Detailed characteristics of the external SCPD: Difference between revisions

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== Current wave withstand  ==
== Current wave withstand  ==


The current wave withstand tests on external SCPDs show as follows:  
The current wave withstand tests on external SCPDs show as follows:  
*For a given rating and technology (NH or cylindrical fuse), the current wave withstand capability is better with an aM type fuse (motor protection) than with a gG type fuse (general use).  
*For a given rating and technology (NH or cylindrical fuse), the current wave withstand capability is better with an aM type fuse (motor protection) than with a gG type fuse (general use).  
*For a given rating, the current wave withstand capability is better with a circuit breaker than with a fuse device.
*For a given rating, the current wave withstand capability is better with a circuit breaker than with a fuse device.


'''Figure J50 '''below shows the results of the voltage wave withstand tests:  
{{FigureRef|J56}} below shows the results of the voltage wave withstand tests:  
 
*to protect a SPD defined for Imax = 20 kA, the external SCPD to be chosen is either a MCB 16 A or a Fuse aM 63 A,
*to protect a SPD defined for Imax = 20 kA, the external SCPD to be chosen is either a MCCB 16 A or a Fuse aM 63 A,
:'''Note:''' in this case, a Fuse gG 63 A is not suitable.  
 
*to protect a SPD defined for Imax = 40 kA, the external SCPD to be chosen is either a MCB 40 A or a Fuse aM 125 A,
Note: in this case, a Fuse gG 63 A is not suitable.  
 
*to protect a SPD defined for Imax = 40 kA, the external SCPD to be chosen is either a MCCB 63 A or a Fuse aM 125 A,
 
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<br>[[Image:Fig J50.jpg|left]] <br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br>
 
'''''Fig. J50:''' Comparison of SCPDs voltage wave withstand capabilities for Imax = 20 kA and Imax = 40 kA''


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{{FigImage|DB422521_EN|svg|J56|Comparison of SCPDs voltage wave withstand capabilities for Imax {{=}} 20 kA and Imax {{=}} 40 kA}}


== Installed Up voltage protection level<br> ==
== Installed Up voltage protection level ==


In general:  
In general:  
*The voltage drop across the terminals of a circuit breaker is higher than that across the terminals of a fuse device. This is because the impedance of the circuit-breaker components (thermal and magnetic tripping devices) is higher than that of a fuse.


*The voltage drop across the terminals of a circuit breaker is higher than that across the terminals of a fuse device. This is because the impedance of the circuit-breaker components (thermal and magnetic tripping devices) is higher than that of a fuse.However:
However:
 
*The difference between the voltage drops remains slight for current waves not exceeding 10 kA (95% of cases);  
*The difference between the voltage drops remains slight for current waves not exceeding 10 kA (95% of cases);  
*The installed Up voltage protection level also takes into account the cabling impedance. This can be high in the case of a fuse technology (protection device remote from the SPD) and low in the case of a circuit-breaker technology (circuit breaker close to, and even integrated into the SPD).
*The installed Up voltage protection level also takes into account the cabling impedance. This can be high in the case of a fuse technology (protection device remote from the SPD) and low in the case of a circuit-breaker technology (circuit breaker close to, and even integrated into the SPD).
 
: '''Note''': The installed Up voltage protection level is the sum of the voltage drops:
Note: The installed Up voltage protection level is the sum of the voltage drops:<br>&nbsp; - in the SPD;<br>&nbsp; - in the external SCPD;<br>&nbsp; - in the equipment cabling  
:* in the SPD;
:* in the external SCPD;
:* in the equipment cabling


== Protection from impedant short circuits  ==
== Protection from impedant short circuits  ==


An impedant short circuit dissipates a lot of energy and should be eliminated very quickly to prevent damage to the installation and to the SPD.<br>'''Figure J51 '''compares the response time and the energy limitation of a protection system by a 63 A aM fuse and a 25 A circuit breaker.<br>These two protection systems have the same 8/20 µs current wave withstand capability (27 kA and 30 kA respectively).
An impedant short circuit dissipates a lot of energy and should be eliminated very quickly to prevent damage to the installation and to the SPD.
 
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<br>[[Image:Fig J51.jpg|left]] <br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br>'''''Fig. J51:''' Comparison of time/current and energy limitations curves for a circuit breaker and a fuse having the same 8/20 µs current wave withstand capability''
{{FigureRef|J57}} compares the response time and the energy limitation of a protection system by a 63 A aM fuse and a 25 A circuit breaker.


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These two protection systems have the same 8/20 µs current wave withstand capability (27 kA and 30 kA respectively).


[[zh:外部短路保护器的详细特征]]
{{FigImage|DB422522_EN|svg|J57|Comparison of time/current and energy limitations curves for a circuit breaker and a fuse having the same 8/20 µs current wave withstand capability}}

Latest revision as of 17:50, 20 December 2019

Current wave withstand

The current wave withstand tests on external SCPDs show as follows:

  • For a given rating and technology (NH or cylindrical fuse), the current wave withstand capability is better with an aM type fuse (motor protection) than with a gG type fuse (general use).
  • For a given rating, the current wave withstand capability is better with a circuit breaker than with a fuse device.

Figure J56 below shows the results of the voltage wave withstand tests:

  • to protect a SPD defined for Imax = 20 kA, the external SCPD to be chosen is either a MCB 16 A or a Fuse aM 63 A,
Note: in this case, a Fuse gG 63 A is not suitable.
  • to protect a SPD defined for Imax = 40 kA, the external SCPD to be chosen is either a MCB 40 A or a Fuse aM 125 A,
Fig. J56 – Comparison of SCPDs voltage wave withstand capabilities for Imax = 20 kA and Imax = 40 kA

Installed Up voltage protection level

In general:

  • The voltage drop across the terminals of a circuit breaker is higher than that across the terminals of a fuse device. This is because the impedance of the circuit-breaker components (thermal and magnetic tripping devices) is higher than that of a fuse.

However:

  • The difference between the voltage drops remains slight for current waves not exceeding 10 kA (95% of cases);
  • The installed Up voltage protection level also takes into account the cabling impedance. This can be high in the case of a fuse technology (protection device remote from the SPD) and low in the case of a circuit-breaker technology (circuit breaker close to, and even integrated into the SPD).
Note: The installed Up voltage protection level is the sum of the voltage drops:
  • in the SPD;
  • in the external SCPD;
  • in the equipment cabling

Protection from impedant short circuits

An impedant short circuit dissipates a lot of energy and should be eliminated very quickly to prevent damage to the installation and to the SPD.

Figure J57 compares the response time and the energy limitation of a protection system by a 63 A aM fuse and a 25 A circuit breaker.

These two protection systems have the same 8/20 µs current wave withstand capability (27 kA and 30 kA respectively).

Fig. J57 – Comparison of time/current and energy limitations curves for a circuit breaker and a fuse having the same 8/20 µs current wave withstand capability
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