Earthing-IEEE80-Final.xls

DESIGN PROCEDURE BLOCK DIAGRAM

FIELD DATA A,r

CONDUCTOR SIZE ts,d,Io

TOUCH & STEP CRITERIA Etouch70, Estep70

INITIAL DESIGN D,n,LT,h

GRID RESISTANCE Rg,LT MODIFY DESIGN D,n,LT,LR

GRID CURRENT IG

YES GPR < Etouch

NO MESH & STEP VOLTAGES Em,Es,Km,Ks,Ki,Kii

NO Em
YES

NO Es
YES

DETAIL DESIGN

EARTHING CALCULATION

A

GENERAL DESIGN DATA

1

Soil Resistivity,

2

r

:

600 Ohm-M

Gravel Resistivity, r s

:

2000 Ohm-M

3

Symmetrical Short Circuit Current, Iefs

:

4

Duration of Earth Fault Current, ts

:

0.3 Sec

5

Design Ambient Temperature

:

50 ° C

6

Thickness of Crushed Gravel, hs

:

0.3 m

7

Depth of Earth Grid, h

:

0.8 m

8

Reference depth of the Grid, h o

9

Standard Used

B

SIZE OF EARTHING CONDUCTOR :

Amm 2 =

50000 A

1 m IEEE - 80 : 2000

I  TCAP  10   t ca r r r 

4

  K 0  Tm   ln     K T  a    0

Eqn.: 40 Page : 43 IEEE Std. 80 - 2000

Where Material Proposed

ar

= Resistivity of Conductor Material

rr

= Thermal co-efficient of resistivity at reference temperature Tr in 1/°C

20.1

Tm

= Max. allowable temperature in °C

419 °C

Ta

= Ambient temperature in °C

Ko

= 1/a0 or 1/ar - Tr in °C

Iefs

= rms current in Ka

50 KA

= Duration of Current in s

0.3 Sec.

tc

0.0032 Ohm - M

40 °C 293

TCAP

= thermal capacity per unit volume from Table 1

3.93 J/(cm³°C)

Amm²

= Conductor cross section in mm²

402 mm²

SELECTED CONDUCTOR (GI Strip) Diameter of equivalent Grid Conductor ,d

= 75 mm x 6 mm = =

450.0 mm² 0.03 m

EARTHING CALCULATION

TOUCH & STEP CRITERIA

K =

r  rs r  rs

Eqn. 21, Page 21, IEEE 80 2000

 r   0 .09  1  r s   Cs = 2 hs  0 .09

Eqn. 27, Page 23, IEEE 80 2000

K

= Reflection factor between different material resistivities

r

= Resistivity of the earth beneath the surface material in W.m

rs

= Surface material resistivity in W.m

hs

= Thickness of the surface material in m

Cs

= Surface layer derating factor

Estep70 = (1000 6Cs  rs )

0.157 ts

K

=

-0.54

Cs

=

0.91

Eqn. 30, Page 27, IEEE 80 2000

Where

Estep 70

= Step Voltage for body weight of 70 kg

Estep 70 Etouch70 = (10001.5Cs rs ) Where

Etouch70

=

3412.28 Volts

Eqn. 33, Page 27, IEEE 80 2000

0.157 ts

= Touch Voltage for body weight of 70 kg

Etouch70

=

1068.05 Volts

EARTHING CALCULATION

C

INITIAL DESIGN ASSUMPTIONS Length 450

Breadth 250

Preliminary Layout of Grid

=

n

= Number of parallel conductors

=

15

D

= Conductor Spacing

=

30 m

h

= Depth of grid burial

=

0.8 m

LT = 2  Na  L Lp

= Length of the conductor across perimeter

=

1800 m

Nr

= No. of Ground Rods

=

33

Lr

= Length of Ground Rods

=

3 m

LR

= Total length of Ground Rods

=

99 m

LC

= Total length of buried condcutor

=

8200 m

LT

= Total length of buried conductors & rods

=

8299 m

Lx

= Maximum length of conductor in X-Axis

=

450

Ly

= Maximum length of conductor in Y-Axis

=

250

D

GRID RESISTANCE

=

112500 m²

1 1  1  Rg = r   1   20A  1  h 20/ A   LT Where A

= Area of the Grid

Rg

= Grid Resistance =

Rg

E

0.87 W

MAXIMUM GRID CURRENT

IG = D f  I g Where Ig Df

= Maximum grid current in A

50000 A

= Decrement factor for the entire duration of fault, given in s

IG

F

0.6

=

30000 A

GROUND POTENTIAL RISE

GPR = I G  Rg GPR

=

26042.3 V

EARTHING CALCULATION GPR VERIFICATION FOR HUMAN SAFETY The safety to personnel is specified by IEEE 80, which requires to limit the development of electrical potential to dangerous value during earth fault current. The regulation stipulates the following parameters to be within the permissible limit a)

Step Voltage (Foot to Foot Contact)

b)

Touch Voltage(Hand to Foot Contact)

CALCULATION FOR ACTUAL DERIVED STEP & MESH VOLTAGE

A

Mesh Voltage

Emesh ( Design ) =

Ki

r  IG  K m  K i   Lr L C  1 . 55  1 . 22   L2  l 2  x Ly  

   L R  

Eqn. 80, Page 91, IEEE 80, 2000

= Corrective factor for current irregularity

K

i

= 0 . 644

 0 . 148

n

Where

n = n

n

a

=

a

 n

b

 n

c

 n

d

2  LT LP na

=

9.1

nb

= 1 for square grids

=

1

nc

= 1 for square and rectangular grids

=

1

nd

= 1 for square, rectangular and L-shaped grids

=

1

n Ki Km

=

9.11

=

1.99

= Spacing factor for Mesh Voltage Km =

Eqn. 68 Page 113 IEEE 80

 D2   D  2 h 2  h   Kii ln  1 8 ln      2 8 Dd 4 d  Kh    2 n  1   16 hd

Where

Kii

= Corrective wieghting factor that adjusts the effect of inner conductors on the corner mesh

K ii =

1 2

(2  n) n

Eqn. 81, Page 93 IEEE 80, 2000

EARTHING CALCULATION

Kh

Kii

=

0.64

Kii

=

1.00 With Rods

= Corrective weighting factor that empasising the grid depth

  1  

=

h ho

  

Where

ho

= Reference depth of grid

=

1

h

= Depth of the ground grid conductor

=

0.8

Kh

=

1.34

Km

=

0.96

Emesh (Design)

=

4104.44 Volts

Calculated Mesh Voltage is Greater than the Tolerable Touch Voltage. MODIFY DESIGN B

Step Voltage Voltage developed for step as per the earthing system proposed during full Earth fault current

Estep ( Design ) =

 Ks

 Ki  r  I G  0 . 75  L C  0 . 85  L R 

Eqn. 92, Page 94 IEEE 80, 2000

Where

Ks

= Spacing factor for Step voltage Ks

1 

=

 1  1  0 .5 1     D  h D  2 h 

n  2

    

Ks K

i

= 0 . 644

 0 . 148

=

0.220

=

1.992444444

n

Ki

Estep (Design )

Estep (Design )

Eqn. 94, Page 94, IEEE 80, 2000

=

=

Calculated Step Voltage is Lower than the Tolerable Step Voltage.HENCE SAFE

1265.62 Volts

1266 Volts

EARTHING CALCULATION SUMMARY

A

EARTH GRID CONDUCTOR Type of Conductor

B

C

Zinc-coated steel rod

Size of Conductor

450

mm

Length of Conductor

8200

mtr

Depth of Conductor

0.8

m below GL

Total Length of Ground Rods

99

mtr

Length of Individual Ground Rods

3

mtr

No. of Ground Rods

33

No.

GROUND RODS

HUMAN SAFETY

Step Voltage Mesh Voltage

UNIT

Designed Value

Permissible Value

Volt

3412

1266

Volt

1068.05

4104

TABLE 1 - MATERIAL CONSTANTS Material Conductivity (%)

Description

Copper annealed 1 soft - drawn

2 3 4 5 6 7 8 9 10

Copper, commercial hard - drawn Copper-clad steel wire Copper-clad steel wire Copper-clad steel rod Aluminium EC Grade Aluminium 5005 alloy Aluminium 6201 alloy Aluminium-clad steel wire Steel, 1020

ar factor

K 0 at

at 20°C

(0°C)

Fusing Temperature Tm (°C)

1

100

1

0.00393

1

234

1

1083

1

2

97

2

0.00381

2

242

2

1084

2

3

40

3

0.00378

3

245

3

1084

3

4

30

4

0.00378

4

245

4

700

4

5

20

5

0.00378

5

245

5

1084

5

6

61

6

0.00403

6

228

6

657

6

7

53.5

7

0.00353

7

263

7

652

7

8

52.5

8

0.00347

8

268

8

654

8

9

20.3

9

0.0036

9

258

9

657

9

10 Stainless - clad steel 11 rod 11 Zinc-coated steel 12 rod 12 13 Stanless steel, 304 13

10.8 10

0.0016 10

605 10

1510 10

9.8 11

0.0016 11

605 11

1400 11

8.6 12 2.4 13

0.0032 12 0.0013 13

293 12 749 13

419 12 1400 13

TCAP Thermal Capacity [J/(cm³.°C]

rr 20°C(mW. cm)

1.72

1

3.42

1.78

2

3.42

4.4

3

3.85

5.86

4

3.85

8.62

5

3.85

2.86

6

2.56

3.22

7

2.6

3.28

8

2.6

8.48

9

3.58

15.9 10

3.28

17.5 11

4.44

20.1 12 72 13

3.93 4.03