Downstream LV network protection: Difference between revisions

From Electrical Installation Guide
m (r2.7.2) (robot Adding: zh:下游低压网络保护)
m (Text replacement - "\[\[ru:[^]]*\]\][ \r\n]*" to "")
 
(11 intermediate revisions by 4 users not shown)
Line 1: Line 1:
{{Menu_Characteristics_of_particular_sources_and_loads}}
{{Menu_Characteristics_of_particular_sources_and_loads}}__TOC__
<br>
__TOC__
 
== Priority circuit protection  ==
== Priority circuit protection  ==


'''Choice of breaking capacity'''
=== Choice of breaking capacity ===


This must be systematically checked with the characteristics of the main source (MV/LV transformer).  
This must be systematically checked with the characteristics of the main source (MV/LV transformer).  


'''Setting of the Short Time Delay (STD) tripping current'''
=== Setting of the Short Time Delay (STD) tripping current ===


*Subdistribution boards
*Subdistribution boards
 
: The ratings of the protection devices for the subdistribution and final distribution circuits are always lower than the generator rated current. Consequently, except in special cases, conditions are the same as with transformer supply.  
The ratings of the protection devices for the subdistribution and final distribution circuits are always lower than the generator rated current. Consequently, except in special cases, conditions are the same as with transformer supply.  
 
*Main LV switchboard
*Main LV switchboard
:* The sizing of the main feeder protection devices is normally similar to that of the generator set. Setting of the STD must allow for the short-circuit characteristic of the generator set (see “Short-circuit current protection” before)
:* Selectivity of protection devices on the priority feeders must be provided in generator set operation (it can even be compulsory for safety feeders). It is necessary to check proper staggering of STD setting of the protection devices of the main feeders with that of the subdistribution protection devices downstream (normally set for distribution circuits at 10 In).


&nbsp; -&nbsp; The sizing of the main feeder protection devices is normally similar to that of the generator set. Setting of the STD must allow for the <br>&nbsp;&nbsp;&nbsp;&nbsp; short-circuit characteristic of the generator set (see “Short-circuit current protection” before)<br>&nbsp; -&nbsp; Discrimination of protection devices on the priority feeders must be provided in generator set operation (it can even be compulsory for&nbsp;<br>&nbsp;&nbsp;&nbsp;&nbsp; safety feeders). It is necessary to check proper staggering of STD setting of the protection devices of the main feeders with that of the <br>&nbsp;&nbsp;&nbsp;&nbsp; subdistribution protection devices downstream (normally set for distribution circuits at 10 In).<br>Note: When operating on the generator set, use of a low sensitivity Residual Current Device enables management of the insulation fault and ensures very simple discrimination.<br>
'''Note''': When operating on the generator set, use of a low sensitivity Residual Current Device enables management of the insulation fault and ensures very simple selectivity.


== Safety of people  ==
== Safety of people  ==
Line 23: Line 20:
In the IT (2<sup>nd</sup> fault) and TN grounding systems, protection of people against indirect contacts is provided by the STD protection of circuit-breakers. Their operation on a fault must be ensured, whether the installation is supplied by the main source (Transformer) or by the replacement source (generator set).  
In the IT (2<sup>nd</sup> fault) and TN grounding systems, protection of people against indirect contacts is provided by the STD protection of circuit-breakers. Their operation on a fault must be ensured, whether the installation is supplied by the main source (Transformer) or by the replacement source (generator set).  


'''Calculating the insulation fault current'''
=== Calculating the insulation fault current ===
 
Zero-sequence reactance formulated as a% of Uo by the manufacturer x’o. The typical value is 8%.
 
The phase-to-neutral single-phase short-circuit current is given by:


Zero-sequence reactance formulated as a% of Uo by the manufacturer x’o. The typical value is 8%.<br>The phase-to-neutral single-phase short-circuit current is given by:<br><math>If=\frac{Un \sqrt 3}{2\ X^'d + X'o}</math> <br>The insulation fault current in the TN system is slightly greater than the three phase fault current. For example, in event of an insulation fault on the system in the previous example, the insulation fault current is equal to 3 kA.<br>
<math>If=\frac{Un \sqrt 3}{2\ X^{'}d + X^{'}o}</math>  


[[ru:Защита отходящих низковольтных сетей]]
The insulation fault current in the TN system is slightly greater than the three phase fault current. For example, in event of an insulation fault on the system in the previous example, the insulation fault current is equal to 3 kA.
[[zh:下游低压网络保护]]

Latest revision as of 09:49, 22 June 2022

Priority circuit protection

Choice of breaking capacity

This must be systematically checked with the characteristics of the main source (MV/LV transformer).

Setting of the Short Time Delay (STD) tripping current

  • Subdistribution boards
The ratings of the protection devices for the subdistribution and final distribution circuits are always lower than the generator rated current. Consequently, except in special cases, conditions are the same as with transformer supply.
  • Main LV switchboard
  • The sizing of the main feeder protection devices is normally similar to that of the generator set. Setting of the STD must allow for the short-circuit characteristic of the generator set (see “Short-circuit current protection” before)
  • Selectivity of protection devices on the priority feeders must be provided in generator set operation (it can even be compulsory for safety feeders). It is necessary to check proper staggering of STD setting of the protection devices of the main feeders with that of the subdistribution protection devices downstream (normally set for distribution circuits at 10 In).

Note: When operating on the generator set, use of a low sensitivity Residual Current Device enables management of the insulation fault and ensures very simple selectivity.

Safety of people

In the IT (2nd fault) and TN grounding systems, protection of people against indirect contacts is provided by the STD protection of circuit-breakers. Their operation on a fault must be ensured, whether the installation is supplied by the main source (Transformer) or by the replacement source (generator set).

Calculating the insulation fault current

Zero-sequence reactance formulated as a% of Uo by the manufacturer x’o. The typical value is 8%.

The phase-to-neutral single-phase short-circuit current is given by:

[math]\displaystyle{ If=\frac{Un \sqrt 3}{2\ X^{'}d + X^{'}o} }[/math]

The insulation fault current in the TN system is slightly greater than the three phase fault current. For example, in event of an insulation fault on the system in the previous example, the insulation fault current is equal to 3 kA.

Share