Chapter G

Sizing and protection of conductors


Calculation of minimum levels of short-circuit current

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If a protective device in a circuit is intended only to protect against short-circuit faults, it is essential that it will operate with certainty at the lowest possible level of short-circuit current that can occur on the circuit

In general, on LV circuits, a single protective device protects against all levels of current, from the overload threshold through the maximum rated short-circuit current-breaking capability of the device.
In certain cases, however, overload protective devices and separate short-circuit protective devices are used.

Examples of such arrangements

Figures G40 to G42 show some common arrangements where overload and short-circuit protections are achieved by separate devices.




FigG40.jpg

















Fig. G40: Circuit protected by aM fuses



FigG41.jpg

















Fig. G41: Circuit protected by circuit-breaker without thermal overload relay



FigG42.jpg


















Fig. G42a: Circuit-breaker D provides protection against short-circuit faults as far as and including the load


As shown in Figures G40 and G41, the most common circuits using separate devices control and protect motors.
Figure G42a constitutes a derogation in the basic protection rules, and is generally used on circuits of prefabricated bustrunking, lighting rails, etc.
Variable speed drive
Figure G42b shows the functions provided by the variable speed drive, and if necessary some additional functions provided by devices such as circuit-breaker, thermal relay, RCD.



Protection to be provided Protection generally provided by the variable speed drive Additional protection
Cable overload Yes = (1) Not necessary if (1)
Motor overload Yes = (2) Not necessary if (2)
Downstream short-circuit Yes  
Variable speed drive overload Yes  
Overvoltage Yes  
Undervoltage Yes  
Loss of phase Yes  
Upstream short-circuit   Circuit-breaker
(short-circuit tripping)
Internal fault   Circuit-breaker
(short-circuit and
overload tripping)
Downstream earth fault (indirect contact) (self protection) RCD ≥ 300 mA
Direct contact fault   RCD ≤ 30 mA




















Fig. G42b: Protection to be provided for variable speeed drive applications


Conditions to be fulfilled

The protective device must fulfill:
  • instantaneous trip setting Im < Iscmin for a circuit-breaker
  • fusion current Ia < Iscmin for a fuse

The protective device must therefore satisfy the two following conditions:

  • Its fault-current breaking rating must be greater than Isc, the 3-phase short-circuit current at its point of installation
  • Elimination of the minimum short-circuit current possible in the circuit, in a time tc compatible with the thermal constraints of the circuit conductors, where:[math]\displaystyle{ tc \ge \frac{k^2S^2}{Isc_{min}\, ^2} }[/math]

(valid for tc < 5 seconds)

Comparison of the tripping or fusing performance curve of protective devices, with the limit curves of thermal constraint for a conductor shows that this condition is satisfied if:

  • Isc (min) > Im (instantaneous or short timedelay circuit-breaker trip setting current level), (see Fig. G45)
  • Isc (min) > Ia for protection by fuses. The value of the current Ia corresponds to the crossing point of the fuse curve and the cable thermal withstand curve (see Fig. G44 and G45)


FigG43.jpg















Fig. G43: Protection by circuit-breaker



FigG44.jpg















Fig. G44: Protection by aM-type fuses



FigG45.jpg















Fig. G45: Protection by gl-type fuses


Practical method of calculating Lmax

In practice this means that the length of circuit downstream of the protective device must not exceed a calculated maximum length: [math]\displaystyle{ L_{max}=\frac{0.8\ U\ Sph}{2 \rho Im} }[/math]

The limiting effect of the impedance of long circuit conductors on the value of short-circuit currents must be checked and the length of a circuit must be restricted accordingly.
The method of calculating the maximum permitted length has already been demonstrated in TN- and IT- earthed schemes for single and double earth faults, respectively. Two cases are considered below:
1 - Calculation of Lmax for a 3-phase 3-wire circuit
The minimum short-circuit current will occur when two phase wires are short-circuited at the remote end of the circuit (see Fig. G46).



FigG46.jpg

 





Fig G46: Definition of L for a 3-phase 3-wire circuit


Using the “conventional method”, the voltage at the point of protection P is assumed to be 80% of the nominal voltage during a short-circuit fault, so that 0.8 U = Isc Zd, where:
Zd = impedance of the fault loop
Isc = short-circuit current (ph/ph)
U = phase-to-phase nominal voltage
For cables ≤ 120 mm2, reactance may be neglected, so that  [math]\displaystyle{ Zd=\rho \frac{2L}{Sph}\ ^{(1)} }[/math]
where:
ρ = resistivity of conductor material at the average temperature during a short-circuit,
Sph = c.s.a. of a phase conductor in mm2
L = length in metres
The condition for the cable protection is Im ≤ Isc with Im = magnetic trip current setting of the CB.
This leads to [math]\displaystyle{ Im \ge \frac{0.8 U}{Zd} }[/math]  which gives with U = 400 V
ρ = 1.25 x 0.018 = 0.023 Ω.mm2/m(2) (Cu)
Lmax = maximum circuit length in metres [math]\displaystyle{ L_{max}=\frac {k\ Sph}{Im} }[/math]

2 - Calculation of Lmax for a 3-phase 4-wire 230/400 V circuit
The minimum Isc will occur when the short-circuit is between a phase conductor and the neutral.
A calculation similar to that of example 1 above is required, but using the following formulae (for cable ≤ 120 mm2 (1) ).

  • Where Sn for the neutral conductor = Sph for the phase conductor [math]\displaystyle{ L_{max}=\frac {3,333 Sph}{Im} }[/math]
  •  If Sn for the neutral conductor < Sph, then [math]\displaystyle{ L_{max}= 6,666 \frac{Sph}{Im}\frac{1}{1+m} }[/math]  where [math]\displaystyle{ m=\frac{Sph}{Sn} }[/math]


For larger c.s.a.’s than those listed, reactance values must be combined with those of resistance to give an impedance. Reactance may be taken as 0.08 mΩ/m for cables (at 50 Hz). At 60 Hz the value is 0.096 mΩ/m.

(1) For larger c.s.a.’s, the resistance calculated for the conductors must be increased to account for the non-uniform current density in the conductor (due to “skin” and “proximity” effects)
Suitable values are as follows:
150 mm2: R + 15%
185 mm2: R + 20%
240 mm2: R + 25%
300 mm2: R + 30%
(2) The high value for resistivity is due to the elevated temperature of the conductor when passing short-circuit current










Tabulated values for Lmax

Figure G47 below gives maximum circuit lengths (Lmax) in metres, for:

  • 3-phase 4-wire 400 V circuits (i.e. with neutral) and
  • 1-phase 2-wire 230 V circuits

protected by general-purpose circuit-breakers. In other cases, apply correction factors (given in Figure G53) to the lengths obtained. The calculations are based on the above methods, and a short-circuit trip level within ± 20% of the adjusted value Im. For the 50 mm2 c.s.a., calculation are based on a 47.5 mm2 real c.s.a.



Operating current level Im of the instantaneous magnetic tripping
element (in A)
c.s.a. (nominal cross-sectional-area) of conductors (in mm2)
  1.5 2.5 4 6 10 16 25 35 50 70 95 120 150 185 240
50 100 167 267 400                      
63 79 133 212 317                      
80 63 104 167 250 417                    
100 50 83 133 200 333                    
125 40 67 107 160 267 427                  
160 31 52 83 125 208 333                  
200 25 42 67 100 167 267 417                
250 20 33 53 80 133 213 333 467              
320 16 26 42 63 104 167 260 365 495            
400 13 21 33 50 83 133 208 292 396            
500 10 17 27 40 67 107 167 233 317            
560 9 15 24 36 60 95 149 208 283 417          
630 8 13 21 32 63 85 132 185 251 370          
700 7 12 19 29 48 76 119 167 226 333 452        
800 6 10 17 25 42 67 104 146 198 292 396        
875 6 10 15 23 38 61 95 133 181 267 362 457      
1000 5 8 13 20 33 53 83 117 158 233 317 400 435    
1120 4 7 12 18 30 48 74 104 141 208 283 357 388 459  
1250 4 7 11 16 27 43 67 93 127 187 253 320 348 411  
1600   5 8 13 21 33 52 73 99 146 198 250 272 321 400
2000   4 7 10 17 27 42 58 79 117 158 200 217 257 320
2500     5 8 13 21 33 47 63 93 127 160 174 206 256
3200     4 6 10 17 26 36 49 73 99 125 136 161 200
4000       5 8 13 21 29 40 58 79 100 109 128 160
5000       4 7 11 17 23 32 47 63 80 87 103 128
6300         5 8 13 19 25 37 50 63 69 82 102
8000         4 7 10 15 20 29 40 50 54 64 80
10000           5 8 12 16 23 32 40 43 51 64
12500           4 7 9 13 19 25 32 35 41 51










































Fig. G47: Maximum circuit lengths in metres for copper conductors (for aluminium, the lengths must be multiplied by 0.62)


Figures G48 to G50 give maximum circuit length (Lmax) in metres for:

  • 3-phase 4-wire 400 V circuits (i.e. with neutral) and
  • 1-phase 2-wire 230 V circuits

protected in both cases by domestic-type circuit-breakers or with circuit-breakers having similar tripping/current characteristics. In other cases, apply correction factors to the lengths indicated. These factors are given in Figure G51.

Rated current of circuit-breakers (in A)  c.s.a. (nominal cross-sectional-area) of conductors (in mm2)
1.5 2.5 4 6 10 16 25 35 50
6 200 333 533 800          
10 120 200 320 480 800        
16 75 125 200 300 500 800      
20 60 100 160 240 400 640      
25 48 80 128 192 320 512 800    
32 37 62 100 150 250 400 625 875  
40 30 50 80 120 200 320 500 700  
50 24 40 64 96 160 256 400 560 760
63 19 32 51 76 127 203 317 444 603
80 15 25 40 60 100 160 250 350 475
100 12 20 32 48 80 128 200 280 380
125 10 16 26 38 64 102 160 224 304



















Fig. G48: Maximum length of copper-conductor circuits in metres protected by B-type circuit-breakers



Rated current of circuit-breakers (in A)
 
c.s.a. (nominal cross-sectional-area) of conductors (in mm2)
1.5 2.5 4 6 10 16 25 35 50
6 100 167 267 400 667        
10 60 100 160 240 400 640      
16 37 62 100 150 250 400 625 875  
20 30 50 80 120 200 320 500 700  
25 24 40 64 96 160 256 400 560 760
32 18.0 31 50 75 125 200 313 438 594
40 15.0 25 40 60 100 160 250 350 475
50 12.0 20 32 48 80 128 200 280 380
63 9.5 16.0 26 38 64 102 159 222 302
80 7.5 12.5 20 30 50 80 125 175 238
100 6.0 10.0 16.0 24 40 64 100 140 190
125 5.0 8.0 13.0 19.0 32 51 80 112 152



















Fig. G49: Maximum length of copper-conductor circuits in metres protected by C-type circuit-breakers



Rated current of circuit-breakers (in A)
 
c.s.a. (nominal cross-sectional-area) of conductors (in mm2)
1.5 2.5 4 6 10 16 25 35 50
1 429 714              
2 214 357 571 857          
3 143 238 381 571 952        
4 107 179 286 429 714        
6 71 119 190 286 476 762      
10 43 71 114 171 286 457 714    
16 27 45 71 107 179 286 446 625 848
20 21 36 57 86 143 229 357 500 679
25 17.0 29 46 69 114 183 286 400 543
32 13.0 22 36 54 89 143 223 313 424
40 11.0 18.0 29 43 71 114 179 250 339
50 9.0 14.0 23 34 57 91 143 200 271
63 7.0 11.0 18.0 27 45 73 113 159 215
80 5.0 9.0 14.0 21 36 57 89 125 170
100 4.0 7.0 11.0 17.0 29 46 71 100 136
125 3.0 6.0 9.0 14.0 23 37 57 80 109
























Fig. G50: Maximum length of copper-conductor circuits in metres protected by D-type circuit-breakers



Circuit detail
3-phase 3-wire 400 V circuit or 1-phase 2-wire 400 V circuit (no neutral)   1.73
1-phase 2-wire (phase and neutral) 230 V circuit   1
3-phase 4-wire 230/400 V circuit or 2-phase 3-wire 230/400 V circuit (i.e with neutral) Sph / S neutral = 1 1
Sph / S neutral = 2 0.67








Fig. G51: Correction factor to apply to lengths obtained from Figures G47 to G50


Note: IEC 60898 accepts an upper short-circuit-current tripping range of 10-50 In for type D circuit-breakers. European standards, and Figure G50 however, are based on a range of 10-20 In, a range which covers the vast majority of domestic and similar installations.

Examples

Example 1

In a 1-phase 2-wire installation the protection is provided by a 50 A circuit-breaker type NSX80HMA, the instantaneous short-circuit current trip, is set at 500 A (accuracy of ± 20%), i.e. in the worst case would require 500 x 1,2 = 600 A to trip. The cable c.s.a. = 10 mm2 and the conductor material is copper.
In Figure G47, the row Im = 500 A crosses the column c.s.a. = 10 mm2 at the value for Lmax of 67 m. The circuit-breaker protects the cable against short-circuit faults, therefore, provided that its length does not exceed 67 metres.
Example 2
In a 3-phase 3-wire 400 V circuit (without neutral), the protection is provided by a 220 A circuit-breaker type NSX250N with an instantaneous short-circuit current trip unit type MA set at 2,000 A (± 20%), i.e. a worst case of 2,400 A to be certain of tripping. The cable c.s.a. = 120 mm2 and the conductor material is copper.
In Figure G47 the row Im = 2,000 A crosses the column c.s.a. = 120 mm2 at the value for Lmax of 200 m. Being a 3-phase 3-wire 400 V circuit (without neutral), a correction factor from Figure G51 must be applied. This factor is seen to be 1.73.
The circuit-breaker will therefore protect the cable against short-circuit current, provided that its length does not exceed 200 x 1.73= 346 metres.


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