Transformer design

TRANSFORMER DESIGN : CALCULATIONS SHEET: SPECIFICATIONS AND DESIGN DATA: KVA= Vp(line)= Vs(line)= frequency= phases=

1000 11000 430 50 3

KV V Hz

connection= Type:

Delta-Star   Core type, Distribution

Tappings: Temperature rise: %impedance=

2.5% - 5% <=40 deg < 5%

CALCULATIONS: Taking value of k, for distribution transformers as:

k=

0.45

Voltage per turn :

Et=

14.2302495 V

therefore flux in core is:

fm=

0.06 .06410022 Wb

Taking the flux density as:

Bm =

1.6

Thus the iron area required is:

Ai=

0.04006264 m^2

Take stacking factor (for cold rolled grain oriented steel)

k s=

0.97

Gross iron Area available is:

Ag=

0.04130169 m^2

W b/m^2

CORE DESIGN: Per phase primary: Per phasesecondary:

Taking a 6 step core :

Diameter of circumscribing circle:

Modified values of

Voltage: Current: Voltage: Current:

V(H.V)ph= I(H.V)ph= V(L.V)ph= I(L.V)ph=

11000 30.3030303 248.260616 1342.67504

k 1=

0.92

d=

 Actual 0.23908072 m

Taken 240

mm

a= b= c= d= e= f=

0.22951749 0.21158643 0.18528756 0.15085993 0.11117253 0.05977018

230 212 186 151 112 60

mm mm mm mm mm mm

iron area: Ai '= flux density: Bm'=

KV A KV A

m m m m m m

0.04037132 m^2 1.58776636

WINDOW AND AND YOKE DESIGN:

 Take Window space Factor as: Selecting Current Density: W indow area required by Output Equation:

Kw= d= Aw=

0.3 2.75 A/mm^2 0.11357226 m^2

Selecting Height to Width Ratio as:

Hw/Ww=

2.5

Window Height: Window Width:

Hw= Ww=

0.53285144 m @ 0.21314057 m @

Distance Between Limbs;

D=

455

mm

Taking the Yoke also to be 6 stepped: Height of yoke: Depth Of Yoke:

Hy= Dpth=

230 230

mm mm

Overall Height: Overall Width

H= W=

990 1150

mm mm

530 215

mm mm

WINDING DESIGN:

Total Primary turns Required= Total Secondary turns Required=

 Area of conductors:

H.V: L.V:

T(H.V)= T(L.V)=

 Actual 5% tap Integral value Taken 773.001206 811.6513 819 17.4459778 18

ah= al=

11.0192837 mm^2 488.245471 mm^2

L.V WINDING DESIGN: Taking Stranded Conductors:  Area per Strand is:

Strands= a=

15 32.5496981 mm^2

Selecting a Double Helical Winding , Taking the distribution of each L.V Conductor as: 5 Vertical and 3 horizontal,(Rectangular Conductor) Fr om the Conductor Size data sheet: Dimensions of each Strand is

h= w=

6 5.5

the per strand area is 32.1mm^2,thus modified value of curr ent density:

d'=

2.78852553 A/mm^2

Taking 0.25mm insulation all over Dimension of each strand is:

h'= w'=

6.5 6

mm mm

Therefore Conductor Size is:

Hc= Wc=

32.5 18

mm mm

Thus the L.V Winding comprises of 2 Layers Helicaly Positioned and,

mm mm

 9 conductors per layer for a total of 18 conductors, taking 2mm for duct between the 2 layers: Taking space between conductors for cooling a sp=

20

mm

Total Winding Height:= Total Winding Width:=

452.5 38

mm mm

H= W=

Taking 5mm clearance for bakelite former between lv and the core: inner diameter of L.V Winding: outer diameter of L.V Winding: Length of mean turn is

din= dout= Lmt(h.v)=

250 326 904.7808

mm mm mm

H.V WINDING DESIGN: The H.V Winding design is done using the cross over winding using rectangular conductors.  A total of 819 turns are accomodated using 13 coils and 7 coils per layer. Each coil consists of 9 horizontal winding turns.Thus total turns=7*13*9=819. voltage per coil is:

V/coil=

846.153846 V

the area of each conductor is 10.9mm^2 thus, modified value of current density:

d'=

2.78009452 A/mm^2

Dimensions for each conductor

h= w=

3.8 3

mm mm

including the 0.25mm insulation all over:

h'= w'=

4.3 3.5

mm mm

Thus,

hc= wc=

30.1 31.5

mm mm

Coil Height coil width ;

using inter coil spacing of 5.5mm and inter layer(horizontal)spacing of 1mm Winding Height=

H= W=

457.3 39.5

mm mm

Taking the clearance between H.V and L.V as: a=

12

mm

inner diameter of H.V Winding: outer diameter of H.V Winding:

din= dout=

350 429

mm mm

Length of mean turn is

Lmt(h.v)=

1223.6532

mm

OPERATING CHARACTERISTICS: RESISTANCE; Resistivity of copper is=

r=

0.021

W-mm^2/m

Resistance of:

H.V:

r(H.V)=

1.8026211

Resistance of:

L.V:

r(L.V)=

0.00070048 W

Req= Rp.u=

3.17782364 W 0.00875434

 Average mean turn is:  Average Height of Winding:

Lmt(avg) Lc=

1064.217 454.9

Ratio of Lmt/Lc is

Ratio=

2.33945263

value of reactance is:

X=

20.8789598 W

p.u value of reactance:

Xp.u=

0.0575178

Net impedance is:

Z=

20.9028936 W

p.u value of impedance is:

Z(p.u)=

0.05758373

Equivalent Resistance refered to H.V: p.u value of resitance=

W

REACTANCE: mm mm

REGULATION: at 0.8 pf full load regulation is:

Reg(p.u)= 0.04151415

at upf full load the regulation is:

Reg(p.u)= 0.00875434

LOSSES AND EFFICIENCY: IRON LOSSES: From the loss graph of the crgo grade 56 loss curves, Loss per unit volume is

Loss/vol=

1.42

W/kg

now total fluxpath length is: volume of the iron parts:

L= volume=

4120 mm 0.16632984 m^3

Taking density of grade 56 crgo is:

s=

7650

Total mass of the iron parts is:

M=

1272.42324 kgs

thus total iron loss is:

Pi=

1806.841

W

Total copper Losses is=

Pc=

8754.3351

W

kg/m^3

thus %full load at max efficiency is

x=

0.45430591

and efficiency at

0.8pf is:

h=

0.98697054

upf is:

h=

0.9895492

MAGNETIZATION CHARACTERISTICS: Total iron losses=

Pi=

1806.841

W

Thus the loss component of no load current is: Il=

0.05475276

now the mmf/meter for iron is:

Ati/m=

110

AT

Total mmf required is

Ati=

453.2

AT

taking atotal of 0.05mm air gap per joint Total airgap length is:

La/g=

0.3

mm

mmf required for the air gap is:

Ata/g=

381.063927 AT

Total mmf Required is

AT0=

834.263927 AT

the magnetizing current per phase is:

Im=

0.25438239

thus the no load current is:

I0=

0.26020812 0.858687 % of full load current.

OVERALL TANK DIMENSIONS AND VOLUME: Taking the basic clearances of:

b= l= h=

50 80 300

mm mm mm

Width of the tank is=

W= L= H=

1439 589 1290

mm mm mm

thus total volume of tank is:

V=

1.131

m^3

for calculation of copper volume: volume of lv winding: volume of hv winding:

V(lv)= V(hv)=

0.01555771 m^3 0.02210328 m^3

Thus total copper volume is total iron volume is

V= V=

0.11298295 m^3 0.16632984 m^3

thus volume of oil in transformer (including radiators is:)

V(oil)=

1.34667402 m^3

1450 600 1300

mm mm mm

CONSERVATOR DESIGN: Volume of conservator is taken . as 10% of oil in tank and radiators thus taking length to diameter ratio as:

V(cons)=

0.1346674

m^3

R= D= L=

2.5 0.40933341 m 1.02333352 m

DESIGN OF COOLING ARRANGEMENTS (RADIATORS): Value of thermal coefficient at 75 deg c is

C=

12.5

W/(m^2-degC)

Temperature rise limits specified:

q=

40

degC

Total Watts dissipating from surface for the requisite temperature rise is:

W/m^2=

500

W/m^2

Surface Area of Tank is:

St=

5.33

m^2

Total Watts that are dissipated from the tank walls naturaly is=

Diss=

2665

W

Thus the total watts required to be dissipated by radiators is

Rdwats=

7896.1761

W

Taking height of radiators as: thus the watts per section for this height and temperature is:

Hrad=

1200

mm

W/sectn=

167

thus no of section required is

sections=

47.2824916

now the values of spacing constants are:

c= b= d=

0.955 0.93 1

Modified value of no of sections required

sections=

53.2370564 56

Thus we select 56 elliptical Radiator sections in total of 6 Radiators,with 7 sections per radiator. Thus Radiator section dimensions are:

h= w= l=

Horizontal distance between each Section is: vertical surface area of each radiator is: Volume of each radiator= Net Volume of all Radiators

A= V= Vnet=

1200 300 25

mm mm mm

50

mm

0.00736588 m^2 0.00883905 m^3 0.4949868 m^3

TRANSFORMER DESIGN

KVA= 25000 Vp(line)= 33 Vs(line)= 6.9 frequency= 50 phase= 3 transportation height=3.5m load loss= 20 no load loss= 110 load loss capitalization= load loss capitalization= Bmax= 1.7 tesla current density= 3 width of conductor= 17y>7 specific loss= 1.2 copper rate= 425 iron rate= 180

KVA KV KV Hz

connection= type= temp= tappings=

KW KW 1 lakh/KW 5 lakh A/mm2 thickness of conductor= stacking factor= KW/Kg Rs./Kg Rs./Kg CALCULATIONS

HV side voltage: LV side voltage:

Vhv= Vlv=

19.05255888 KV 6.9 KV

Current in HV & LV 

Current in HV: current in LV:

Iph(hv)= Iph(lv)=

437.3865676 1207.729469

Core area 

assuming diameter: core area:

D= A=

440 mm 136847.776 mm2

No. of turns in HV & LV 

HV no. of turns: LV no.of turns

N(hv)= N(lv)=

min.HV turns(90%): N(hv min)= max. HV turns(110%) N(hv max)

133.6009207 368.9042622

134 369

332.1 405.9

333 406

H e ig h t o f c o r e s t r u c t u r e  

assuming height of core structure 2500 mm. H= 2500 mm height of core window: H(window) 1620 mm height of winding: H(wdg)= 1470 mm Design of HV winding 

using Disc winding. assuming No. of turns/disc=

Star-Delta power transformer   75 10.00%

3

4
HV no.of turns: No. of discs: actual No. of discs:

T(hv)= Discs=

369 123 128

width of HV conductor: w(hv)= assuming current density: area of conductor: a(hv)= assuming thickness:

8.184375 2.5 174.954627 3.47

No. of parallel paths: paths=

6.160421642

123

6

Design of LV conductor 

area of conductor: a(lv)= width of LV conuctor: w(lv)= assuming thickness:

483.0917874 7.670149254 2.5

No. of parallel paths: paths=

25.19334482

26

Design of Tapping winding 

winding turns: T(tap)= assuming no. of turns per discs: No. of discs: Discs= actual no. of discs: Discs= ht of tapping winding: ht(tap)=

73 3 24.33333333 28 964.6875

25

C a lc u l a t i o n o f % Z  

width of air gap btwn core & LV: width of air gap btwn LV & HV: width of air gap btwn HV & tap: width of LV winding:

T1=

Inner Dia for LV: mean dia of LV:

ID(lv)= D1=

width of HV winding:

T2=

Inner Dia of HV: mean dia of HV:

ID(hv)= D2=

width of Tapping wdg T3=

Tg= Tg1= Tg2=

15 mm 15 mm 10 mm 78 470 587 71.46 656 763.19 23.82

Inner Dia of Tapping: ID(tap): mean dia of Tapping: D3=

818.92 854.65

ID for air gap btwn HV-LV: mean diameter Dg1=

626 661.73

ID for air gap btwn HV-Tap: mean diameter: Dg2=

798.92 813.92

summation ATD:

ATD=

45516.09745 mm2 455.1609745

Rogowski Factor:

Kr=

0.964388269

Heq=

1524.282332 mm 152.4282332 cm

 Ampere turns:

AT=

161395.6434

Volts/turns:

V/T=

52.17758139

% impedance:

%Z=

11.45326084 %

Width of core 

width of transformer:

W(core)=

2536.76

Volume of core 

volume of 3 limbs: volume of 2 yokes:

vlm(limb)= 738977990.3 vlm(yoke)= 736777185.3

total volume of core:

total=

1475755176

Core loss 

Weight of core: No load loss:

wt= core loss=

11289.52709 18.06324335 KW

Copper loss 

mean dia of LV: mean dia of HV: mean dia of Tap:

d(lv)= d(hv)= d(tap)=

548 mm 727.46 mm 842.74 mm

mean length turn LV: Lmt(lv)= mean length turn HV: Lmt(hv)= mean length turn Tap: Lmt(tap)=

1721.592774 2285.382992 2647.545793

area of conductor LV: a(lv)= area of conductor HV: a(hv)=

483.0917874 mm2 174.954627 mm2

length of LV: length of HV: length of Tap:

l(lv)= l(hv)= l(tap)=

230693.4317 mm2 843306.324 mm2 74131.2822 mm2

resistance LV: resistance HV: resistance Tap:

Rlv= Rhv= Rtap=

0.009550708 0.09640286 0.008474344

Copper loss in LV:

loss(lv)=

41.79228836 KW

Copper loss in HV(normal tap)=

56.94720892 KW

Total loss 

total loss:

116.8027406