Coordination of residual current protective devices: Difference between revisions

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Selectivity between RCDs is achieved either by time-delay or by subdivision of circuits, which are then protected individually or by groups, or by a combination of both methods.
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Discriminative-tripping coordination is achieved either by time-delay or by subdivision of circuits, which are then protected individually or by groups, or by a combination of both methods.<br>Such discrimination avoids the tripping of any RCD, other than that immediately upstream of a fault position:


*With equipment currently available, discrimination is possible at three or four different levels of distribution&nbsp;:
Such selectivity avoids the tripping of any RCD, other than that immediately upstream of a fault position.


&nbsp; - At the main general distribution board<br>&nbsp; - At local general distribution boards<br>&nbsp; - At sub-distribution boards<br>&nbsp; - At socket outlets for individual appliance protection  
Selectivity must be verified at all levels of the distribution, typically:
* At the main general distribution board
* At local general distribution boards
* At sub-distribution boards
* At socket outlets for individual appliance protection


*In general, at distribution boards (and sub-distribution boards, if existing) and on individual-appliance protection, devices for automatic disconnection in the event of an indirect-contact hazard occurring are installed together with additional protection against direct-contact hazards.<br>
The paragraphs below explain how to achieve selectivity between RCDs. But keep in mind that the sensitivity of the fault protection, if it is by RCD, must also be consistent with the maximum earthing resistance of the exposed and extraneous-conductive-parts of the equipment downstream of this RCD.


== Discrimination between RCDs ==
== Selectivity between RCDs ==


The general specification for achieving total discrimination between two RCDs is as follow:
Residual Current Devices are by design very sensitive to fault and shall be coordinated properly to achieve total selectivity, in addition to overcurrent protection selectivity.


*The ratio between the rated residual operating currents must be &gt; 2
Different types of RCDs are covered by different standard (IEC/EN 61009-1, IEC/EN 60947-2 Annex B or Annex M, IEC 61008). Anyway, whatever the type of RCD, the following rules apply to achieve selectivity between RCDs, as per IEC standards:
*Time delaying the upstream RCD
* the sensitivity of the upstream residual current device must be at least equal to three times the sensitivity of the downstream residual current device, and
* the upstream residual current device must be:
** of the selective (S) type (or setting) if the downstream residual current device is an instantaneous type,
** of the delayed (R) type (or setting) if the downstream residual current device is a selective type.
The minimum non-tripping time of the upstream device will therefore be greater than the maximum tripping time of the downstream device for all current values.


Discrimination is achieved by exploiting the several levels of standardized sensitivity: 30 mA, 100 mA, 300 mA and 1 A and the corresponding tripping times, as shown in '''Figure F34'''.  
{{FigureRef|F61}} is an example of application of these rules to achieve RCD selectivity with 3 levels.


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{{FigImage|DB422244_EN|svg|F61|Total selectivity at 3 levels}}
<br>
[[Image:FigF34.jpg|left]]
<br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br>
'''''Fig. F34:''' Total discrimination at 2 levels''


----
Some manufacturers propose RCD offers with a better earth leakage current measurement accuracy than the minimum required by standards. In that case, the sensitivity ratio to achieve selectivity between upstream and downstream RCDs may be lower than 3.


== Discrimination at 2 levels  ==
As an example, Schneider Electric offers VigiPacT and MicroLogic Vigi can be selective with ratios ranging from 1.25 to 2, depending on the other RCDs upstream/downstream. To know the exact values of applicable ratios for Schneider Electric RCD offers, refer to section "Selectivity of RCDs" in the latest '''[https://www.se.com/ww/en/download/document/LVPED318033EN/ "Complementary Technical Information - Selectivity, Cascading and Coordination Guide"]'''{{fn|1}}


(see '''Fig. F35''')<br>'''Protection'''
== Example of selectivity up to 4 levels ==


*Level A: RCD time-delayed setting I (for industrial device) or type S (for domestic device) for protection against indirect contacts
Example of installation with 4 levels of RCD selectivity ({{FigureRef|F62}}).
*Level B: RCD instantaneous, with high sensitivity on circuits supplying socket-outlets or appliances at high risk (washing machines, etc.)


'''Schneider Electric solutions'''
=== Protection ===


*Level A: Compact or Acti 9 circuit-breaker with adaptable RCD module (Vigicompact&nbsp;NSX160), setting I or S type
* Level 1: RCD time-delayed (setting III)
*Level B: Circuit-breaker with integrated RCD module (DPN Vigi) or adaptable RCD&nbsp;module (e.g. Vigi iC60) or Vigicompact NSX
* Level 2: RCD time-delayed (setting II)
* Level 3: RCD selective or time-delayed (setting I)
* Level 4: RCD instantaneous


Note: The setting of upstream RCCB must comply with selectivity rules and take into account all the downstream earth leakage currents.<br>
'''Note:''' The setting of upstream RCCB must comply with selectivity rules and take into account all the downstream earth leakage currents.


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{{FigImage|DB422247_EN|svg|F62|Example of installation with RCDs selectivity at 4 levels}}


<br>[[Image:FigF35.jpg|left]] <br><br><br><br><br><br><br><br><br><br>'''''Fig. F35: '''Total discrimination at 2 levels<br>''
{{footnotes}}
<references>
{{fn-detail|1|For more information on the different types and the selection of RCDs, you can also refer to the [https://www.se.com/ww/en/download/document/CA908066E/ Earth Fault Protection guide] }}
</references>


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{{Related-guides-intro}}
{{RelatedGuide
|image=Hp-highlight-selectivity-guide.png
|title=Selectivity, Cascading and Coordination Guide
|text=Get all required information to verify your electrical distribution design's robustness, considering overloads and short circuits.


== Discrimination at 3 or 4 levels  ==
Combine the benefits of selectivity and cascading to maximize power availability of your LV design at optimized cost.


(see '''Fig. F36''') <br>'''Protection'''
Find Schneider Electric's coordination data for ACBs, MCCBs, MCBs, switches, busbar trunking (busways), motor starters and more.
|btn-text=Download the guide (.pdf)
|link=https://www.se.com/ww/en/download/document/LVPED318033EN/
}}


*Level A: RCD time-delayed (setting III)
[[fr:Protection contre les chocs et incendies électriques]]
*Level B: RCD time-delayed (setting II)
[[de:Schutz gegen elektrischen Schlag]]
*Level C: RCD time-delayed (setting I) or type S
*Level D: RCD instantaneous
 
'''Schneider Electric solutions'''
 
*Level A: Circuit-breaker associated with RCD and separate toroidal transformer (Vigirex RH328AP)
*Level B: Vigicompact or Vigirex
*Level C: Vigirex, Vigicompact or Vigi NC100 or Vigi C60
*Level D:
 
&nbsp; - Vigicompact or<br>&nbsp; - Vigirex or<br>&nbsp; - Multi 9 with integrated or adaptable RCD module: Vigi C60 or DPN Vigi<br>Note: The setting of upstream RCCB must comply with selectivity rules and take into account all the downstream earth leakage currents<br>
 
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<br>[[Image:FigF36.jpg|left]] <br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br>'''''Fig. F36: '''Total discrimination at 3 or 4 levels''
 
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'''Discriminative protection at three levels''' (see '''Fig. F37''')
 
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<br>[[Image:FigF37.jpg|left]] <br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br>'''''Fig. F37: '''Typical 3-level installation, showing the protection of distribution circuits in a TT-earthed system. One motor is provided with specific protection''
 
[[ru:Система TT: координация устройств защиты от замыканий на землю]]
[[zh:TT系统剩余电流保护装置间的配合]]

Latest revision as of 08:36, 27 April 2022

Selectivity between RCDs is achieved either by time-delay or by subdivision of circuits, which are then protected individually or by groups, or by a combination of both methods.

Such selectivity avoids the tripping of any RCD, other than that immediately upstream of a fault position.

Selectivity must be verified at all levels of the distribution, typically:

  • At the main general distribution board
  • At local general distribution boards
  • At sub-distribution boards
  • At socket outlets for individual appliance protection

The paragraphs below explain how to achieve selectivity between RCDs. But keep in mind that the sensitivity of the fault protection, if it is by RCD, must also be consistent with the maximum earthing resistance of the exposed and extraneous-conductive-parts of the equipment downstream of this RCD.

Selectivity between RCDs

Residual Current Devices are by design very sensitive to fault and shall be coordinated properly to achieve total selectivity, in addition to overcurrent protection selectivity.

Different types of RCDs are covered by different standard (IEC/EN 61009-1, IEC/EN 60947-2 Annex B or Annex M, IEC 61008). Anyway, whatever the type of RCD, the following rules apply to achieve selectivity between RCDs, as per IEC standards:

  • the sensitivity of the upstream residual current device must be at least equal to three times the sensitivity of the downstream residual current device, and
  • the upstream residual current device must be:
    • of the selective (S) type (or setting) if the downstream residual current device is an instantaneous type,
    • of the delayed (R) type (or setting) if the downstream residual current device is a selective type.

The minimum non-tripping time of the upstream device will therefore be greater than the maximum tripping time of the downstream device for all current values.

Figure F61 is an example of application of these rules to achieve RCD selectivity with 3 levels.

Fig. F61 – Total selectivity at 3 levels

Some manufacturers propose RCD offers with a better earth leakage current measurement accuracy than the minimum required by standards. In that case, the sensitivity ratio to achieve selectivity between upstream and downstream RCDs may be lower than 3.

As an example, Schneider Electric offers VigiPacT and MicroLogic Vigi can be selective with ratios ranging from 1.25 to 2, depending on the other RCDs upstream/downstream. To know the exact values of applicable ratios for Schneider Electric RCD offers, refer to section "Selectivity of RCDs" in the latest "Complementary Technical Information - Selectivity, Cascading and Coordination Guide"[1]

Example of selectivity up to 4 levels

Example of installation with 4 levels of RCD selectivity (Figure F62).

Protection

  • Level 1: RCD time-delayed (setting III)
  • Level 2: RCD time-delayed (setting II)
  • Level 3: RCD selective or time-delayed (setting I)
  • Level 4: RCD instantaneous

Note: The setting of upstream RCCB must comply with selectivity rules and take into account all the downstream earth leakage currents.

Fig. F62 – Example of installation with RCDs selectivity at 4 levels

Notes

  1. ^ For more information on the different types and the selection of RCDs, you can also refer to the Earth Fault Protection guide
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