Configuration of LV circuits: Difference between revisions

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{{Menu_MV_and_LV_architecture_selection_guide}}
{{Menu_MV_and_LV_architecture_selection_guide}}
<br>
Main possible configurations (see figures '''D18 to D25'''):


*'''Radial single feeder configuration''': This is the reference configuration and the most simple. A load is connected to only one single source. This configuration provides a minimum level of availability, since there is no redundancy in case of power source failure.
Main possible configurations:  


----
* '''Single feeder configuration (fig.D20):''' This is the reference configuration and the most simple. A load is connected to one single source. This configuration provides a minimum level of availability, since there is no redundancy in case of power source failure.


[[File:FigD18.jpg|none]]
[[File:FigD18.jpg|none]]
'''''Fig. D18:'''&nbsp;Radial single feeder configuration''
'''Fig. D20:''' Single feeder configuration  


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* '''Parallel transformers configuration (fig.D21):''' The power supply is provided by more than 1 transformer generally connected in parallel to the same main LV switchboard.
 
*'''Two-pole configuration''': The power supply is provided by 2 transformers, connected to the same MV line. When the transformers are close, they are generally connected in parallel to the same MLVS.
 
----


[[File:FigD19.jpg|none]]
[[File:FigD19.jpg|none]]
'''''Fig. D19:'''&nbsp;Two-pole configuration''
'''Fig. D21:''' Parallel transformers configuration  
 
----
 
*'''Variant: two-pole with two ½ MLVS''': In order to increase the availability in case of failure of the busbars or authorize maintenance on one of the transformers, it is possible to split the MLVS into 2 parts, with a normally open link (NO). This configuration generally requires an Automatic Transfer Switch, (ATS).


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* '''Variant: Normally open coupled transformers (fig.D22):''' In order to increase the availability it is possible to split the main LV switchboard into 2 parts, with a normally open bus-coupler (NO). This configuration may require an Automatic Transfer Switch between the coupler and transformer incomers.


[[File:FigD20.jpg|none]]
[[File:FigD20.jpg|none]]
'''''Fig. D20:'''&nbsp;Two-pole configuration with two ½ MLVS and NO link''
'''Fig. D22:''' Normally open coupled transformers


----
* '''Main LV switchboard interconnected by a busway (fig D23):''' Transformers are physically distant, and operated in parallel. They are connected by a busway, the load can always be supplied in the case of failure of one of the sources. The redundancy can be:


*'''Shedable switchboard (simple disconnectable attachment)''': A series of shedable circuits can be connected to a dedicated switchboard. The connection to the MLVS is interrupted when needed (overload, generator operation, etc)
- Total: each transformer being able to supply all of the installation,<br>
- Partial: each transformer only being able to supply part of the installation. In this case, part of the loads must be disconnected (load-shedding) in the case of one of transformer failure.


----
[[File:FigD21.jpg|none]]
'''Fig. D23:''' Main LV switchboard interconnected by a busway


[[File:FigD21.jpg|none]]
* '''LV ring configuration (fig. D24):''' This configuration can be considered as an extension of the previous configuration with interconnection between switchboards. Typically, 4 transformers connected in parallel to the same MV line, supply a ring using busway. A given load is then supplied by several transformers. This configuration is well suited to large sites, with high load density (in kVA/m²). If all of the loads can be supplied by 3 transformers, there is total redundancy in the case of failure of one of the transformers. In fact, each busbar can be fed by one or other of its ends. Otherwise, downgraded operation must be considered (with partial load shedding). This configuration requires special design of the protection plan in order to ensure discrimination in all of the fault circumstances.
'''''Fig. D21:'''&nbsp;Shedable switchboard''


----
As the previous configuration this type of installation is commonly used in automotive industry or large site manufacturing industry.


*'''Interconnected switchboards''': If transformers are physically distant from one another, they may be connected by a bus<br>bar trunking. A critical load can be supplied by one or other of the transformers. The availability of power is therefore improved, since the load can always be supplied in the case of failure of one of the sources. <br>The redundancy can be:
* '''Double-ended power supply (fig. D25):''' This configuration is implemented in cases where maximum availability is required. The principle involves having 2 independent power sources, e.g.:


'''&nbsp;&nbsp;&nbsp; - '''Total: each transformer being capable of supplying all of the installation,<br>'''&nbsp;&nbsp;&nbsp; - '''Partial: each transformer only being able to supply part of the installation. In this case, part of the loads must be disconnected&nbsp;<br>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; (load-shedding) in the case of one of the transformers failing.  
- 2 transformers supplied by different MV lines,<br>
- 1 transformer and 1 generator,<br>
- 1 transformer and 1 UPS.


----
An automatic transfer switch (ATS) is used to avoid the sources being parallel connected. This configuration allows preventive and curative maintenance to be carried out on all of the electrical distribution system upstream without interrupting the power supply.


[[File:FigD22.jpg|none]]
[[File:FigD22.jpg|none]]
'''''Fig. D22:'''&nbsp;Interconnected switchboards''
'''Fig. D25:''' Double-ended configuration with automatic transfer switch


----
* '''Configuration combinations (fig D.26):''' An installation can be made up of several sub-asssemblies with different configurations, according to requirements for the availability of the different types of load. E.g.: generator unit and UPS, choice by sectors (some sectors supplied by cables and others by busways).
 
*'''Ring configuration''': This configuration can be considered as an extension of the configuration with interconnection between switchboards. Typically, 4 transformers connected to the same MV line, supply a ring using busbar trunking. A given load is then supplied power by several clustered transformers. This configuration is well suited to extended installations, with a high load density (in kVA/m²). If all of the loads can be supplied by 3 transformers, there is total redundancy in the case of failure of one of the transformers. In fact, each busbar can be fed power by one or other of its ends. Otherwise, downgraded operation must be considered (with partial load shedding). This configuration requires special design of the protection plan in order to ensure discrimination in all of the fault circumstances.
 
----


[[File:FigD23.jpg|none]]
[[File:FigD23.jpg|none]]
'''''Fig. D23:'''&nbsp;Ring configuration''
'''Fig. D26:''' Example of a configuration combination


----
1: Single feeder, 2: Main LV switchboard interconnected by a busway, 3: Double-ended


*'''Double-ended power supply''': This configuration is implemented in cases where maximum availability is required. The principle involves having 2 independent power sources, e.g.:
For the different possible configurations, the most probable and usual set of characteristics is given in the following table:
 
&nbsp;&nbsp; '''-''' 2 transformers supplied by different MV lines,<br>&nbsp;&nbsp; '''-''' 1 transformer and 1 generator,<br>&nbsp;&nbsp; '''- '''1 transformer and 1 UPS.<br>An automatic transfer switch (ATS) is used to avoid the sources being parallel connected. This configuration allows preventive and curative maintenance to be carried out on all of the electrical distribution system upstream without interrupting the power supply.
 
----
 
[[File:FigD24.jpg|none]]
'''''Fig. D24:'''&nbsp;Double-ended configuration with automatic transfer switch''
 
----
 
*'''Configuration combinations''': An installation can be made up of several sub-asssemblies with different configurations, according to requirements for the availability of the different types of load. E.g.: generator unit and UPS, choice by sectors (some sectors supplied by cables and others by busbar trunking).<br>
 
----
 
[[File:FigD25.jpg|none]]
'''''Fig. D25:'''&nbsp;Example of a configuration combination'' <br>''1: Single feeder, 2: Switchboard interconnection, 3: Double-ended''
 
----
 
For the different possible configurations, the most probable and usual set of characteristics is given in the following table:  
 
----
 
<br>


{| class="wikitable" width="819" style="width: 819px; height: 293px;"
{| class="wikitable" width="819" style="width: 819px; height: 293px;"
|-
|-
! rowspan="2" | <br>&nbsp;Characteristic to<br>&nbsp;be considered  
! rowspan="2" | Characteristic to be considered  
! colspan="6" | &nbsp;Configuration
! colspan="6" | Configuration
|-
|-
! &nbsp;Radial
! &nbsp;Single feeder (fig. D20)
! &nbsp;Two-pole
! &nbsp;Parallel transformer or transformers connected via a coupler (fig. D21-D22)
! Sheddable&nbsp;load
! Main LV switchboard interconnected by a busway (fig D24)
! &nbsp;Interconnected&nbsp;<br>&nbsp;switchboards
! &nbsp;LV ring
! &nbsp;Ring
! Double-ended
! Double-ended
|-
|-
Line 100: Line 64:
| Any  
| Any  
| Any  
| Any  
| 1 level 5000 to 25000 m²
| 1 level 5000 to 25000 m²
| Any
|-
| Power demand
| < 2500kVA
| Any
| ≥ 2500kVA
| > 2500kVA
| Any  
| Any  
| 1 level<br>5 to 25000m²
| 1 level<br>5 to 25000m²
| Any
|-
|-
| Location latitude  
| Location latitude  
| Any  
| Any  
| Any  
| Any  
| Any
| &nbsp;Medium or high
| Medium or high  
| Medium or high  
| Any
| Medium or high
|-
| Maintainability
| Minimal
| Standard
| Minimal
| &nbsp;Standard
| Standard
| Enhanced
|-
| Power demand
| &lt; 2500kVA
| Any  
| Any  
| Any
| &nbsp;≥ 1250kVA
| &nbsp;&gt; 2500kVA
| Any
|-
|-
| Load distribution  
| Load distribution  
| Localized loads
| Localized loads  
| Localized loads  
| Intermediate or uniform load distribution
| Intermediate or uniform load distribution
| Localized loads  
| Localized loads  
| Localized load
| Intermediate or <br>uniform distribution
| Uniform distribution
| Localized loads
|-
|-
| Interruptions&nbsp;sensitivity
| Maintainability
| Long interruption&nbsp;<br>acceptable
| Minimal
| Long interruption&nbsp;<br>acceptable
| Standard
| Sheddable
| Standard
| Long&nbsp; interruption<br>acceptable
| Standard
| Long interruption <br>acceptable
| Enhanced
| Short or no&nbsp;<br>interruption
|-
|-
| Disturbances sensitivity  
| Disturbances sensitivity  
| valign="middle" | Low sensitivity  
| Low sensitivity
| valign="middle" | High sensitivity  
| High sensitivity  
| valign="middle" | Low sensitivity
| High sensitivity  
| valign="middle" | High sensitivity  
| High sensitivity  
| valign="middle" | High sensitivity  
| High sensitivity  
| valign="middle" | High&nbsp;sensitivity
|-
|-
| Other constraints
| /
| /
| /
| /
| &nbsp;/
| Double-ended&nbsp;<br>loads
|}
|}
'''Fig. D27:''' Recommendations for the configuration of LV circuits


[[ru:Конфигурация цепей низкого напряжения]]
[[ru:Конфигурация цепей низкого напряжения]]
[[zh:低压回路的配置]]
[[zh:低压回路的配置]]

Revision as of 05:44, 8 December 2014


Main possible configurations:

  • Single feeder configuration (fig.D20): This is the reference configuration and the most simple. A load is connected to one single source. This configuration provides a minimum level of availability, since there is no redundancy in case of power source failure.
FigD18.jpg

Fig. D20: Single feeder configuration

  • Parallel transformers configuration (fig.D21): The power supply is provided by more than 1 transformer generally connected in parallel to the same main LV switchboard.
FigD19.jpg

Fig. D21: Parallel transformers configuration

  • Variant: Normally open coupled transformers (fig.D22): In order to increase the availability it is possible to split the main LV switchboard into 2 parts, with a normally open bus-coupler (NO). This configuration may require an Automatic Transfer Switch between the coupler and transformer incomers.
FigD20.jpg

Fig. D22: Normally open coupled transformers

  • Main LV switchboard interconnected by a busway (fig D23): Transformers are physically distant, and operated in parallel. They are connected by a busway, the load can always be supplied in the case of failure of one of the sources. The redundancy can be:

- Total: each transformer being able to supply all of the installation,
- Partial: each transformer only being able to supply part of the installation. In this case, part of the loads must be disconnected (load-shedding) in the case of one of transformer failure.

FigD21.jpg

Fig. D23: Main LV switchboard interconnected by a busway

  • LV ring configuration (fig. D24): This configuration can be considered as an extension of the previous configuration with interconnection between switchboards. Typically, 4 transformers connected in parallel to the same MV line, supply a ring using busway. A given load is then supplied by several transformers. This configuration is well suited to large sites, with high load density (in kVA/m²). If all of the loads can be supplied by 3 transformers, there is total redundancy in the case of failure of one of the transformers. In fact, each busbar can be fed by one or other of its ends. Otherwise, downgraded operation must be considered (with partial load shedding). This configuration requires special design of the protection plan in order to ensure discrimination in all of the fault circumstances.

As the previous configuration this type of installation is commonly used in automotive industry or large site manufacturing industry.

  • Double-ended power supply (fig. D25): This configuration is implemented in cases where maximum availability is required. The principle involves having 2 independent power sources, e.g.:

- 2 transformers supplied by different MV lines,
- 1 transformer and 1 generator,
- 1 transformer and 1 UPS.

An automatic transfer switch (ATS) is used to avoid the sources being parallel connected. This configuration allows preventive and curative maintenance to be carried out on all of the electrical distribution system upstream without interrupting the power supply.

FigD22.jpg

Fig. D25: Double-ended configuration with automatic transfer switch

  • Configuration combinations (fig D.26): An installation can be made up of several sub-asssemblies with different configurations, according to requirements for the availability of the different types of load. E.g.: generator unit and UPS, choice by sectors (some sectors supplied by cables and others by busways).
FigD23.jpg

Fig. D26: Example of a configuration combination

1: Single feeder, 2: Main LV switchboard interconnected by a busway, 3: Double-ended

For the different possible configurations, the most probable and usual set of characteristics is given in the following table:

Characteristic to be considered Configuration
 Single feeder (fig. D20)  Parallel transformer or transformers connected via a coupler (fig. D21-D22) Main LV switchboard interconnected by a busway (fig D24)  LV ring Double-ended
Site topology Any Any 1 level 5000 to 25000 m² 1 level 5000 to 25000 m² Any
Power demand < 2500kVA Any ≥ 2500kVA > 2500kVA Any
Location latitude Any Any Medium or high Medium or high Any
Load distribution Localized loads Localized loads Intermediate or uniform load distribution Intermediate or uniform load distribution Localized loads
Maintainability Minimal Standard Standard Standard Enhanced
Disturbances sensitivity Low sensitivity High sensitivity High sensitivity High sensitivity High sensitivity

Fig. D27: Recommendations for the configuration of LV circuits

ru:Конфигурация цепей низкого напряжения zh:低压回路的配置

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