EMC implementation - Communication networks: Difference between revisions

From Electrical Installation Guide
Home > ElectroMagnetic Compatibility (EMC) > EMC implementation > EMC implementation - Communication networks
(cleaned up source: table format, etc ...)
m (Text replacement - "\[\[ru:[^]]*\]\][ \r\n]*" to "")
 
(12 intermediate revisions by 4 users not shown)
Line 1: Line 1:
{{Menu_EMC_guidelines}}
{{Menu_EMC_guidelines}}
__TOC__
It is highly recommended to follow the European Standards EN 50173 series to perform Information Technology cablings.
It is highly recommended to follow the European Standards EN 50173 series to perform Information Technology cablings.


Line 14: Line 12:
Communication networks are mostly extensive. They interconnect equipment located in different areas where the feeding power supplies could have different earthing systems.
Communication networks are mostly extensive. They interconnect equipment located in different areas where the feeding power supplies could have different earthing systems.


[[File:Fig_R17_2013.jpg|none|700px]]
{{FigImage|DB422781_EN|svg|R19|How to reduce disturbing currents loop}}
'''''Fig. R17 :''''' ''How to reduce disturbing currents loop''


If these different areas are not well equipotential, harsh transient currents could appear (lightning, main power fault, etc.) causing high voltage potential differences between interconnected equipment.
If these different areas are not well equipotential, harsh transient currents could appear (lightning, main power fault, etc.) causing high voltage potential differences between interconnected equipment.
Line 33: Line 30:
AC and mostly DC Coils (relay, contactor, actuator, etc.) are very disturbing sources.
AC and mostly DC Coils (relay, contactor, actuator, etc.) are very disturbing sources.


[[File:Fig_R18_2013.jpg|none]]
{{FigImage|DB422782|svg|R20|TVS reduces the arcing voltage}}
'''''Fig. R18 :''''' ''TVS reduces the arcing voltage''


To minimize these High Frequency disturbances the following solutions could be implemented. '''(In grey, the preferred choice).'''
To minimize these High Frequency disturbances the following solutions could be implemented. '''(In grey, the preferred choice).'''


{| class="wikitable" style="width: 770px; height: 201px" width="770"
{{tb-start|id=Tab1441|num=R21|title=TVS table information|cols=4}}
{| class="wikitable"
|-
|-
! Symbol  
! Symbol  
! Transient Voltage <br> Suppression type  
! Transient Voltage  
! '''For AC
Suppression type  
! For AC
! For DC  
! For DC  
! Overvoltage limitation
! Overvoltage limitation
! Contact fall time
! Contact fall time
|-
|-
| {{Table_HC2}} | [[File:Fig_R19a.jpg|none]]
| {{tb-HC2}} style="text-align:center;" | [[File:DB422783.png]]
| {{Table_HC2}} | R-C network  
| {{tb-HC2}} | R-C network  
| {{Table_HC2}} | Y
| {{tb-HC2}} | Y
| {{Table_HC2}} | Y
| {{tb-HC2}} | Y
| {{Table_HC2}} | 2 to 3 . Un
| {{tb-HC2}} | 2 to 3 . Un
| {{Table_HC2}} | 1 to 2 times the standard time
| {{tb-HC2}} | 1 to 2 times the standard time
|-
|-
| {{Table_HC2}} | [[File:Fig_R19b.jpg|none]]
| {{tb-HC2}} style="text-align:center;" | [[File:DB422784.png]]
| {{Table_HC2}} | Metal Oxide Varistor
| {{tb-HC2}} | Metal Oxide Varistor
| {{Table_HC2}} | Y
| {{tb-HC2}} | Y
| {{Table_HC2}} | Y
| {{tb-HC2}} | Y
| {{Table_HC2}} | < 3 . Un
| {{tb-HC2}} | < 3 . Un
| {{Table_HC2}} | 1.1 to 1.5 times the standard time
| {{tb-HC2}} | 1.1 to 1.5 times the standard time
|-
|-
| {{Table_HC2}} | [[File:Fig_R19c.jpg|none]]
| {{tb-HC2}} style="text-align:center;" | [[File:DB422785.png]]
| {{Table_HC2}} | Transient Voltage Suppression Diode Bidirectional
| {{tb-HC2}} | Transient Voltage  
| {{Table_HC2}} | Y
Suppression Diode <br>
| {{Table_HC2}} | Y
Bidirectional
| {{Table_HC2}} | < 2. Un
| {{tb-HC2}} | Y
| {{Table_HC2}} | 1.1 to 1.5 times the standard time
| {{tb-HC2}} | Y
| {{tb-HC2}} | < 2. Un
| {{tb-HC2}} | 1.1 to 1.5 times the standard time
|-
|-
| [[File:Fig_R19d.jpg|none]]
| style="text-align:center;" | [[File:DB422786.png]]
| Transient Voltage Suppression Diode Directional
| Transient Voltage  
Suppression Diode <br>
Directional
| N
| N
| Y
| Y
Line 75: Line 77:
| 3 to 10 times the standard time
| 3 to 10 times the standard time
|-
|-
| [[File:Fig_R19e.jpg|none]]
| style="text-align:center;" | [[File:DB422787.png]]
| Free wheeling diode
| Free wheeling diode
| N
| N
Line 82: Line 84:
| 3 to 10 times the standard time
| 3 to 10 times the standard time
|-
|-
| [[File:Fig_R19f.jpg|none]]
| style="text-align:center;" | [[File:DB422788.png]]
| Resistor
| Resistor
| Y
| Y
Line 89: Line 91:
| 1.5 to 2.5 times the standard time
| 1.5 to 2.5 times the standard time
|}
|}
'''''Fig. R19:''''' ''TVS table information''


To be efficient, the TVS shall be installed closely to the coil.
To be efficient, the TVS shall be installed closely to the coil.
[[ru:Конструктивное исполнение ЭМС - сети связи]]
[[zh:电磁兼容实施 - 通信网络]]

Latest revision as of 09:48, 22 June 2022

It is highly recommended to follow the European Standards EN 50173 series to perform Information Technology cablings.

To ensure a reliable data transmission, the quality of the whole link shall be homogeneous. That means the category of the different cables shall be the same, the connecting interfaces shall be adapted to the cables.

Cables and connections of different categories may be mixed within a channel however the resultant performance will be determined by the category of the lowest performing component.

The shield continuity of the whole link (patch cords, Terminal Outlets, horizontal cable) shall be ensured and controlled by tests.

The Terminal Outlets (TO) could be used to earth the screen terminations in the cabinet. The choice of these TO is very important.

Communication networks are mostly extensive. They interconnect equipment located in different areas where the feeding power supplies could have different earthing systems.

Fig. R19 – How to reduce disturbing currents loop

If these different areas are not well equipotential, harsh transient currents could appear (lightning, main power fault, etc.) causing high voltage potential differences between interconnected equipment.

Communication interfaces (board, module, etc.) could be disturbed or damaged by this common mode over voltages.

The use of TN-S earthing system and well equipotential installation minimize this issue.

In any case, the use of Surge Protective Device (SPD) installed in Common Mode and/or Differential Mode is recommended.

If the different areas/zones are not equipotential, if the power supply earthing system is TN-C or IT, or if there is a doubt and the previous 2 points, optical fiber links are highly recommended.

To avoid electrical safety issue, the optical fiber link should not have any metallic parts.

Protection against coils disturbances

AC and mostly DC Coils (relay, contactor, actuator, etc.) are very disturbing sources.

Fig. R20 – TVS reduces the arcing voltage

To minimize these High Frequency disturbances the following solutions could be implemented. (In grey, the preferred choice).

Fig. R21 – TVS table information
Symbol Transient Voltage

Suppression type

For AC For DC Overvoltage limitation Contact fall time
DB422783.png R-C network Y Y 2 to 3 . Un 1 to 2 times the standard time
DB422784.png Metal Oxide Varistor Y Y < 3 . Un 1.1 to 1.5 times the standard time
DB422785.png Transient Voltage

Suppression Diode
Bidirectional

Y Y < 2. Un 1.1 to 1.5 times the standard time
DB422786.png Transient Voltage

Suppression Diode
Directional

N Y Un + 0.7 V 3 to 10 times the standard time
DB422787.png Free wheeling diode N Y Un + 0.7 V 3 to 10 times the standard time
DB422788.png Resistor Y Y < 4 . Un 1.5 to 2.5 times the standard time

To be efficient, the TVS shall be installed closely to the coil.

Share