values between 0° & 360° .have values between 0° & 360° .

the terminals 2U,2V& 2W on the low voltage side are related to the terminals the terminals 2U,2V& 2W on the low voltage side are related to the terminals 1U,1V,1W on the high voltage side , the mark up U , V, W corresponding to DIN 1U,1V,1W on the high voltage side , the mark up U , V, W corresponding to DIN standard .standard .

Obtaining the clock hour number:Obtaining the clock hour number:

the clock hour number can be obtained by first drawing the vector diagrams of the the clock hour number can be obtained by first drawing the vector diagrams of the connections of the windings up one on top of the other and both on top of a clock face connections of the windings up one on top of the other and both on top of a clock face in such a way that the marking 1V of the high voltage side coincides with number 12 in such a way that the marking 1V of the high voltage side coincides with number 12 corresponding to 0 .corresponding to 0 .

the position 2V of the connection diagram of the low voltage side on the clock face the position 2V of the connection diagram of the low voltage side on the clock face gives the clock hour number of the vector group .gives the clock hour number of the vector group .Example: (fig 2).Example: (fig 2).

Fig no (2)Fig no (2)Vector group (DY5)Vector group (DY5)

* C – Y/S: * C – Y/S: High voltage side : C connection .High voltage side : C connection .Low voltage side : y connection Low voltage side : y connection

Clock – hour number 5 multiplied by 30° gives 150° Clock – hour number 5 multiplied by 30° gives 150° phase displacement between vector 1V of the high voltage phase displacement between vector 1V of the high voltage winding & the vector 2V of the low voltage winding .winding & the vector 2V of the low voltage winding .

preferred vector group :preferred vector group :

for distribution transformers , star or delta connections for for distribution transformers , star or delta connections for the high voltage windings and star or zizag connections the high voltage windings and star or zizag connections for the low voltage winding are preferred table (3)* shows for the low voltage winding are preferred table (3)* shows some group numbers some group numbers

Table no (3)Table no (3)

4.1 Indoor installation :4.1 Indoor installation :Indoor pattern fluid cooled transformers must be installed in covered rooms Indoor pattern fluid cooled transformers must be installed in covered rooms which provide protection against rain , snow , dust & sand etc…. , and good which provide protection against rain , snow , dust & sand etc…. , and good ventilation .ventilation .Dry type transformers : must be installed in closed rooms which dry & Dry type transformers : must be installed in closed rooms which dry & practically dust free the rooms should be easily accessible , to allow for practically dust free the rooms should be easily accessible , to allow for transport , operation maintenance & fire fighting .transport , operation maintenance & fire fighting .

4.2 Outdoor installation : 4.2 Outdoor installation : Fluid cooled transformers are suitable for outdoor installation when Fluid cooled transformers are suitable for outdoor installation when provided with suitable bushings & paint finish suitable for outdoor provided with suitable bushings & paint finish suitable for outdoor conditions.conditions.Measuring the temperature of insulating and cooling fluid the temperature Measuring the temperature of insulating and cooling fluid the temperature of the cooling and insulating fluid are measure near the top for this purpose, of the cooling and insulating fluid are measure near the top for this purpose, the caver of the transformer contains for thermometer pockets into which the caver of the transformer contains for thermometer pockets into which thermometers can be inserted these pockets are filled with same type of thermometers can be inserted these pockets are filled with same type of cooling and insulating fluids used within the transformer cooling and insulating fluids used within the transformer

4.3 Building dimensions of transformer station :4.3 Building dimensions of transformer station :The dimensions of the transformers are an important factor to house the The dimensions of the transformers are an important factor to house the transformer allowance should always be made for increase the power transformer allowance should always be made for increase the power demand in the future .demand in the future .The following table give an example of dimensions of transformers for a The following table give an example of dimensions of transformers for a given power [table (4) & fig no (3)*] .given power [table (4) & fig no (3)*] .

Fig no (3)Fig no (3)

Table no (4)Table no (4)Shows some ratings of Transformers And their dimensions and weightsShows some ratings of Transformers And their dimensions and weights

The height of the building to house a transformer & also provide the The height of the building to house a transformer & also provide the required access is dependant upon the height of the transformer , the type of required access is dependant upon the height of the transformer , the type of ventilation , the location cables & connections & the clearance necessary ventilation , the location cables & connections & the clearance necessary between live parts & earthed metal . for this type of transformer station the between live parts & earthed metal . for this type of transformer station the minimum height transformer should be the over all height of the minimum height transformer should be the over all height of the transformer plus 500mm ..transformer plus 500mm ..

4.4 Width of inspection passage way:4.4 Width of inspection passage way:

the length & width of a transformer station with service access should be the length & width of a transformer station with service access should be dimensioned such that for transformers with rated power of up to 630 KVA dimensioned such that for transformers with rated power of up to 630 KVA the inspection passage wais are at least 70 cm wide , for transformers of the inspection passage wais are at least 70 cm wide , for transformers of 800-1600K.V.A. the passage- ways should be at least 75 cm wide 800-1600K.V.A. the passage- ways should be at least 75 cm wide

4.5 Floor of transformer station for fluid cooled transformers :4.5 Floor of transformer station for fluid cooled transformers :

the floor of the transformer station can be made from either a reinforced the floor of the transformer station can be made from either a reinforced concrete slab with an opening in the centre or from girders of reinforced concrete slab with an opening in the centre or from girders of reinforced concrete slab construction is used . the cement grouting should have an concrete slab construction is used . the cement grouting should have an inclination of 1-2° in the direction of the collecting pit as shown in fig.(4) *inclination of 1-2° in the direction of the collecting pit as shown in fig.(4) *

fig no ( 4 )fig no ( 4 )example for the indoor example for the indoor

installation of a transformerinstallation of a transformer

4.6 Rails for transportation rollers :4.6 Rails for transportation rollers :

the international specifications states the recommendations for steel the international specifications states the recommendations for steel I section girders for supporting transformers the transportation I section girders for supporting transformers the transportation rollers rest on these girders which also incorporate a guide strip 2 rollers rest on these girders which also incorporate a guide strip 2 cm high fig. (5) * cm high fig. (5) *

Fig no (5)Fig no (5)Typical arrangement of girderTypical arrangement of girder

And guide strip for And guide strip for transportation rollerstransportation rollers

4.7 For oil immersed transformers:4.7 For oil immersed transformers:

Collecting tank and pits cooling and insulating fluid : Collecting tank and pits cooling and insulating fluid : For transformers with a rated power of 630 – K.V.A a collecting tank below the For transformers with a rated power of 630 – K.V.A a collecting tank below the transformer can be used providing it has capacity sufficient to hold the total fluid of transformer can be used providing it has capacity sufficient to hold the total fluid of the transformer floor can also be used as collecting tank when the door step & the transformer floor can also be used as collecting tank when the door step & ventilation openings are correspondingly high ventilation openings are correspondingly high

Collecting pit :Collecting pit :For transformers with rated power of 800 – 1600 K.VA, the collecting pit provided For transformers with rated power of 800 – 1600 K.VA, the collecting pit provided must have a capacity of approxi 2 m³ ( oil content of transformers ) .must have a capacity of approxi 2 m³ ( oil content of transformers ) .With a number of transformers each with rated capacity of between 800 – 1600 With a number of transformers each with rated capacity of between 800 – 1600 K.VA. a common collecting pit can be used providing this has a capacity at least 2 K.VA. a common collecting pit can be used providing this has a capacity at least 2 m³ . this pit can be situated out side the transformers , it is permitted to construct a m³ . this pit can be situated out side the transformers , it is permitted to construct a number of small inter connected pits providing the total capacity of these pits exceed number of small inter connected pits providing the total capacity of these pits exceed 2 m³ . a sum pit should be provided in the bottom of each pit to facilitate the pumping 2 m³ . a sum pit should be provided in the bottom of each pit to facilitate the pumping out of small amounts of water or oil .out of small amounts of water or oil .

Gravel, granite chipping layer :Gravel, granite chipping layer :Collecting pits & the oil carrying ducts for a common collecting pit must be screened Collecting pits & the oil carrying ducts for a common collecting pit must be screened above by a layer of gravel or granite chipping at least 20 cm , thick laid on a above by a layer of gravel or granite chipping at least 20 cm , thick laid on a galvanized iron grating to minimize the spread of fire fig no (5) *galvanized iron grating to minimize the spread of fire fig no (5) *

Outdoor collecting pit :Outdoor collecting pit :

A collecting pit must also be provided if transformers are installed A collecting pit must also be provided if transformers are installed outdoor in order to prevent seepage of cooling &insulating fluid into outdoor in order to prevent seepage of cooling &insulating fluid into the ground . the out door collecting pit must have a capacity of at the ground . the out door collecting pit must have a capacity of at least 1.2 times the fluid content of the transformer to allow for part least 1.2 times the fluid content of the transformer to allow for part filling of rain water or melted or melted snow , the pit must be filling of rain water or melted or melted snow , the pit must be pumped out regularly , other wise it would became filled with pumped out regularly , other wise it would became filled with rainwater .rainwater .

4.8 Ventilation of transformer rooms :4.8 Ventilation of transformer rooms :

When designing the room to house a self – cooled transformer it When designing the room to house a self – cooled transformer it must be borne in mind that the transformer heat losses must be must be borne in mind that the transformer heat losses must be dissipated inlet- & outlet air openings have to provided the air inlet dissipated inlet- & outlet air openings have to provided the air inlet should be either from underneath the transformer or as close as should be either from underneath the transformer or as close as possible to the floor level but never higher than the midpoint of the possible to the floor level but never higher than the midpoint of the transformer . the outlet opening should be as high as passible.inlet transformer . the outlet opening should be as high as passible.inlet and outlet openings should be arranged on opposite walls . The and outlet openings should be arranged on opposite walls . The efficiency of the ventilation increases with the difference in height efficiency of the ventilation increases with the difference in height between the middle of the transformer tank & the outlet openings, between the middle of the transformer tank & the outlet openings, fig (6)*.fig (6)*.

Fig no (6)Fig no (6)Arrangement of inlet Arrangement of inlet

and outlet air openingsand outlet air openings

4.9 Dimensioning of outlet air opening :4.9 Dimensioning of outlet air opening :

from curves given fig.(10) the dimensions of the required out let air from curves given fig.(10) the dimensions of the required out let air opening can be approximated the value obtained is for a free air opening can be approximated the value obtained is for a free air opening without screen & also allowing for an air temperature rise of opening without screen & also allowing for an air temperature rise of 15 °C within the room the values have been increased by for simple 15 °C within the room the values have been increased by for simple screens approx. 10% , for screens & shutters approx. 50 % .screens approx. 10% , for screens & shutters approx. 50 % .

Dimensions of inlet- air opening :Dimensions of inlet- air opening : The dimensions of the inlet – air opening can be 10 % smaller than The dimensions of the inlet – air opening can be 10 % smaller than

the dimensions of the outlet- air opening , ( plus the increase the dimensions of the outlet- air opening , ( plus the increase required for screen & shutters ) . to find the dimensions of inlet & required for screen & shutters ) . to find the dimensions of inlet & outlet air openings . outlet air openings .

Given :Given :

Height from station floor to center of outlet air opening 3100 mm , Height from station floor to center of outlet air opening 3100 mm , transformer rated power 400 K.V.A height from station floor to mid transformer rated power 400 K.V.A height from station floor to mid point of transformer tank 600 mm resulting difference in height h = point of transformer tank 600 mm resulting difference in height h = 3100 – 600 = 2500 mm .3100 – 600 = 2500 mm .Outlet air opening obtained from curves 0.9 m² Outlet air opening obtained from curves 0.9 m² Increase for simple screen + 10 % + 0.09 m² Increase for simple screen + 10 % + 0.09 m² Dimension of outlet air opening 0.99 m²Dimension of outlet air opening 0.99 m²Dimension of inlet air opening (10 %) 0.9 m²Dimension of inlet air opening (10 %) 0.9 m²

5.1 5.1 Important instructions for Important instructions for commissioning :commissioning :

الخطوات التى يجب مراعاتها قبل بدء الخطوات التى يجب مراعاتها قبل بدء الختبارات والتشغيل :الختبارات والتشغيل :

1.1. cleaning the porcelain bushings – bus bars forcleaning the porcelain bushings – bus bars for

both H.T & L.T sides & tank surfaceboth H.T & L.T sides & tank surface جهتى - - 11 التوصميل وبارات الصمينى العوازل جهتى تنظيمف التوصميل وبارات الصمينى العوازل تنظيمف

الضغط العالى والضغط المنخفض وكذلك سطح التنك الضغط العالى والضغط المنخفض وكذلك سطح التنك ومواسير التبريد.ومواسير التبريد.

2.2. well fastening of porcelain bushing to well fastening of porcelain bushing to transformer cover and to be sure that transformer cover and to be sure that oil seals are in good conditionoil seals are in good condition

التنك - - 22 جسمم علمى الصمينى العوازل ربمط ممن التنك التأكمد جسمم علمى الصمينى العوازل ربمط ممن التأكمد وسلمة الجوانات المرنة التى تمنع تسرب الزيت من وسلمة الجوانات المرنة التى تمنع تسرب الزيت من

المحولتالمحولت

3.3. oil level for safe operationoil level for safe operation التأكد من أن مستوى الزيت فى المحول بالقدر الكافى التأكد من أن مستوى الزيت فى المحول بالقدر الكافى ––33على ممبين أدنمى مسمتوى يقمل عمن بحيمث ل على للتشغيمل ممبين أدنمى مسمتوى يقمل عمن بحيمث ل للتشغيمل خزان التمدد واذا احتاج المر فيمكن تزويد الزيت عن خزان التمدد واذا احتاج المر فيمكن تزويد الزيت عن طريمق الفتحة العليما بخزان التمدد وبنفمس نوع الزيت طريمق الفتحة العليما بخزان التمدد وبنفمس نوع الزيت

الصلى أو المعادل لهالصلى أو المعادل له

4.4. in case that the transformer is not used in case that the transformer is not used for long time the dielectric strength of for long time the dielectric strength of oil is to be checked & after a year of oil is to be checked & after a year of operation it must be not less than 20 operation it must be not less than 20 K.V/2.5 mmK.V/2.5 mm

اسمتعمال المحول لمدة طويلمة وكذلك - - 44 اسمتعمال المحول لمدة طويلمة وكذلك فى حالمة عدم فى حالمة عدم بعد مرور عام على التشغيل يجب اعادة اختبار قوة بعد مرور عام على التشغيل يجب اعادة اختبار قوة

مم. مم. 2.52.5 ك.ف/ ك.ف/2020عزل الزيت ويجب أل تقل عن عزل الزيت ويجب أل تقل عن

5.5. to ensure safety of operation apparatus like to ensure safety of operation apparatus like bucholz relay , thermometer , silica gel and bucholz relay , thermometer , silica gel and earthing screwearthing screw

55 - - ، البوخهلز مثمل الوقايمة أجهزة سملمة ممن ، التأكمد البوخهلز مثمل الوقايمة أجهزة سملمة ممن التأكمد الترمومتر والسيلكاجل ومسمار الرضىالترمومتر والسيلكاجل ومسمار الرضى

6.6. to be sure that the silica – gel is blue to be sure that the silica – gel is blue ( i,e) able to remove humidity , if it became ( i,e) able to remove humidity , if it became red it must be dried 140° till it is blue again red it must be dried 140° till it is blue again or must be changed .or must be changed .

يمكنه - - 66 حتمى الزرق السميلكاجل الملمح لون ممن يمكنه التأكمد حتمى الزرق السميلكاجل الملمح لون ممن التأكمد الحمر اللون الممى تحول فإذا الرطوبمة الحمر امتصمماص اللون الممى تحول فإذا الرطوبمة امتصمماص بتعريضه الملمح تجفيمف إعادة يجمب فإنمه بتعريضه الوردى الملمح تجفيمف إعادة يجمب فإنمه الوردى

حتى يستعيد لونه حتى يستعيد لونه ººمم140140لدرجة حرارة ل تزيد عن لدرجة حرارة ل تزيد عن الزرق أو بتغيير الملحالزرق أو بتغيير الملح

7.7. terminals of warning and switching off in the terminals of warning and switching off in the Buchholz relay must be connected to the Buchholz relay must be connected to the warning circuit and to the protection circuits warning circuit and to the protection circuits of the customer Here is a guide connection of the customer Here is a guide connection diagram (fig.No.13) In case of small faults diagram (fig.No.13) In case of small faults the gasses gathered around the upper fault the gasses gathered around the upper fault which closed , the warning circuit and the which closed , the warning circuit and the warning voice is heared , in case of big warning voice is heared , in case of big faults a big amount of gasses move the faults a big amount of gasses move the lower float which shuts the tripping circuit lower float which shuts the tripping circuit and the current is switched off the trafo – and the current is switched off the trafo – warning and switching circuits work on the warning and switching circuits work on the customer protection current on voltages customer protection current on voltages between 24 & 220 Volts A.C or D.C . between 24 & 220 Volts A.C or D.C .

يجب توصيل نقطتى النذار ونقطتى الفصل فى - 7روزتة جهاز البوخهلز بأجهزة النذار والفصل بمفاتيح العميل حيث تعمل صفارة النذار اذا تراكمت الغازات

حول العوامة العليا بجهاز البوخهلز وحيث يفصل جهاز الوقاية مفتاح تغذية المحول بالكهرباء فى حالة حدوث

قصر فى الدائرة واندفاع الغازات من المحول الى العوامة السفلية فى جهاز البوخهلز .

وتعمل دائرتا النذار والفصل على تيار تشغيل 220 الى 24أجهزة الوقاية عند العميل على جهد من

فولت تيار مستمر أو متردد.) يوضح توصيل جهاز البوخهلز 13شكل رقم (

بأجهزة النذار والفصل

8.8. To be sure that the tape changer is in the To be sure that the tape changer is in the required position .required position .

التأكد من تثبيت منظم الجهد فى الوضع المراد تشغيل التأكد من تثبيت منظم الجهد فى الوضع المراد تشغيل - - 88المحول عليه .المحول عليه .

9.9. In case of indoor installation of Trafo, the In case of indoor installation of Trafo, the dimensions of the Trafo room must be dimensions of the Trafo room must be suitable to the Trafo , size and aeration , air suitable to the Trafo , size and aeration , air ducts must be made in opposite ducts must be made in opposite directions .Covering the air ducts with a directions .Covering the air ducts with a metallic net is recommended metallic net is recommended

أن - - 99 فيراعمى المبانمى داخمل المحول تركيمب حالمة أن فى فيراعمى المبانمى داخمل المحول تركيمب حالمة فى كمما يحسن المحول لحجمم مناسمبة الغرفمة أبعاد كمما يحسن تكون المحول لحجمم مناسمبة الغرفمة أبعاد تكون عمل فتحات تهوية فى اتجاهين متضادين ويحسن أن عمل فتحات تهوية فى اتجاهين متضادين ويحسن أن

تغطى فتحات التهوية بشبكة معدنيةتغطى فتحات التهوية بشبكة معدنية

) يوضح توصيل جهاز البوخهلز بأجهزة النذار والفصل) يوضح توصيل جهاز البوخهلز بأجهزة النذار والفصل77شكل رقم (شكل رقم (

5.2Transformer tests:5.2Transformer tests: الختباراتالختبارات

routine tests are carried out according routine tests are carried out according to IEC standards :to IEC standards :

لمواصفات طبققا الروتينيقة الختبارات المحولت علقى لمواصفات تجرى طبققا الروتينيقة الختبارات المحولت علقى تجرى IECIEC: وتشمل : وتشمل

turns – ratio test turns – ratio test Insulation test between windings and Insulation test between windings and between winding and earth.between winding and earth.Induced high voltage test. Induced high voltage test. no – load losses test no – load losses test short circuit test short circuit test windings resistance measurementswindings resistance measurements

اختبار نسبة التحويلاختبار نسبة التحويل اختبار العزل بين الملفات وبعضها وبينها وبين اختبار العزل بين الملفات وبعضها وبينها وبين

الرض .الرض ..اختبار العزل بالجهد التأثيرى لكل حلقة من الملفات.اختبار العزل بالجهد التأثيرى لكل حلقة من الملفات اختبار قياس الفقد فىالقلب الحديدى فى حالة عدم وجود حمل اختبار قياس الفقد فىالقلب الحديدى فى حالة عدم وجود حمل اختبار قصر الدائرة اختبار قصر الدائرةقياس مقاومة الملفاتقياس مقاومة الملفات

5.2.1 upon request following 5.2.1 upon request following tests can be made :tests can be made :

حسب طلب العميل يمكن إجراء الختبارات التاليةحسب طلب العميل يمكن إجراء الختبارات التالية

loading and heat test loading and heat test resistance of insulation to impulse resistance of insulation to impulse

test test noise lvelnoise lvel

اختبار التحميل ودرجة الحرارةاختبار التحميل ودرجة الحرارةاختبار تحمل العزل للصدمات الكهربائيةاختبار تحمل العزل للصدمات الكهربائيةقياس مستوى الضوضاءقياس مستوى الضوضاء

6.16.1 Arrangement of distribution transformers Arrangement of distribution transformers The distribution transformers can be arranged centrally in one station or The distribution transformers can be arranged centrally in one station or in a number of sub – stations distributed over the whole load area .in a number of sub – stations distributed over the whole load area .As a rule they should be placed at the centers of load thus the length of As a rule they should be placed at the centers of load thus the length of cables cross section of conductors and losses are kept within economic cables cross section of conductors and losses are kept within economic limits .limits .The centrally arranged system used for distribution systems where only The centrally arranged system used for distribution systems where only small extension of the area is likely and load intensity is high .small extension of the area is likely and load intensity is high .the load equalization occurs mainly on the low tension side on the bus the load equalization occurs mainly on the low tension side on the bus bars see fig (8)* in calculating the rated power of distribution bars see fig (8)* in calculating the rated power of distribution transformer .transformer .

Fig no (8)Fig no (8)Centrally Arranged distributionCentrally Arranged distribution Transformers in a sub-stationTransformers in a sub-station

6.2 6.2 Some requirements for operation :- Some requirements for operation :-

The peak load of the whole distribution system taking into account a The peak load of the whole distribution system taking into account a reserve in the event of one transformer being out of order the reserve in the event of one transformer being out of order the transformers should if possible be equal in size to facilitate operation transformers should if possible be equal in size to facilitate operation in parallel and interchangeability.in parallel and interchangeability.The decent tralized arrangement of distribution transformers is of ten The decent tralized arrangement of distribution transformers is of ten favored for wide supply area and for widely distributed centers of favored for wide supply area and for widely distributed centers of load neighborly substation can then be connected by ri ng main on load neighborly substation can then be connected by ri ng main on the low voltage side in this way load equalization between the sub the low voltage side in this way load equalization between the sub station Can be achieved and the supply can be maintained when station Can be achieved and the supply can be maintained when one of the transformers on the high voltage side of substation is out one of the transformers on the high voltage side of substation is out of order.of order.if necessary several transformers may be required as reserve , as if necessary several transformers may be required as reserve , as shown in fig ( 9 ) and fig ( 10 ) and fig (11 ) .shown in fig ( 9 ) and fig ( 10 ) and fig (11 ) .

Fig no (9)Fig no (9)Decentralized arrangement of distributionDecentralized arrangement of distribution

Transformers in several sub-stationsTransformers in several sub-stations

Fig no (10)Fig no (10)Ring-main system with ring Ring-main system with ring Circuit looped between sub-Circuit looped between sub-

stationsstations

Fig no (11)Fig no (11)diagram of ring-main diagram of ring-main system.system.a) Ring –main system a) Ring –main system with two ring circuitswith two ring circuitsb) Ring-main system with b) Ring-main system with terminal stationterminal station

6.3 6.3 Peculiarities of high voltage ring system:Peculiarities of high voltage ring system: this simple way to loop ring circuits into substations is via load break isolators this simple way to loop ring circuits into substations is via load break isolators the ring circuit can be opened at convenient points to confine a fault to a part the ring circuit can be opened at convenient points to confine a fault to a part of the circuit only ( e.g in substation b3 ) fig (12)*of the circuit only ( e.g in substation b3 ) fig (12)*By means of short circuit indicators in each sub-station affected can be By means of short circuit indicators in each sub-station affected can be determined thus the faulty section of the circuit can be readily found and determined thus the faulty section of the circuit can be readily found and isolated.isolated.

After isolating the faulty cable run at (d) ( worst fault condition ) & closing the After isolating the faulty cable run at (d) ( worst fault condition ) & closing the isolating point in substation b3 , normal service can be resumed under the isolating point in substation b3 , normal service can be resumed under the worst fault condition , with the fault in cable run ( d ) between the ring supply worst fault condition , with the fault in cable run ( d ) between the ring supply and the first substation the remaining cable has to supply current to the whole and the first substation the remaining cable has to supply current to the whole ring circuit and must therefore be rated for single supply if there is a load ring circuit and must therefore be rated for single supply if there is a load center with high load demand opposite the transfer station ( e.g a university , center with high load demand opposite the transfer station ( e.g a university , hospital in a rural area ) , it will found advantageous to provides a ring main hospital in a rural area ) , it will found advantageous to provides a ring main system with a terminal substation at the load center . this would ensure good system with a terminal substation at the load center . this would ensure good load equalization and high security of supply to, all sub station yet the number load equalization and high security of supply to, all sub station yet the number of ring circuits will be less fig. (11) of ring circuits will be less fig. (11)

6.46.4 Parallel operation: Parallel operation:

transformers will operate in parallel when they are connected to the same network transformers will operate in parallel when they are connected to the same network system, both on the high voltage as well as on the low voltage side .system, both on the high voltage as well as on the low voltage side .slight different conditions apply between operation in parallel bus bars and operation slight different conditions apply between operation in parallel bus bars and operation in parallel on systems networks .in parallel on systems networks .

6.5 6.5 general requirements for parallel operation :general requirements for parallel operation :

for satisfactory operation in parallel , especially on bus bars the following general for satisfactory operation in parallel , especially on bus bars the following general requirements apply ;requirements apply ; For transformers having the same vector group and clock hour number, terminals For transformers having the same vector group and clock hour number, terminals

having identical designations are paralleled . having identical designations are paralleled . The ratio of transformation must be identical .The ratio of transformation must be identical . All taping must have identical values on each transformer .All taping must have identical values on each transformer . The rated impeadence voltage must be practically the same within 10 % , the The rated impeadence voltage must be practically the same within 10 % , the

transformer with the smaller rated power should have the higher rated transformer with the smaller rated power should have the higher rated impeadence voltage , if possible the ratio of the rated power of transformers impeadence voltage , if possible the ratio of the rated power of transformers working in parallel should not be more than3:1 .working in parallel should not be more than3:1 .

for checking the phase relationship the 2N-terminal of the transformer to be for checking the phase relationship the 2N-terminal of the transformer to be connected to the transformer to be connected is connected to the 1N bus bar of the connected to the transformer to be connected is connected to the 1N bus bar of the system the phase relation is then check by using a voltmeter if the connection is system the phase relation is then check by using a voltmeter if the connection is correct the voltmeter will indicate zero , if the connection is correct the voltmeter correct the voltmeter will indicate zero , if the connection is correct the voltmeter will indicate values values of up to twice the phase voltage fig (13) * .will indicate values values of up to twice the phase voltage fig (13) * .

Fig no ( 13 )Fig no ( 13 )

6.6 6.6 Protection by fuses ( short circuit protection ) :Protection by fuses ( short circuit protection ) :

Distribution transformers are normally protected against short circuits by high Distribution transformers are normally protected against short circuits by high voltage H.R.C- fuses ( table No 5 ) can be used for the selection of fuses for voltage H.R.C- fuses ( table No 5 ) can be used for the selection of fuses for distribution transformers ; the maximum current inrush when switching on the distribution transformers ; the maximum current inrush when switching on the transformer has been taken into consideration .transformer has been taken into consideration .

Table no (5)Table no (5)Guiding values for the ratingGuiding values for the rating Of high-voltageOf high-voltage HRC-fusesHRC-fuses

6.7 Over load protection:6.7 Over load protection:

the over load protection of transformers is provided on the low voltage side the over load protection of transformers is provided on the low voltage side . the low voltage H.R.C- fuses or the thermally delayed over current trips . the low voltage H.R.C- fuses or the thermally delayed over current trips of the circuit breakers are selected according to the rated current IN of the of the circuit breakers are selected according to the rated current IN of the transformer . this selection normally provides adequate selectivity between transformer . this selection normally provides adequate selectivity between high – voltage and low voltage side . high – voltage and low voltage side .

6.8 Short circuit strength:6.8 Short circuit strength:

Distribution transformers need to be designed to with stand the effects of Distribution transformers need to be designed to with stand the effects of external short circuits with out damage .external short circuits with out damage .

Steady state R.M.S short circuit currentSteady state R.M.S short circuit current II..KK : :

The short circuit current Ik of a transformer is the steady state R.M.S. The short circuit current Ik of a transformer is the steady state R.M.S. value of current at the terminals following on all phases short circuit on the value of current at the terminals following on all phases short circuit on the terminals of the outgoing side and when the D.C component has decayed terminals of the outgoing side and when the D.C component has decayed with constant rated voltage applied to the input terminals . with constant rated voltage applied to the input terminals .

Calculation of steady state R.M.S short circuit current :Calculation of steady state R.M.S short circuit current :

For transformer operating at rated voltage & rated frequency and tappings For transformer operating at rated voltage & rated frequency and tappings adjusted to the principal tap , the continuous short circuit current Ik can be adjusted to the principal tap , the continuous short circuit current Ik can be calculated from the rated current IN & the rated impeadence voltage UKN . calculated from the rated current IN & the rated impeadence voltage UKN .

IN = rated current in A .IN = rated current in A .

UKN = rated independence voltage in % .UKN = rated independence voltage in % .For the calculation of short circuit currents of installation systems , the For the calculation of short circuit currents of installation systems , the

resistance of the system must be taken into consideration . for calculation of resistance of the system must be taken into consideration . for calculation of short – circuit current in three phase systems .short – circuit current in three phase systems .

6.11 Maximum permissible duration of short circuit :6.11 Maximum permissible duration of short circuit :

For values of Ik and time duration see table ( 6 ) the peak short circuit For values of Ik and time duration see table ( 6 ) the peak short circuit current is important in considering the dynamic stresses in the transformer & current is important in considering the dynamic stresses in the transformer & other operating equipment affected by the fault .other operating equipment affected by the fault .The peak short circuit current “ IS “ of a transformer is the first peak The peak short circuit current “ IS “ of a transformer is the first peak maximum transient value of current at the terminals of the outgoing side . maximum transient value of current at the terminals of the outgoing side . The first peak value of current Ik is the The first peak value of current Ik is the multiple of the R.M.S short multiple of the R.M.S short circuit current IKcircuit current IK

A.in current circuit short R.M.S k =I

2 X

table no (6) table no (6) Values of Ik and time of durationValues of Ik and time of duration

2 X

2 I I KS ×=

. ) peak value (A in current circuit short peak I S =.A in current circuit short R.M.S epermissibl maximum IK =

.factor impulse 2 X =

6.12 Calculation of the peak short circuit current Is :6.12 Calculation of the peak short circuit current Is :

The permissible peak short circuit current Is of a transformer is :The permissible peak short circuit current Is of a transformer is :

Where : Where :

Impulse factor : the impulse factor of the reactance X to the Ohmeic resistance R , ( Impulse factor : the impulse factor of the reactance X to the Ohmeic resistance R , ( i.e ) dependent on the ratio of the reactance voltage Ui.e ) dependent on the ratio of the reactance voltage Uxx to the resistive voltage drop UR to the resistive voltage drop UR of the transformer . of the transformer .

Maintenance work is permitted only when the transformer is switched off and the Maintenance work is permitted only when the transformer is switched off and the terminals earthed .terminals earthed .

7.17.1 Dry type transformers: Dry type transformers:

Dry type transformers must be kept dust free & protected against pollution . at Dry type transformers must be kept dust free & protected against pollution . at regular intervals these should be cleaned with bellows or a vacuum cleaner . regular intervals these should be cleaned with bellows or a vacuum cleaner . terminals and bolted joints should also be checked regularly .terminals and bolted joints should also be checked regularly .

Drying out :Drying out :

The insulation resistance between windings & also windings to earth provides good The insulation resistance between windings & also windings to earth provides good indication of the condition of the insulation especially when a transformer has been indication of the condition of the insulation especially when a transformer has been out of service over a long period and many have absorbed moisture . subsequent out of service over a long period and many have absorbed moisture . subsequent drying out may therefore be necessary .drying out may therefore be necessary .

The insulation resistance at room temperature should not less than The insulation resistance at room temperature should not less than

For operating voltage: For operating voltage: Up to 1000 v 15 m. ohm.Up to 1000 v 15 m. ohm. Above 1000 v 25 m. ohmAbove 1000 v 25 m. ohm Above 5000 v 40 m. ohm .Above 5000 v 40 m. ohm .

The insulation resistance is normally measure with 1000 V or 2000 V instrumentThe insulation resistance is normally measure with 1000 V or 2000 V instrument

If the insulation resistance is below the above recommended values it can be assumed If the insulation resistance is below the above recommended values it can be assumed that moisture has been observed by the insulation .that moisture has been observed by the insulation .

7.3 The winding can be dried out as follows :7.3 The winding can be dried out as follows :

By heating in a drying oven at a temperature of approx. 80°C or with heaters By heating in a drying oven at a temperature of approx. 80°C or with heaters such as incandescent lamps , resister elements or radiators . the surface of the such as incandescent lamps , resister elements or radiators . the surface of the windings must not exceed 100°C when using direct radiation .windings must not exceed 100°C when using direct radiation .heating under short – circuit conditions with a maximum rated current the output heating under short – circuit conditions with a maximum rated current the output side of the transformer is short – circuited and the input side connected to a side of the transformer is short – circuited and the input side connected to a voltage approximately equal to the impedance voltage .voltage approximately equal to the impedance voltage .this voltage is adjusted such that the current flowing does not exceed the rated this voltage is adjusted such that the current flowing does not exceed the rated current stated on the nameplate is exceeded during drying the room must be current stated on the nameplate is exceeded during drying the room must be well ventilated during dying process . the value of insulation resistance should well ventilated during dying process . the value of insulation resistance should be measured repeatedly .be measured repeatedly .

7.27.2 Renovation of the operating room : Renovation of the operating room :During renovation work in the transformer room the transformer should be During renovation work in the transformer room the transformer should be switched off and earthed . switched off and earthed . It is important , particularly with dry type transformer to cover carefully to protect It is important , particularly with dry type transformer to cover carefully to protect from dust , paint , humidity and other pollution , when building and painting work from dust , paint , humidity and other pollution , when building and painting work is in process , the room must be well ventilated and if necessary heated .is in process , the room must be well ventilated and if necessary heated .Cast resin transformers are largely maintenance free and do not require drying .Cast resin transformers are largely maintenance free and do not require drying .

7.37.3 Oil – immersed transformers : Oil – immersed transformers :

the type of fluid used is stated on the rating plate .the maintenance of this the type of fluid used is stated on the rating plate .the maintenance of this type of transformer includes :type of transformer includes : Checking the level of fluid at the sight glass .Checking the level of fluid at the sight glass . Checking effectiveness of gaskets and quality of paint finish .Checking effectiveness of gaskets and quality of paint finish . Testing the insulating fluid of moisture content and checking or Testing the insulating fluid of moisture content and checking or

reactivating the silica – gel in the breather .reactivating the silica – gel in the breather .To check the moisture content of the insulating fluid a sample must be taken To check the moisture content of the insulating fluid a sample must be taken

to ensure that the measurement corresponds to the actual conditions of the to ensure that the measurement corresponds to the actual conditions of the fluid within the transformer , special care the highest degree of clean lines fluid within the transformer , special care the highest degree of clean lines is required when taking samples .is required when taking samples .1.1. A specimen bottle with large opening and glass stopper ( not cork ) is A specimen bottle with large opening and glass stopper ( not cork ) is

required required 2.2. The bottle must be cleaned with clean alcohol and well dried .The bottle must be cleaned with clean alcohol and well dried .3.3. The drain cook must be carefully cleaned and dried before taking a test The drain cook must be carefully cleaned and dried before taking a test

sample . sample . 4.4. The specimen bottle should be approximately half filled with the fluid The specimen bottle should be approximately half filled with the fluid

and rinsed with this fluid before a test sample is taken .and rinsed with this fluid before a test sample is taken ...

7.47.4 break down voltage : break down voltage : Eleven samples should be taken and a break down voltage test made with Eleven samples should be taken and a break down voltage test made with electrodes having a 2 – 5 mm gap for each sample the break down electrodes having a 2 – 5 mm gap for each sample the break down voltage test is repeated six times with a 2 minute interval between each . voltage test is repeated six times with a 2 minute interval between each . the break down voltage is the mean value of the results of tests 2 to 6 . the break down voltage is the mean value of the results of tests 2 to 6 . the transformers of insulation rating up to 30 k.v. the mean value the transformers of insulation rating up to 30 k.v. the mean value acceptable is for new oil or a skarel 60 k.v. minimum and for used oil 30 acceptable is for new oil or a skarel 60 k.v. minimum and for used oil 30 k. v. minimum .k. v. minimum .if the measured values fall below the above mentioned minimum values if the measured values fall below the above mentioned minimum values the insulating fluid must be changed or re conditional by use of special the insulating fluid must be changed or re conditional by use of special filter presses or for small trans formers the complete transformer can be filter presses or for small trans formers the complete transformer can be dried under vacuum the manufacturers of transformers and the electricity dried under vacuum the manufacturers of transformers and the electricity boards have the necessary plant and devices for the conditioning and boards have the necessary plant and devices for the conditioning and drying of the insulating fluid .drying of the insulating fluid .for refilling is necessary the fluid used must be identical to the original it for refilling is necessary the fluid used must be identical to the original it is recommended to test the new fluid for break down voltage before is recommended to test the new fluid for break down voltage before refilling refilling