TWO-CORE 600/1000V (CVWAZV)

3LE 1: SINGLE-CORE 600/10OOV (CVWAZV) XLPE/PVC/SWA(AL)/PVC

BLE 2: TWO-CORE 600/1000V (CVWAZV)

IftUKAlUfi MfiUSVSI

3LE 1: SINGLE-CORE 600/10OOV (CVWAZV)

unuKmun mnuwsi

^IEC ^60502-2

bie 1 3.6/6(Max. 7.2) KV THREE-CORE CABLES

Copper conductor Sfwpe

of strand

Approx.

outer da.

Thidc.

of XLPE irtsuiafjon

PVC separator

Shaath

Thrdc Approx

outer

kcSa.

{mm}

Cia.

jarYarizec steel

*wre

Thick, of PVC outer- sbeath

Approx.

overaJI cSa.

Approx.- rei.

weight

electrical charadertstia?

Ojrrert rating Cooduclof resistance Capaci

tance

Reactance Short

a150Hi

{mm) 4.7 5.9 7.0 8.1

{mm) (mm)

1.2 1.2 1.3 1.4 1.4 1.5 1.5

{mm) (mm) (mm) (kfjAm)

lr. air at 40°C

(A)

in the ground at2S°C

"Tib-

140 170 200

O.C.

at20°C (fl/km)

50Hz at90°C

(11/km) (rf/Vm) (Q/km) dtaA current (or Isec

(kA)

Ciraiar compact

9.7 11.4 12.8 14.3 16.0 18.4 20.6 23.3 263

25 2.5 2.5 25 2S 2,5 2.5 2-5 2.5 26 2.8 3.0 3.2

»nt»fiGBicrt : i»d. ys4ow & &o«

1.6 1.7 1.8 2.0

£1 31.6 34.2 37.0 39.6 43.7 47.3 50.6 53.8 57.7 63.5 69.3 76.3 83.9

20 2.0 20 2.5 2.5 15 25 2.5 2.5 2.5 3.15 3.15

22 23 23 2.5 26 2.7 28 29 3.0 32 3.5 3.8

3.15 4.0

40.5 43.0 46.0 50.0 54.0 58.0 61.5 65.0 69.0 75.0 83.0 90.5 98.5

2.830 3,330 3,840 4,870 5.910 7.020 8.080 9.210 10.710 13,090 16.410 19.880 23,820

105

13?

195 245 300 340 385 440 515 585 665

745 i 650

245 290 330 365

1.15 0.727 0.524 0.387 0.268 0.193 0.153 0.124

415 0.0991

475 530

0.0754 0.0601 0.0470

1.47 0.927 0.668 0.494 0.342 0.247 0.196 0.160 0.128 0.0988

;o.osoo 0.0643

0.0366 0.0522

0.21 0.24 0.28 0.31 0.35 0.40 0.43 0.47 0.52 0.56 0.57 J160 0.62

0.117 0.109 0.105 0.100 0.0949 0.0914 0.0885 0.0860 0.0837 0.0817 0.0805 0.0790 0.0779

2.41 3.72 5.18 7.36 10.2 13.8 17.4 21.8 26.8 34.7 43.4 57.7 72.1

ble 2 6/10 (Max. 12) KV THREE-CORE CABLES

irlicaiion ; rod. j-eoow 4 Dh>e

16,38,7/15 (Max. 17.5) KV THREE-CORE CABLES

per conductor Trie*.

Of XLPE insulation

PVC separation sheath

Shape

of strand

Approx.

outer

(mm) (mm)

5.9 _4.5

7.0 4.5

8.1 _4.5

9.7 _4.5

Circular 11.4 45

12.8 4.5

:ompacl 14.3 4.5

16.0 4.5

18.4 _4.5

Thick.

1.4 1.4 1.5 1.5 1 6 1.7 1.7 1 8 1 9

Approx.

outer ola.

(mm) 43.3 46.1 48.7 52.6 56.4 59.7 62.9 66 7

Dia.

of galvanized

steel wire

2.5 2.5 2.5 2.5 2.5 2.5 2.5 3.15

Thick, of PVC outer- shea th

(mm) 2.6 2.7 2.8 2.9 3.0 3.1 3.2 3.4

Approx.

overall dia.

54.0 57.0 59.5 63.5 67.5 71.0 74.5 80.0

Approx,

net

weight

(kcykm) 4,790 5,420 6,080 7,160 8,350 9,460 10.640 13,090

Ourrerf rating

In air

at 4frC

(A) M0 170 200 250 305 350 395 ,150

In the ground 3t2S°C (A) 140 170 200 245 290 330 370 J 10

Electrical characteristics CorirJudof resistance

D.C.

ai20°C

(0./km) 0.727 0.524 0.387 0.268 0.193 0.153 0.124

0_0_991

50Hz at90°C

(n/km) 0.927 0.663 0.494 0.342 0.247 0.196 0 159 0.126

Capaci

tance

li£/tm) 0.16 0.18 0.20 0.22 0.25 0.27 0.29 0.31

Reactance Short

at50Hz

(n/km) 0.131 0.124 0.118 0.112 0.107 0.103 0.0994 0.0962

droit currer*

(or 1 sec

(kA) 3.72 5.18 7.36 10.2 13.8 17.4 21.8 26.8

•G C

c

APPENDIX 6 Short Circuit Ratings

<Vp

^eqcU*

^{da*- &}

srtcircuit ratings

PPER CONDUCTORS

FIGURE 2 m

'alues of fault current given in the graph Figure 2 ased on the cable being fully loaded at the stait i short circuit (conductor temperature 90°C) and il conductor temperature of 250°C. and it should

be ensured that the accessories assoctated with the

cable are also capable of operation at these values oi fault current and temperature.

o-i 0-2 0-3 0-4 0-5 0-6 0-8 1 "0 2-0

OURATION OF SHORT CIRCUIT IN SECONDS

Y!>e IsmrV IrtA.*fOjf>rn? COn'VCiOrs (ttis;cjdo! IhC ccvnp,eswi type) 'SnofICCCVTimcna-X i-VC f-V" L'OC «w,'.c si'.tc™

3-0

APPENDIX 7 Fuse Link Type CMF

Fuse link type CMF Appe<Ac-. 5-

Ken 2000 30C0

motor starting current (A)

WOO 2000

motor storting current ( A ,

mole* staring current IA)

3UO0

3000

10. Choice of fuse links

Choice of rated voltage U^:

The rated voltage of the .use links must be equal to, or higher than the operating line voltage. By choosing (uselink rated voltage considerably higher than the linevoltage, the maximum arc voltage mustnot exceed

the insulation level of the network.

Choice of rated current 1^:

The minimum permissible currentrating of the fuse link for motor protection may be determined from the selection charts I, II and III.The three different charts are for

run-up times of 6,15 and 60 seconds respectively. Each chartcontains different characteristics, dependingon the number of starts per hour. Ofthis specific numberof starts per hour, the first two arein

immediate succession; the rest being evenly

spacedinthe 1 hourperiod. The number of starts per hour indicatesthe timeinterval between seperate starts. For example, 4 starts in 15 minutes are represented by 16 starts per hour.

On the horizontal axis of the selection chart, the motor starting current is given, and along the vertical axis the current rating of

the fuse link is found.

Selection procedure:

- Select the charts which are appropriate

for the run-up time of the motor. .

- select the starting current along the

horizontal axis,

- depending on the number of starts per

hour, select the correct characteristic (2.4,8, 16.32),

- read of the correct rating of the fuse link

on the vertical axis.

Example: ^A ^B

Starting current of the motor Run-up time

Number ol starts per hour Chart number

850A 6 sec.

2 1

250A 15 sec.

16 2

xise link type CMF

—?Mr r — ] [ , . . . .

•*<

'— - - v - x - ^ - *

~^T v

^_L

\ ' ^.

? ^V * k \

>T

1 ^\

) : — '.-.

H ^{±^}

^\ ^N\

* \ s

\ \\

' . 3 V.-i-4-f

t y. \ ' \

I w —

--V --v* V*

^L... ^_ ^•

Tj 7

-^—s - ^ - _iv—

:? ^S3 ^t⁰ ^160X0 ^{s o a s}

••s

i \

\-\l _^__.

¹ ^•

c tt*

—=S= - J r ^r-\V-

A \ \ *

' 0

a i

, - V vv-i-

* — - -

A--V- JA^

\v \ ^\

\ 1V ^ ⁾

*V" 2 J 1

Current /

> > t

Strom in A —^{— ^}

i j * • i t?

z_/\

T /

/ ^{+ ••'}

\ •

^<<

1 > •>*p

*i •**-'' **•'-'-'-

~£ ^

/ ^-"" T' ^ ^

^ ^

^ ^

S 13 20 SO IM

Pro^Mtlivr curitr* kA |rms)

7. Pre-arcinn times

The characteristics are equal for all rated voltages and are recorded from cold

condition.

In the uncertain interrupting zone the curves

are dotted.

8. Current limitation

CMF fuse links are current limiting. A large short circuit current will therefore not reach its full value. The diagram shows the relation between the prospective short circuit current and the peak value og the cut off current.

9. Overvoltages

In orderlo be currentlimiting, the fuse links' must generate an arc voltage exceeding the instantaneous value of the operating

voltage. The overvoltage generated by the

CMF fuse link is below the maximum

permissible value ace to IEC282-1.

CMF fuse links can safely be used if the system line voltage is 50-100% of the rated

Fuse link type CMF

11. Replacement of melted fuse links

The fuse link cannot be regenerated.

According to IEC. Publication 282-1, all 3 fuse links should be replaced, even if onry 1 or 2 of the fuse links in the threephase

12. The K-factor

According to the IEC 644, the K-factor is a factor {less than unity) d.eftning an overload characteristic to which the fuse link may be repeatedly subjected under specified motor starting conditions without deterioration. The overload characteristic is obtained by

13. Data and dimensions CMF

system have operated. Exceptions are allowed when it can be verified that the fuse link(s) have not experienced any

overcurrent

multiplyingthe currenton the prearcing characteristic (melting time characteristics) by K. The Value of K given in the data table is chosen at 10 seconds melting time, and is valid for melting times between 5 and 60 seconds.

UN •n ^e ^D ^K* '1 '3 Ro PN

Minimum Maximum

. kV A m m mm - KA A mohm Watt Pre-arc

Aas

Interruption A*s

•Q? \

²⁹² ⁶⁵ ^0,75 ^50' ²⁷⁵ ^3,25 ⁴⁹ ^1,4-104 ^{(17-104 )\}

292 65 0,7 50 -400 1,94 75 3,8 '104 L50-104 J

3,6 ²⁰⁰ 292 87 0,7 50 500 1,42 75 7,6'104 71 -104

^250^

²⁹² ⁸⁷ ^0,6 ⁵⁰ ⁷⁶⁰ ^1.03 ⁹⁰ ^14-104 _v?:10**?

315 292 87 0,6 50 900 0,85 122 21*10"* 180-104

63 442 65 0,75 50 175 8,63 45 0,48 • 104 6,5-104

100 442 65 0,75 50 275 4,93 67 1,40* 104 18 • 104

7,2

160 442 65 0,7 50 400 2,96 119 3,8 *104- 54-104

200 442 87 0,7 50 500 2,15 118 7,6-104 75-104

250 442 •87* 0,6 50 800 1,56 142 14- 104 120* 104

315 442 87 0,6 50 950 1,30 193 21 • 104 220-104

63 442 65 0,75 50 190 13,3 77 0,48 • 104 11 -104

100 442 87 0,75 50 275 6,72 103 1,4- 104 20 "104

160 442 87 0.7 50 480 4,04 155 3,8-10" 70 • 104

200 442 87 0,7 50 653 2.89 ¹⁷³ 9,3- 104 91 • 104

c ^CMF

3 s

*) The K-lactor is relened to the

Legends:

e = see figure

D = see figure

Ij = max. short circuit current tested l3 - minimum breaking current

Rq = resistance at room temperature

APPENDIX 8 Proposed Cable Sizes

SHINRYO(M)SDNBHD

PROJECT: PUTRAJAYA PRECINCT 5

POWER CABLES SCHEDULE SUMMARY -41.S\>

"Group Derating Factor = 0.73

SHINRY0(M)SDN8HD

PROJECT: PUTRAJAYA PRECINCT 5

POWER CABLE SCHEDULE SUMMARY - 3 3kV Swit

Cabfe Schedule Rev l.xis

SHINRYO (M) SON BHD

PROJECT : PUTRAJAYA PRECINCT 5

POWER CABLE SCHEDULE SUMMARY - 415V VSD Los

From To

Transformer A Transformer B Transformer C

-#B*-A

VFDB VEQ.C

VFDA VFDB VFDC

Variable Frequ"

Variable Frequf P-0102A

P-0102B

Variable Frequ Secondary Chille

P-0102C

^Secondary Chille-,

^Secondary Chute

No of

Core type Or Cable

JC/S/P (Cu) jusrp (Cu) JC/S/P (Cu) JCS/R(CuT X/S/P(Cu).

JO§/P.(Cu)

Proposed Cable Size(sq.mm)

500 500 500 400:

'WQ.-&:

400.:^

Ampacity of cable at 40 deg.C

870 870 870

"n&Tsd^s?

^SZOT KSJSilS©

Remarks

%^P-J

APPENDIX 9 Crystal Report-Short Circuit Simulation for Basic

Engineering Design

Project:Basic_f=ngineering_5r DAPPERFaultContributionCompleteReport Date:2December2004 4:02:54PM ComprehensiveShortCircuitStudySettings PhaseFaultYes SingleLinetoGroundYes LinetoLineFaultNo toLinetoGroundNo MotorContributionYes TransformerTapNo PhaseShiftYes -InitialSymmetricalAmps- Name llkVS'board ll/3.3a 11/3.3b 11/415a 11/415b Bus Future Phase1 Busl ll/415a2 VPhase1

InCable OuCable InCable OuCable InCable InCable OuCable InIndMa inIndMa inCable InIndMa inIndMtr

3Phase 17,313 1,061 296 15,958 17,613 13,191 2,384 2,050 43,782 33,968 4,973 4,973

SLG 0 0 0 0 17,560 14,620 1,585 1,362 41,133 34,979 3,115 3,115

LLG 0 0 0 0

FaultedBus BusVoltages BranchCurrents PhaseorSequence FaultCurrentCalculation AsymFaultCurrentatTime

AHBuses FirstBusFromFault FirstBranchFromFault Reportphasequantities InitialSymmetricalRMS(with1/2CycleAsym) 0.50 -AsymmetricalAmps-—InitSymNeutralAmps- LL 0 0 0

3Phase 27,641 1,694 473 25,478

SLG 0 0 0 28,44628,940 21,30524,095 3,8512,612 3,3112,246 52,18847,984 40,49040,805 5,9283,633 5,9283,633

LLG 0 0 0

LL 0 0 0

SLG 17,560 41,133

LLG

—initsymNeuicraiAmps— BusName3PhaseSLGLLGLL3PhaseSLGLLGLLSLGLLG 415VBus200000000 ll/415b2InCable00000000 415VPhase2InIndMtr2,2561,480002,6371,70900 415VPhase2InIndMtr2,2561,480002,6371,70900 HkVNodeBus417,26000027,295000 11/415aInCable16,96600026,829000 11/0.415TxlAInXformer2296000468000 HkVNodeBus700000000 11/415bOuCable 11/0.415TxlBOuXformer2 HkVNodeBus917,27100027,456000 ll/3.3aInCable16,21000025,770000 1l/3.3kVTxAInXformer21,0610001,687000 3.3kVNode417,63517,5900028,59429,14400 3.3aInCable4,4312,946007,1844,88100 H/3.3kVTxAInXformer213,21814,6520021,43224,2760017,591 HkVNodeBus317,35400027,860000 11aInCable1,3570002,178000 TNB1InUtil.16,00000025,686000 HkVNodeBus200000000 ll/3.3bOuCable 11/3.3kVTxBOuXformer2 3.3kVNode500000000 3.3bOuCable 11/3.3kVTxBOuXformer2

Name NodeBus4 TxlA NodeBus5 TxlB InCable InXformer2 InCable OuXformer2 -InitialSymmetricalAmps- 3PhaseSLGLLGLL 51,36049,59000 9,4276,06800 42,04243,58700

-AsymmetricalAmps——InitSymNeutralAmps- 3PhaseSLGLLGLLSLG 82,92282,04300 15,22010,03900 67,87872,1120049,590

LLG

APPENDIX 10 Crystal Report-Short Circuit Simulation for Detail

Engineering Design

rrojeci:uetan_cngineenng_or DAPPERFaultContributionCompleteReport Date:2December2004 Time:4:10:35PM ComprehensiveShortCircuitStudySettings ThreePhaseFaultYes SingleLinetoGroundYes LinetoLineFaultNo LinetoLinetoGroundNo MotorContributionYes TransformerTapYes XformerPhaseShiftYes -InitialSymmetricalAmps- BusName HkVS'boardB 11/3.3M ll/415bl PI-1 llkVS'boardA ll/3.3al ll/415al 11a PI-1 3.3kVBus2 11/3.3b2 TxVFDB PI-2 P-0101D-E P-0231C-E OuCable OuCable InPi InCable InCable InCable InPi OuCable InXformer2 InPi InIndMtr InIndMtr

3Phase 15.818 15,818 15,819 1,450 320 15,487 0 20,041 590 17,258 836 593

SLG 0 16,548 325 15,016 460 326

LLG 0

FaultedBus BusVoltages BranchCurrents PhaseorSequence FaultCurrentCalculation AsymFaultCurrentatTime

AllBuses FirstBusFromFault FirstBranchFromFault Reportphasequantities InitialSymmetricalRMS(with1/2CycleAsym) 0.50 -AsymmetricalAmps-—InitSymNeutralAmps- LL 0

3Phase 15,818 15,818 15,819 1,450 320 15,487 0

SLG 0 24,55922,990 723451 21,14920,860 1,024639 727453

LLG 0

LL 0

SLGLLG 16,548

w a.

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in r-i o ->3- oo m ^o

in 00 N i n \D N t

so' of —<"

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s o s o o * * — r o o s o s

c N m o o t N ' t f , o o r o r >

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Name HkVNodeBusl ll/3.3al ll/3.3kVA Nodel ll/3.3a2 11/3.3kVA HkVNodeBus2 ll/3.3bl ll/3.3kVB Node2 ll/3.3b2 HkVNodeBus3 11a HkVNodeBus4 ll/415al 11/0.415A HkVNodeBusS 11/415M InIndMtr InIndMtr InIndMtr InIndMtr InIndMtr InIndMtr OuIndMtr InCable InXformer2 InCable InXformer2 OuCable OuXformer2 OuCable OuXformer2 InCable InUtil. InCable InXformer2 OuCable

-InitialSymmetricalAmps- 3Phase 580 1,161 918 22 43 7 15,642 15,358 1,451 20,129 6,846 13,356 0 16,292 1,764 16,000 15,610 15,521 320 0

SLG 352 704 557 13 26 4 16,635 3,772 12,898 0

LLG 0 0 0 0 0 0

LL 0 0 0 0 0 0

3Phase 722 1,444 1,143 27 54 15,642 15,358 1,451 24,694 8,398 16,384 0 16,292 1,764 16,000 15,610 15,521 320 0

-AsymmetricalAmps- SLG 446 892 706 17 33 5 23,204 5,261 17,991 0

LLG 0 0 0 0 0 0

LL 0 0 0 0 0 0

—InitSymNeutralAmps- SLGLLG 16,635

BusName Tx11/0.415B 415VNodeBusl 11/415a2 Tx11/0.415A 415VNodeBus2 11/415b2 Tx11/0.415B 415VNodeBus3 TxVFDA P-0102A 415VNodeBus4 TxVFDB P-0102B-C

OuXformer2 InCable InXformer2 OuCable OuXformer2 InXformer2 InIndMtr InXformer2 InIndMtr

-InitialSymmetricalAmps- 3Phase 45,430 10,517 34,928 0 14,142 10,396 3,756 17,884 10,388 7,511

SLG 41,632 6,425 35,216 0 12,984 10,691 2,299 14,893 10,730 4,170

LLGLL

-AsymmetricalAmps 3Phase 64,984 15,044 49,962 0

SLG 63,747 9,838 53,922 0 22,68521,424 16,67617,639 6,0243,793 27,98524,325 16,25617,525 11,7546,811

LLGLL

—InitSymNeutralAmps- SLGLLG 41,632 12,984 14,893

APPENDIX 11 Crystal Report-Load Flow Simulation for Basic

Engineering Design

Date:2December2004 Time:3:58:04PM LoadFlowStudySettings IncludeSourceImpedance SolutionMethod LoadSpecification GenerationAccelerationFactor SwingGenerators SourceIn/OutService TNB1In Buses BusNameIn/OutService HkVNodeBus2In HkVNodeBus3In HkVNodeBus4In HkVNodeBus7In HkVNodeBusSIn HkVNodeBus9In llkVS'boardIn

Project:BasicJEngineering_Lc LoadFlowSummaryReport Vpu 1.00

Yes Exact(Iterative) ConnectedLoad 1.00 Angle 0.00 DesignVolts 11.000 11.000 11.000 11.000 11.000 11.000 11.000

kW 4,451.0

LoadAccelerationFactor BusVoltageDrop% BranchVoltageDrop% kvarVD% 3,459.61.21 LFVoltsAngleDegreePUVolts 10.866-0.820.99 10.867-0.820.99 10.866-0.820.99 10.866-0.820.99 00.000.00 10.866-0.820.99 10.866 1

-0.820.99

1.00 5.00 3.00 UtilityImpedance 0.01+j0.33 %VD 1.22 1.21 1.22 1.22 100.00 1.22 1.21

NameIn/OutService BuslIn Bus2In In In Node5In NodeBuslIn NodeBus2In NodeBus3In NodeBus5In BuslIn VBus2In NodeBus4In In DesignVolts 3.300 3.300 3.300 3.300 3.300 33.000 33.000 33.000 415 415 415 415 33.000

LFVolts 3.218 3.211 0 3.219 3.212 0 0 0 405 402 402 405 0

AngleDegree -31.78 -31.93 0.00 -31.78 -31.94 0.00 0.00 0.00 -31.70 -31.63 -31.63 -31.70 0.00

PUVolts 0.98 0.97 0.00 0.98 0.97 0.00 0.00 0.00 0.98 0.97 0.97 0.98 0.00

%VD 2.47 2.68 100.00 2.46 2.67 100.00 100.00 100.00 2.36 3.17 3.17 2.36 100.00 Bus Bus

Component Name In/Out Service

%VDkW Loss kvar Loss kVA Loss LFAmps Rating%

PF 11aIn0.014,451.0 0.3

3,459.6 0.3 5,637.4 0.4 299.5 0.0 0.79 11/3.3bIn0.001,862.8 0.0

1,454.3 0.0 2,363.3 0.1 125.6 0.0 0.79 11/415aIn0.00493.1 0.0

380.8 0.0 623.0 0.0 33.1 0.0 0.79 11/415bIn0.00493.1380.8623.033.10.79

FromBus ToBus Component Name In/Out Service

%VDkW Loss kvar Loss kVA Loss LFAmps Rating%

PF HkVNodeBus70.00.00.00.0 llkVS'board HkVNodeBus9

11/3.3aIn0.001,601.6 0.0 1,243.4 0.0 2,027.6 0.0 107.7 0.0

0.79 3.3kVNode4 3.3kVBusl 3.3kVNode5 3.3kVBus2

3.3a 3.3b

In0.01 In0.01

1,601.6 0.2 1,862.8 0.2 1,201.2 0.1 1,397.1 0.2 2,002.0 0.2 2,328.4 0.3

359.1 0.0 418.6 0.0

0.80 0.80 415NodeBus5 415VBus2

ll/415b2In0.81493.1 4.5 368.9 2.5 615.8 5.2 877.4 0.0

0.80 415VNodeBus4 415VBusl

ll/415a2In0.81493.1 4.5 368.9 2.5 615.8 5.2 877.4 0.0

0.80 2-WindingTransformers FromBus ToBus

Component Name In/Out Service

%VDkW Loss kvar Loss kVA Loss LFAmps Rating%

PF 1lkVNodeBus 3.3kVNode5

11/3.3kVTxBIn1.451,862.8 0.0 1,454.3 57.2 2,363.2 57.2 126.0 39.9 0.79 llkVNodeBus 415VNodeBus

11/0.415TxlAIn1.15493.1 0.0 380.8 11.9 623.0 11.9 33.0 31.5 0.79 llkVNodeBus 415NodeBus5

11/0.415TxlBIn1.15493.1 0.0 380.8 11.9 623.0 11.9 33.0 31.5 0.79 llkVNodeBus 3.3kVNode4

H/3.3kVTxAIn1.251,601.6 0.0 1,243.3 42.1 2,027.6 42.1 108.0 34.2

0.79

APPENDIX 12 Crystal Report-Load Flow Simulation for Detail

Engineering Design

Date:2December2004 Time:4:07:54PM LoadFlowStudySettings IncludeSourceImpedance SolutionMethod LoadSpecification GenerationAccelerationFactor SwingGenerators SourceIn/OutService TNBIn Buses BusNameIn/OutService 1lkVNodeBuslIn HkVNodeBus2In HkVNodeBus3In HkVNodeBus4In llkVNodeBus5In 1lkVS'boardAIn 1lkVS'boardBIn Vpu 1.00

Project:Detail_Engineering_Lc LoadFlowSummaryReport Yes Exact(Iterative) IstLevelDemandorEnergyFactor 1.00

LoadAccelerationFactor BusVoltageDrop% BranchVoltageDrop% AnglekWkvarVD% 0.006,102.31,681.02.06 DesignVoltsLFVoltsAngleDegreePUVolts 10.7630.260.98 10.7630.260.98 10.7730.280.98 10.7640.260.98 10.7640.260.98 10.7640.260.98 10.7640.260.98 1

11.000 11.000 11.000 11.000 11.000 11.000 11.000

1.00 5.00 3.00 UtilityImpedance 0.33+J0.01 %VD 2.16 2.15 2.06 2.14 2.15 2.14 2.14

NameIn/OutService kVBuslIn Bus2In NodelIn In VBuslIn Bus2In NodeBuslIn NodeBus2In NodeBus3In NodeBus4 Bus Bus

In Component Name 11a A lkVS'boardA NodeBusl A S'boardB S'boardB

ll/3.3al ll/415al 11/3.3M 11/415M

DesignVolts In/Out Service In In In In In

3.300 3.300 3.300 3.300 415 415 415 415 415 415 %VD 0.08 0.01 0.00 0.01 0.00

LFVolts kW Loss 6,102.3 4.4 2,718.5 0.3 524.8 0.0 1,973.1 0.2 881.5 0.0

3.340 3.351 3.341 3.352 421 419 423 422 429 420

AngleDegree kvar Loss 1,681.0 3.5 882.7 0.3 77.9 0.0 604.5 0.1 112.4 0.0

-3.68 -1.14 -1.67 -1.14 -0.97 -1.83 -0.92 -1.72 -3.71 -5.27 kVA Loss 6,329.6 5.6 2,858.3 0.4 530.6 0.0 2,063.6 0.2 58.6 0.0

PUVolts 1.01 1.02 1.01 1.02 1.01 1.01 1.02 1.02 1.03 1.01 LFAmps Rating% 339.2 0.0 153.3 0.0 28.5 0.0 110.7 0.0 47.7 0.0

%VD -1.21 -1.55 -1.24 -1.56 -1.41 -1.05 -1.81 -1.71 -3.31 -1.14 PF 0.96 0.95 0.99 0.96 0.99

FromBus ToBus Component Name In/Out Service

%VDkW Loss kvar Loss kVA Loss LFAmps Rating%

PF 3.3kVNodel 3.3kVBusl

ll/3.3a2In0.032,718.1 0.6 782.1 0.6 2,828.4 0.8 488.8 0.0

0.96 3.3kVNode2 3.3kVBus2

ll/3.3b2In0.021,972.8 0.3 552.0 0.3 2,048.6 0.4 352.9 0.0

0.96 415VNodeBusl 415VBusl

ll/415a2In0.39524.8 2.0 66.8 0.8 529.0 2.1 722.9 0.0

0.99 415VNodeBus2 415VBus2

11/415b2In0.65881.4 5.5 81.5 2.2 885.2 5.9 1,210.8 0.0

1.00 2-WindingTransformers FromBus ToBus

Component Name In/Out Service

%VDkW Loss kvar Loss kVA Loss LFAmps Rating%

PF llkVNodeBus 3.3kVNodel

Tx11/3.3kVAIn-3.392,718.2 0.1 882.4 100.4 2,857.9 100.4 153.0 57.3 0.95 1lkVNodeBus 3.3kVNode2

Txll/3.3kVBIn-3.721,972.9 0.1 604.3 52.3 2,063.4 52.3 111.0 41.3 0.96 11kVNodeBus 415VNodeBus

Tx11/0.415AIn-3.95524.8 0.0 77.9 11.0 530.6 11.0 28.0 33.9 0.99 llkVNodeBus 415VNodeBus

Txl1/0.415BIn-3.85881.4 0.0 112.4 30.9 888.6 30.9 48.0 56.8

0.99 3.3kVBusl 415VNodeBus

TxVFDAIn-2.10283.8 0.0 182.2 13.9 337.2 13.9 58.0 83.3

0.84 3.3kVBus2 415VNodeBus

TxVFDBIn0.41567.6 0.1 394.7 57.9 691.3 57.9 119.0 170.2

0.82

PiImpedances Bus Bus

ComponentName API-1 S'boardB Bus2 kVBusl VBus2 VBusl

PI-2 PI-3

%VD 0.00 0.00 0.00

kW Loss 2,854.5 0.0 0.0 0.0 0.0 0.0

kvar Loss 716.9 0.0 0.0 0.0 0.0 0.0

kVA Loss 2,943.2 0.0 0.0 0.0 0.0 0.0 LFAmps Rating% 157.9 0.6 0.0 0.0 0.0 0.0

PF 0.97 0.00 0.00

APPENDIX 13 Simulation Diagrams-Branch and Bus Fault Currents

for Basic Engineering Design

llkVS'board 11/415a -I1Isc3P296A 4-Isc3P16966A ll/0.415TxIAg -tIsc3PPri296A 4Isc3P42042A 4IscSLG43587A 415VPhasel Isc3P4973A IscSLG3115A

']••Isc3P1061A 4-Isc3P16210A Isc3PPri1061A Isc3P13218A IscSLG14652A 11/415a2 -TIsc3P9427A 1XIscSLG6068A 4Isc3P33968A 4IscSLG34979A 415VPhasel isc3P4973A IscSLG3115A

TNB1lkV(Phase1-Phase2) Isc3P16000A 1"Isc3P1357A 4-Isc3P15958A Il/3.3kVTxA |IsIsc3P4431A i.3.3a4-IscSLG2946A 4-Isc3P13191A 4-IscSLG14620A ®! 3.3kVPhasel Isc3P2050A IscSLG1362A

11/3.3kVTxB 0 3.3kVFuture Isc3P2384A IscSLG1585A

J11/415b U/0.4l5TxlB 0' 415VPhase2 Isc3P2256A IscSLG1480A

J® 415VPhase2 Isc3P2256A IscSLG1480A

43782Amps3P 41133AmpsSLG

17313Amps3P llkVS'board 11/415aJ 11/0.415TxlA 0 415VPhasel

ll/415a2

17613Amps3P 17560AmpsSLG

TNB1lkV(Phase1-Phase2} (i)H/3.3kVTxA 0 3.3kVPhasel

!1/3.3b 11/3,3kVTxBfgs, 3.3b 0 3.3kVFuture

li/415b S)11/0.415TxlB ill/41Sb2 0 415VPhase2

APPENDIX 14 Simulation Diagrams-Branch and Bus Fault Currents

for Detail Engineering Design

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APPENDIX 15 Simulation Diagrams-Load Flow Study without Power Factor Correction for Basic Engineering

Design

LFVD%1.21% llkVS'board 11/415a ]1/0.415TxlA 4493.1kW 4380.8kVAR PctVD1.1% 415VBusl LFVD%3.17%^^

4-493.1kW 4380.8kVAR PctVD0.0% LF33A3.3kVBusl

1601.6kW 1243.4kVAR PctVD0.0% LF108A 1601.6kW 1243.3kVAR, PctVD1.2%' LFVD%2.47% Il/415a2 4-493.1kW 4-368.9kVAR PctVD0.8% LF877A fkf 415VPhasel 610.70kVA

4451.0kW 3459.6WAR 4451.0kW 3459.6kVAR PctVD0.0% LF300A H/3.3kVTxA 1601.6kW 1201.2kVAR PctVD0.0% LF359A 3.3kVPhasel 2001.80kVA 4-1862.8kW 4-1454.3kVAR PctVD0.0% LF126A H/33kVTxB. 4-1862.8kW 4-1397.1kVAR PctVD0.0% LF419A 0 3.3kVFuture 2328.17kVA

1862.8kW 1454.3kVAR PctVD1.5% 3.3kVBus2 LFVD%2.68%

j11/415b $_-J-493.1kW 4380.8kVAR PctVD0.0% LF33A ll/0.4I5TxlB 4493.1kW 4380.8kVAR PctVD1.1% H/415b2 4493.1kW J-368.9kVAR PctVD0.8% LF877A 0 415VPhasel 610.70WA

LFVD%3.17%

11/0.415TxlA 33.10PriAmps 877.43SecAmps Ampacity105.0A ll/415a2 877.43Amps 0 415VPhasel TNB11kV(Phase1-Phase2) 11a299.50Amps 107.73Amps 107.73PriAmps(2)H/3.3kVTxA 33.10Amps359.10SecAmpss Ampacity314.9AJ359.10Amps 3.3a 3.3kVBusl( 3.3kVPhasel

125.57Amps 3.3kVFuture

11/3.3kVTxBkiJ125.57PriAmps 418.55SecAmps 418.55AmpsS;Ampacity314.9A \3.3b I3.3kVBus2

11/415b 33.10Amps ll/0.415TxlB 33.10PriAmps 877.43SecAmps Ampacity105.0A U/415b2 877.43Amps 0 415VPhasel

APPENDIX 16 Simulation Diagrams-Load Flow Study with Power

Factor Correction for Detail Engineering Design

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APPENDIX 17 Single Line Diagrams for Basic, Detail and

Construction Engineering Design

FESj

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THE FUTURE EQUIPMENT SYSTEM [PHASE 2,3. 8 41 IS SHOWN IN DOTTED LINES.

THE POWER FACTOR AT 33kV TNB INCOMING PANEL SHALL BE AT LEAST 0.93. IT IS CONTRACTOR'S RESPONSIBILITY TO DETERMINE THE NEEDS OF CAPACITOR FOR EACH SWITCHBOARD.

THE TRANSFORMERQUANTITY AND RATING TO BE VERIFYBY CONTRACTOR.

THE FEEDER AND MCC QUANTITY AND RATING FOR I IhV. 3.3KV AND 415V SHALL BE VERIFY BYCONTRACTOR.

FOR FUTURE INSTALLATION ( SHOWN IN DOTTED LINES). FEEDERS SHALL C

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(MODULAR)

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3LE 1: SINGLE-CORE 600/10OOV (CVWAZV) XLPE/PVC/SWA(AL)/PVC

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APPENDIX 6

Short Circuit Ratings

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srtcircuit ratings

FIGURE 2 m

APPENDIX 7

Fuse Link Type CMF

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APPENDIX 8

Proposed Cable Sizes

APPENDIX 9

Crystal Report-Short Circuit Simulation for Basic

Engineering Design

APPENDIX 10

Crystal Report-Short Circuit Simulation for Detail

Engineering Design

APPENDIX 11

Crystal Report-Load Flow Simulation for Basic

Engineering Design

APPENDIX 12

Crystal Report-Load Flow Simulation for Detail

Engineering Design

APPENDIX 13

Simulation Diagrams-Branch and Bus Fault Currents

for Basic Engineering Design

APPENDIX 14

Simulation Diagrams-Branch and Bus Fault Currents

for Detail Engineering Design

APPENDIX 15

Simulation Diagrams-Load Flow Study without Power Factor Correction for Basic Engineering

Design

APPENDIX 16

Simulation Diagrams-Load Flow Study with Power

Factor Correction for Detail Engineering Design

APPENDIX 17

Single Line Diagrams for Basic, Detail and

Construction Engineering Design

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