The components of a SPD: Difference between revisions
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The SPD chiefly consists of (see {{FigRef|J50}}): | |||
'''1)''' one or more nonlinear components: the live part (varistor, gas discharge tube, etc.); | |||
'''2)''' a thermal protective device (internal disconnector) which protects it from thermal runaway at end of life (SPD with varistor); | |||
'''3)''' an indicator which indicates end of life of the SPD; | |||
: Some SPDs allow remote reporting of this indication; | |||
'''4)''' an external SCPD which provides protection against short circuits (this device can be integrated into the SPD). | |||
{{FigImage|DB422510|svg|J50|Diagram of a SPD}} | |||
== Technology of the live part == | |||
== Technology of the live part | |||
Several technologies are available to implement the live part. They each have advantages and disadvantages: | Several technologies are available to implement the live part. They each have advantages and disadvantages: | ||
*Zener diodes; | *Zener diodes; | ||
*The gas discharge tube (controlled or not controlled); | *The gas discharge tube (controlled or not controlled); | ||
Line 21: | Line 22: | ||
The table below shows the characteristics and the arrangements of 3 commonly used technologies. | The table below shows the characteristics and the arrangements of 3 commonly used technologies. | ||
- | {{tb-start|id=Tab1302|num=J51|title=Summary performance table|cols=5}} | ||
{| class="wikitable" | |||
{| class="wikitable | |||
|- | |- | ||
! Component | ! Component | ||
! Gas Discharge Tube (GDT) | ! Gas Discharge Tube (GDT) | ||
! Encapsulated spark gap | ! Encapsulated spark gap | ||
! Zinc oxide varistor | ! Zinc oxide varistor | ||
! GDT and varistor in series | ! GDT and varistor in series | ||
! Encapsulated spark gap and varistor in parallel | ! Encapsulated spark gap and varistor in parallel | ||
|- | |- | ||
| {{ | | {{tb-HC2}} | '''Characteristics''' | ||
! | ! | ||
! | ! | ||
! | ! | ||
! | ! | ||
! | ! | ||
|- | |- | ||
| {{ | | {{tb-HC2}} | | ||
| valign="middle" | [[File: | | valign="middle" | [[File:DB422511.png]] | ||
| valign="middle" | [[File: | | valign="middle" | [[File:DB422512.png]] | ||
| [[File: | | [[File:DB422513.png]] | ||
| [[File: | | [[File:DB422514.png]] | ||
| [[File: | | [[File:DB422515.png]] | ||
|- | |- | ||
| {{ | | {{tb-HC2}} | '''Operating mode''' | ||
| Voltage switching | | Voltage switching | ||
| Voltage switching | | Voltage switching | ||
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| Voltage-switching and -limiting in parallel | | Voltage-switching and -limiting in parallel | ||
|- | |- | ||
| {{ | | {{tb-HC2}} | '''Operating curves''' | ||
| valign="middle" align="center" colspan="2" | [[File: | | valign="middle" align="center" colspan="2" | [[File:DB422516.png]] | ||
| valign="middle" align="center" | [[File: | | valign="middle" align="center" | [[File:DB422517.png]] | ||
| {{ | | {{tb-HC2}} | | ||
| {{ | | {{tb-HC2}} | | ||
|- | |- | ||
| {{ | | {{tb-HC2}} | '''Application''' | ||
| | | | ||
*Telecom network | *Telecom network | ||
Line 73: | Line 71: | ||
| LV network | | LV network | ||
|- | |- | ||
| {{ | | {{tb-HC2}} | '''SPD Type''' | ||
| Type 2 | | Type 2 | ||
| Type 1 | | Type 1 | ||
| Type 1 | | Type 1 or Type 2 | ||
| Type 1+ Type 2 | | Type 1+ Type 2 | ||
| Type 1+ Type 2 | | Type 1+ Type 2 | ||
|} | |} | ||
''' | '''Note:''' Two technologies can be installed in the same SPD (see {{FigRef|J52}}) | ||
{{Gallery|J52|The Schneider Electric brand iPRD SPD incorporates a gas discharge tube between neutral and earth and varistors between phase and neutral|| | |||
|PB116777.jpg|| | |||
|DB422518.svg||}} |
Latest revision as of 17:50, 20 December 2019
The SPD chiefly consists of (see Fig. J50):
1) one or more nonlinear components: the live part (varistor, gas discharge tube, etc.);
2) a thermal protective device (internal disconnector) which protects it from thermal runaway at end of life (SPD with varistor);
3) an indicator which indicates end of life of the SPD;
- Some SPDs allow remote reporting of this indication;
4) an external SCPD which provides protection against short circuits (this device can be integrated into the SPD).
Technology of the live part
Several technologies are available to implement the live part. They each have advantages and disadvantages:
- Zener diodes;
- The gas discharge tube (controlled or not controlled);
- The varistor (zinc oxide varistor).
The table below shows the characteristics and the arrangements of 3 commonly used technologies.
Note: Two technologies can be installed in the same SPD (see Fig. J52)