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TransformerTransformer

Muhamad Zahim SujodExt : 2312A1-01-06

zahim@ump.edu.my

BEE2123 ELECTRICAL MACHINES

BEE2123 ELECTRICAL MACHINES

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Learning OutcomesLearning Outcomes

At the end of the lecture, student should to: Understand the principle and the nature of principle and the nature of

static machines of transformer.static machines of transformer.

Perform an analysis on transformers which their principles are basic to the understanding of electrical machineselectrical machines.

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IntroductionIntroduction A transformer is a static machinesstatic machines. The word ‘The word ‘transformertransformer’ comes form the word ‘’ comes form the word ‘transformtransform’.’. Transformer is not an energy conversion devicenot an energy conversion device, but is a

device that device that changeschanges AC electrical power at one voltage AC electrical power at one voltage level into AC electrical power at another voltage level level into AC electrical power at another voltage level through the action of magnetic field, without a change in through the action of magnetic field, without a change in frequency. frequency.

It can be either to It can be either to step-upstep-up or or step downstep down..

Generation Generation StationStation

TX1 TX1

DistributionsDistributions

TX1

TX1

Transmission Transmission SystemSystem

33/13.5kV33/13.5kV 13.5/6.6kV13.5/6.6kV

6.6kV/415V6.6kV/415V

ConsumerConsumer

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Transformer Construction Two types of iron-core construction:

a) Core - type construction

b) Shell - type construction

Core - type construction

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Transformer Construction

Shell - type construction

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Ideal Transformer

An ideal transformer is a transformer which has no loseswhich has no loses, i.e. it’s winding has no ohmic resistance, no magnetic leakage, and therefore no I2 R and core loses.

However, it is impossibleimpossible to realize such a transformer in practice.

Yet, the approximate characteristic of ideal transformer will approximate characteristic of ideal transformer will be used in characterized the practical transformer.be used in characterized the practical transformer.

VV11 VV22

NN1 1 : N: N22

EE11 EE22

II11 II22

VV11 – Primary Voltage – Primary Voltage

VV22 – Secondary Voltage – Secondary Voltage

EE11 – Primary induced Voltage – Primary induced Voltage

EE22 – secondary induced Voltage – secondary induced Voltage

NN11:N:N22 – Transformer ratio – Transformer ratio

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Transformer Equation

Faraday’s Law states that, If the flux passes through a coil of wire, a voltage will be

induced in the turns of wire. This voltage is directly proportional to the rate of change in the flux with respect of time.

If we have NN turns of wire,

dt

tdEmfV indind

)(

dt

tdNEmfV indind

)(

Lenz’s Law

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Transformer Equation

For an ac sources, Let V(t) = Vm sint

i(t) = im sint

Since the flux is a sinusoidal function;

Then:

Therefore:

Thus:

tt m sin)(

tNdt

tdNEmfV

m

mindind

cos

sin

mmindind fNNEmfV 2(max)

mmm

rmsind fNfNN

Emf

44.42

2

2)(

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Transformer Equation For an ideal transformer

In the equilibrium condition, both the input power will be equaled to the output power, and this condition is said to ideal condition of a transformer.

From the ideal transformer circuit, note that,

Hence, substitute in (i)

m

m

fNE

fNE

22

11

44.4

44.4

1

2

2

1

2211 coscos

I

I

V

V

IVIV

poweroutputpowerInput

………………… (i)

2211 VEandVE

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Transformer Equation

aI

I

N

N

E

ETherefore

1

2

2

1

2

1,

Where, ‘aa’ is the Voltage Transformation RatioVoltage Transformation Ratio; which will determine whether the transformer is going to be step-up or step-down

EE11 > E > E22For a >1For a >1

For a <1For a <1 EE11 < E < E22

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Transformer Rating

Transformer rating is normally writtenwritten in terms of Apparent Apparent PowerPower.

Apparent power is actually the product of its rated current its rated current and rated voltageand rated voltage.

2211 IVIVVA Where,

I1 and I2 = rated current on primary and secondary winding.

V1 and V2 = rated voltage on primary and secondary winding.

Rated currents are actually the Rated currents are actually the full load currentsfull load currents in in transformertransformer

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Example

1. 1.5kVA single phase transformer has rated voltage of 144/240 V. Finds its full load current.SolutionSolution

AI

AI

FL

FL

6240

1500

45.10144

1500

2

1

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Example

2. A single phase transformer has 400 primary and 1000 secondary turns. The net cross-sectional area of the core is 60m2. If the primary winding is connected to a 50Hz supply at 520V, calculate:a) The induced voltage in the secondary winding

b) The peak value of flux density in the core

SolutionSolution

N1=400 V1=520V A=60m2

N2=1000 V2=?

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Example 2 (Cont)a) Know that,

b) Emf,

2

520

1000

400

V

2

1

2

1

V

V

N

Na

VV 13002

2

21

/976.0

)60)()(400)(50(44.4520

44.4

1300,520,

44.4

44.4

mWbB

B

ABfNE

VEVEknown

ABfN

fNE

m

m

m

m

m

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Example

3. A 25kVA transformer has 500 turns on the primary and 50 turns on the secondary winding. The primary is connected to 3000V, 50Hz supply. Find:

a) Full load primary current

b) The induced voltage in the secondary winding

c) The maximum flux in the core

SolutionSolution

VA = 25kVA

N1=500 V1=3000V

N2=50 V2=?

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Example 3 (Cont)a) Know that,

b) Induced voltage,

c) Max flux

VI

IEE

AI

I

I

N

Na

3003.83

33.83000

3.8350

33.8500

2

112

2

1

2

2

1

AV

VAI

IVVA

FL 33.83000

1025 3

11

mWb

fNE

27

)50)(50(44.4300

44.4

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Practical Transformer (Equivalent Circuit)

V1 = primary supply voltage

V2 = 2nd terminal (load) voltage

E1 = primary winding voltage

E2 = 2nd winding voltage

I1 = primary supply current

I2 = 2nd winding current

I1’ = primary winding current

Io = no load current

Ic = core current

Im = magnetism current

R1= primary winding resistance

R2= 2nd winding resistance

X1= primary winding leakage reactance

X2= 2nd winding leakage reactance

Rc= core resistance

Xm= magnetism reactance

VV11

II11 RR11XX11

RRCC

IIcc

XXmm

IImm

IIoo

EE11 EE22

VV22

II11’’

NN11: N: N22

RR22

XX22

LoadLoad

II22

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Single Phase Transformer (Referred to Primary) Actual MethodActual Method

22

22

2

2

12 '' RaRORR

N

NR

22

22

2

2

12 '' XaXORX

N

NX

a

II

aVVORVN

NVE

22

2222

1'21

'

'

VV11

II11 RR11 XX11

RRCC

IIcc

XXmm

IImm

IIoo

EE11 EE22 VV22

II22’’ NN11: N: N22

RR22’’ XX22

’’

Load

II22

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Single Phase Transformer (Referred to PrimaryPrimary) Approximate MethodApproximate Method

22

22

2

2

12 '' RaRORR

N

NR

VV11

II11 RR11XX11

RRCC

IIcc

XXmm

IImm

IIoo

EE11 EE22 VV22

II22’’ NN11: N: N22RR22

’’ XX22’’

Load

II22

22

22

2

2

12 '' XaXORX

N

NX

a

II

aVVORVN

NVE

22

2222

1'21

'

'

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Single Phase Transformer (Referred to PrimaryPrimary) Approximate MethodApproximate Method

22

22

2

2

12 '' RaRORR

N

NR

VV11

II11RR0101 XX0101

aVaV22

22

22

2

2

12 '' XaXORX

N

NX

'

'

2101

2101

XXX

RRR

2222

1'2 ' aVVORV

N

NV

In some application, the excitation branch has a small current compared to load current, thus it may be neglected without causing serious error.

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Single Phase Transformer (Referred to SecondarySecondary) Actual MethodActual Method

21

11

2

1

21 ''

a

RRORR

N

NR

a

VVORV

N

NV 1

111

21 ''

I1’ R1’X1’

RC’

Ic

Xm’

Im

Io

I2 R2

X2

VV22

21

11

2

1

21 ''

a

XXORX

N

NX

a

V1

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Single Phase Transformer (Referred to SecondarySecondary) Approximate MethodApproximate Method

21

11

2

1

21 ''

a

XXORX

N

NX

2102

2102

'

'

XXX

RRR

II11’’ RR0202 XX0202

VV22

a

V1

21

11

2

1

21 ''

a

RRORR

N

NR

a

VVORV

N

NV 1

111

21 ''

11 ' aII

Neglect the excitation branch

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Example

4. For the parameters obtained from the test of 20kVA 2600/245 V single phase transformer, refer all the parameters to the high voltage side if all the parameters are obtained at lower voltage side.

Rc = 3.3, Xm =j1.5, R2 = 7.5, X2 = j12.4

Solution

Given

Rc = 3.3, Xm =j1.5,

R2 = 7.5, X2 = j12.4

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Example 4 (Cont)

i) Refer to H.V side (primary)

R2’=(10.61)2 (7.5) = 844.65,

X2’=j(10.61)2 (12.4) = 1.396k

Rc’=(10.61)2 (3.3) = 371.6,

Xm’=j(10.61)2 (1.5) = j168.9

61.10245

2600

2

1

2

1 V

V

E

Ea

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Power Factor

Power factor = angle between Current and angle between Current and voltagevoltage, cos

V

I

= -veV

I

= +ve

VI

= 1

Lagging Leading unity

Power factor always lagging for real transformer.

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Example

5. A 10 kVA single phase transformer 2000/440V has primary resistance and reactance of 5.5 and 12 respectively, while the resistance and reactance of secondary winding is 0.2 and 0.45 respectively. Calculate:

i. The parameter referred to high voltage side and draw the equivalent circuit

ii. The approximate value of secondary voltage at full load of 0.8 lagging power factor, when primary supply is 2000V.

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Example 5 (Cont)

SolutionSolution

R1=5.5 , X1=j12

R2=0.2 , X2=j0.45

i) Refer to H.V side (primary)

R2’=(4.55)2 (0.2) = 4.14,

X2’=j(4.55)20.45 = j9.32

Therefore,

R01=R1+R2’=5.5 + 4.13 = 9.64

X01=X1+X2’=j12 + j9. 32 = j21.32

55.4440

2000

2

1

2

1 V

V

E

Ea

V1 aV2

R01 X01

21.329.64

I1

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Example 5 (Cont)

SolutionSolution

ii) Secondary voltage

p.f = 0.8

Cos = 0.8

=36.87o

Full load,

From eqn. cct,

AV

VAIFL 5

2000

1010 3

1

o

oo

oo

V

Vj

aVIjXRV

8.06.422

)55.4()87.365)(32.2164.9(02000

))((0

2

2

2101011

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Transformer Losses Generally, there are two types of losses;

i.i. Iron lossesIron losses :- occur in core parameters

ii.ii. Copper lossesCopper losses :- occur in winding resistance

i.i. Iron LossesIron Losses

ii.ii. Copper LossesCopper Losses

circuitopenccciron PRIPP 2)(

022

2012

1

22

212

1

)()(,

)()(

RIRIPreferredifor

PRIRIPP

cu

circuitshortcucopper

Poc and Psc will be discusses later in transformer test

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Transformer Efficiency

To check the performance of the device, by comparing the output with respect to the input.

The higher the efficiency, the better the system.

%100cos

cos

%100

%100,

22

22

cuc

lossesout

out

PPIV

IV

PP

P

PowerInput

PowerOutputEfficiency

%100cos

cos

%100cos

cos

2)(

)(

cucnload

cucloadfull

PnPnVA

nVA

PPVA

VA

Where, if ½ load, hence n = ½ ,½ load, hence n = ½ , ¼ load, n= ¼ ,¼ load, n= ¼ , 90% of full load, n =0.990% of full load, n =0.9Where Pcu = Psc

Pc = Poc

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Voltage Regulation

The purpose of voltage regulation is basically to determine the percentage of voltage drop between no load and full load.

Voltage Regulation can be determine based on 3 methods:

a) Basic Defination

b) Short – circuit Test

c) Equivalent Circuit

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Voltage Regulation (Basic Defination)

In this method, all parameter are being referred to primary or secondary side.

Can be represented in either Down – voltage Regulation

Up – Voltage Regulation

%100.

NL

FLNL

V

VVRV

%100.

FL

FLNL

V

VVRV

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Voltage Regulation (Short – circuit Test)

In this method, direct formula can be used.

%100

cos.

1

. V

VRV fpscsc

If referred to primary side

%100

cos.

2

. V

VRV fpscsc

If referred to secondary side

Note that:Note that:

‘–’ is for Lagging power factor‘+’ is for Leading power factor Isc must equal to IFL

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Voltage Regulation (Equivalent Circuit )

In this method, the parameters must be referred to primary or secondary

%100

sincos.

1

.01.011

V

XRIRV fpfp If referred to

primary side

If referred to secondary side

Note that:Note that:

‘+’ is for Lagging power factor‘–’ is for Leading power factor j terms ~0

%100

sincos.

2

.02.022

V

XRIRV fpfp

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Example

6. In example 5, determine the Voltage regulation by using down – voltage regulation and equivalent circuit.

SolutionSolution

Down – voltage Regulation

Know that, V2FL=422.6V

V2NL=440V

Therefore,

%95.3

%100440

6.422440

%100.

NL

FLNL

V

VVRV

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Example 6 (Cont)

Equivalent Circuit

I1=5A R01=9.64 X01 = 21.32 V1=2000V, 0.8 lagging p.f

%12.5

%1002000

)6.0(32.21)8.0(64.95

%100sincos

.1

.01.011

V

XRIRV fpfp

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Example

7. A short circuit test was performed at the secondary side of 10kVA, 240/100V transformer. Determine the voltage regulation at 0.8 lagging power factor if

Vsc =18V

Isc =100

Psc=240W

SolutionSolutionCheck: Check:

Hence, we can use short-circuit methodHence, we can use short-circuit method

,

100100

10000

2

2

scFL

FL

II

AV

VAI

%100

cos.

2

. V

VRV fpscsc

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Example 7 (Cont)

o

scsc

scsc

scscscsc

ofp

fpscsc

IV

P

IVP

thatKnow

Hence

fpGiven

V

VRV

34.82)100)(18(

240cos

cos

cos

,

87.368.0cos,

8.0.

%100cos

.

1

1

1.

2

.

%62.12

%100100

87.3634.82cos18.

oo

RV

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Example

8. The following data were obtained in test on 20kVA 2400/240V, 60Hz transformer.

Vsc =72V

Isc =8.33A

Psc=268W

Poc=170W

The measuring instrument are connected in the primary side for short circuit test. Determine the voltage regulation for 0.8 lagging p.f. (use all 3 methods), full load efficiency and half load efficiency.

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Example 8 (Cont)

.72.786.34.6364.8

64.833.8

72

4.63)33.8)(72(

268cos

cos

cos

,

87.368.0cos,

8.0.

%100cos

.

0101

1

1

1.

2

.

sideprimarytoconnectedbecausejXRjZ

I

VZ

IV

P

IVP

thatKnow

Hence

fpGiven

V

VRV

osc

sc

scsc

o

scsc

scsc

scscscsc

ofp

fpscsc

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Example 8 (Cont)

%68.2%100

2400

)6.0(72.7)8.0(86.32400

20000

%100sincos

.,.2

%68.2%1002400

87.364.63cos72.

%100cos

.,.1

1

.01.011

1

.

V

XRIRVcircuitEquivalent

RV

V

VRVmethodCircuitShort

fpfp

oo

fpscsc

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Example 8 (Cont)

%68.2

%100240

58.233240

%100.

79.058.233

240

24004.6364.887.36

2400

2000002400

,.3

2

2

20111

NL

FLNL

o

ooo

V

VVRV

VV

V

aVZIV

DefinationBasic

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Example 8 (Cont)

%12.97%100)268()5.0(170)8.0)(20000)(5.0(

)8.0)(20000)(5.0(

%34.97%100)268()1(170)8.0)(20000)(1(

)8.0)(20000)(1(

2)(

2)(

loadhalf

loadfull

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Measurement on Transformer

There are two test conducted on transformer.i.i. Open Circuit TestOpen Circuit Test

ii.ii. Short Circuit testShort Circuit test

The test is conducted to determine the parameter of to determine the parameter of the transformerthe transformer.

Open circuit testOpen circuit test is conducted to determine magnetism parameter, RRcc and X and Xmm.

Short circuit testShort circuit test is conducted to determine the copper parameter depending where the test is performed. If performed at primary, hence the parameters are RR0101 and XX0101 and vice-versavice-versa.

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Open-Circuit Test

Measurement are at high voltage sidehigh voltage side From a given test parameters,

Rc Xm

Voc

Ic Im

Voc

Ioccosoc

Ioc

Voc

Ic

Im

Iocsinoc

oc

Note:If the question asked parameters referred to question asked parameters referred to Low voltage sideLow voltage side, the parameters (Rc and Xm) obtained

need to be referred to low voltage sideneed to be referred to low voltage side m

ocm

c

occ

mc

ococm

ococc

ococ

ococ

ococococ

I

VX

I

VR

XandRThen

II

II

Hence

IV

P

IVP

,

,,

sin

cos

,

cos

cos

1

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Short-Circuit Test

Measurement are at low voltage sideat low voltage side If the given test parameters are taken on primary taken on primary

side, Rside, R0101 and X and X0101 will be obtained will be obtained. Or else, vice-versa.

X01R01

For a case referred to Primary side

010101

01

1

,

cos

cos

jXRZ

I

VZ

Hence

IV

P

IVP

scsc

sc

scsc

scsc

scscscsc

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Example

9. Given the test on 500kVA 2300/208V are as follows:

Poc = 3800W Psc = 6200W

Voc = 208V Vsc = 95V

Ioc = 52.5A Isc = 217.4A

Determine the transformer parameters and draw equivalent circuit referred to high voltage side. Also calculate appropriate value of V2 at full load, the full load efficiency, half load efficiency and voltage regulation, when power factor is 0.866 lagging.

[1392, 517.2, 0.13, 0.44, 202V, 97.74%, 97.59%, 3.04%]

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Example 9 (Cont)

A

II

A

II

IVP

o

ococm

o

ococc

ooc

ococococ

2.49

6.69sin5.52

sin

26.18

6.69cos5.52

cos

6.69)208)(5.52(

3800cos

cos

1

Ioccosoc

Ioc

Voc

Ic

Im

Iocsinoc

oc

From Open Circuit Test,

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Example 9 (Cont)

23.421.49

208

39.1126.18

208

m

ocm

c

occ

I

VX

I

VR

Since Voc=208Vall reading are taken on the secondary side

Parameters referred to high voltage side,

21.517208

230023.4'

1392208

230039.11'

22

2

1

22

2

1

E

EXX

E

ERR

mm

cc

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Example 9 (Cont)

AV

VAIFL 4.217

2300

10500 3

11

osc

scscscsc IVP

53.72)4.217)(95(

6200cos

cos

1

From Short Circuit Test,

First, check the First, check the IIscsc

Since IFL1 =Isc , all reading are actually taken on the primary side

42.013.0

53.7244.053.724.217

95

01

j

I

VZ

oo

scsc

sc

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Example 9 (Cont)

Equivalent circuit referred to high voltage side,

VV22’=aV’=aV22VV11

RRcc

13921392 XXmm

517.21517.21

RR0101

0.130.13 XX0101

0.420.42

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Example 9 (Cont)

Efficiency,

%59.97

%1003800)5.0)(6200()866.0)(10500)(5.0(

)866.0)(10500)(5.0(

%100cos

cos

%74.97

%10038006200)866.0)(10500(

)866.0)(10500(

%100cos

cos

23

3

22

1

3

3

ocscL

ocscFL

PPnnVA

nVA

PPVA

VA

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Example 9 (Cont)

Voltage Regulation,

%04.3

%1002300

3053.72cos)95(

%100cos

.1

E

VRV pfscsc