Some practical issues concerning MV distribution networks: Difference between revisions

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== Overhead networks  ==
== Overhead networks  ==


Weather conditions such as wind and frost may bring wires into contact and cause temporary (as opposed to permanent) short-circuits.<br>Ceramic or glass insulating materials may be broken by wind-borne debris or carelessly discharged firearms. Shorting to earth may also result when insulating material becomes heavily soiled.<br>Many of these faults are able to rectify themselves. For example, damaged insulating materials can continue functioning undetected in a dry environment, although heavy rain will probably cause flashover to earth (e.g. via a metallic support structure). Similarly, heavily soiled insulating material usually causes flashover to earth in damp conditions.<br>Almost invariably, fault current will take the form of an electric arc, whose intense heat dries the current’s path and, to some extent, re-establishes insulating properties. During this time, protection devices will normally have proved effective in eliminating the fault (fuses will blow or the circuit breaker will trip).<br>Experience has shown that, in the vast majority of cases, the supply can be restored by replacing fuses or reclosing the circuit breaker.<br>As such, it is possible to improve the service continuity of overhead networks significantly by using circuit breakers with an automated reclosing facility on the relevant feeders.<br>These automated facilities support a set number of reclosing operations if a first attempt proves unsuccessful. The interval between successive attempts can be adjusted (to allow time for the air near the fault to deionise) before the circuit breaker finally locks out after all the attempts (usually three) have failed.<br>Remote control switches can be used on cable segments within networks to further improve service continuity. Load-break switches can also be teamed with a reclosing circuit breaker to isolate individual sections.  
Weather conditions such as wind may bring overhead wires into contact and cause phase to phase short-circuits.


<br>
Over voltages due to lightning strokes may generate flash-over across ceramic or glass insulators and cause phase to earth faults


{| class="wikitable" style="width: 65%; height: 232px;"
Temporary contacts of vegetation such as trees with live overhead conductors may also generate phase to earth faults.
|-
 
| (1) A medium-voltage loop is an underground distribution network based on cables from two MV substation feeders. The two feeders are the two ‘ends’ of the loop and each is protected by an MV circuit breaker.<br>The loop is usually open, i.e. divided into two sections (half- loops), each of which is supplied by a feeder. To support this arrangement, the two incoming load-break switches on the substations in the loop are closed, allowing current to circulate around the loop. On one of the stations one switch is normally left open, determining the start of the loop. <br>A fault on one of the half-loops will trigger the protection device on the associated feeder, de-energising all substations within that half loop. Once the fault on the affected cable segment (between two adjacent substations) has been located, the supply to these substations can be restored from the other feeder. <br>This requires some reconfiguration of the loop, with the load-break switches being switched in order to move the start of the loop to the substation immediately downstream of the fault and open the switch on the substation immediately upstream of the fault on the loop. These measures isolate the cable segment where the fault has occurred and restore the supply to the whole loop, or to most of it if the switches that have been switched are not on substations on either side of the sole cable segment affected by the fault. <br>Systems for fault location and loop reconfiguration with remote control switches allow these processes to be automated.
Most of these faults are temporary. They disappear naturally with the interruption of the voltage. This means that the supply can be restored after a short delay following the tripping. This delay is usually named "dead time".
|}
 
Hence the sequence of fault clearing and voltage restoration in an overhead network is as follow:
 
* Fault detection by phase to phase or phase to earth protection
* Circuit breaker opening, the faulty over-head line is de-energized
* Dead time
* Circuit breaker reclosing. Following the reclosing two situations are possible:
- The fault has been cleared by the interruption of the voltage, the reclosing is successful
- The line is still faulty, a new tripping is initiated followed again by a reclosing sequence.
 
* Several sequences of tripping-reclosing may be activated depending on the rules of operation of the network adopted by the utility
* If after the execution of the preselected number of reclosing sequences the fault is still present, the circuit breaker is automatically locked and consequently the faulty part of the network remains out of service until the fault is localized and eliminated.


As such, it is possible to improve significantly the service continuity of overhead networks by using automatic reclosing facilities. Generally a reclosing circuit breaker is associated to each overhead line.


== Underground networks  ==
== Underground networks  ==


Cable faults on underground networks can sometimes be caused by poorly arranged cable boxes or badly laid cables. For the most part, however, faults are the result of damage caused by tools such as pickaxes and pneumatic drills or by earthmoving plant used by other public utilities.<br>Insulation faults sometimes occur in connection boxes as a result of overvoltage, particularly at locations where an MV network is connected to an underground cable network. In such cases, overvoltage is usually caused by atmospheric conditions, and the reflection effects of electromagnetic waves at the junction box (where circuit impedance changes sharply) may generate sufficient strain on the cable box insulation for a fault to occur.<br>Devices to protect against overvoltages, such as lightning arresters, are often installed at these locations.<br>Underground cable networks suffer from fewer faults than overhead networks, but those which do occur are invariably permanent and take longer to locate and resolve.<br>In the event of a fault affecting an MV loop cable, the supply can be quickly restored to users once the cable segment where the fault occurred has been located.<br>Having said this, if the fault occurs at a feeder for a radial supply, it can take several hours to locate and resolve the fault, and all the users connected in a single branch arrangement downstream of the fault will be affected.<br>In cases where service continuity is essential for all or part of the installation concerned, provision must be made for an auxiliary supply. <br>
Cable Faults on underground MV cables may have several causes such as:
 
* Poor quality of cable laying, absence of mechanical protection
* Bad quality of cable terminations confection
* Damages caused by excavators or tools such as pneumatic drills
* Over voltages generated by lightning strokes occurring on overhead line connected to underground cables. The over voltages can be amplified at the levels of the junctions between overhead lines and underground cables causing the destruction of the cable terminations. Lightning arresters, are often installed at these locations to limit the risks of damages.  
 
The experience shows that the rate of fault occurring on underground cables is lower than the one registered for overhead lines. But faults on underground cables are invariably permanent and take longer time to locate and repair.
 
A loop architecture (see '''Fig. B10)''' correctly instrumented with fault detectors and motorized load break switches allow within a short period of time to identify a faulty cable, to disconnect it and to restore the supply to the whole substations included in the loop.
 
These procedures of faults detection, cables disconnection and supply restoration can be automatically performed in less one minute by dedicated functions commonly integrated in remote control and monitoring systems of MV networks.


== Remote control and monitoring for MV network  ==
== Remote control and monitoring for MV network  ==
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Remote control and monitoring of MV feeders makes it possible to reduce loss of supply resulting from cable faults by supporting fast and effective loop reconfiguration. This facility relies on switches with electric controls which are fitted on a number of substations in the loop and linked to modified remote-control units. All stations containing this equipment can have their supply restored remotely, whereas other stations will require additional manual operations <br>
Remote control and monitoring of MV feeders makes it possible to reduce loss of supply resulting from cable faults by supporting fast and effective loop reconfiguration.
 
This facility relies on motorized switches associated with fault detectors on a number of substations in the loop and controlled by remote control units. All stations containing this equipment can have their supply restored remotely, whereas other stations will require additional manual operations.
 
 
'''''Fig. B7:''''' ''Supervisory Control And Data Acquisition System SCADA''
 
== Values of earth fault currents in MV networks ==
 
(see '''Fig. B8''' and '''Fig. B9''')
 
The values of earth fault currents in MV distribution networks depend on the MV neutral earthing system. These values must be limited to reduce their effects, mainly:


== Values of earth fault currents for MV power supply  ==
* Damages to equipment
* Temporary over voltages
* Transient over voltages
* Touch and step voltages.


The values of earth fault currents on distribution networks depend on the MV substation’s earthing system (or neutral earthing system). They must be limited to reduce their impact on the network and restrict possible increased potential on user substation frames caused by the coupling of earth switches (overhead networks), and to reduce flashover with the station’s LV circuits capable of generating dangerous levels of potential in the low voltage installation.<br>Where networks have both overhead and underground elements, an increased cable earthing capacitance value may cause the earth fault current value to rise and require measures to compensate this phenomenon. Earthing impedance will then involve reactance (a resistor in parallel with an inductor) in line with the leakage rate: the neutral earthing system is compensated. Compensatory impedance makes it possible to both:
The neutral of an MV network can be earthed by five different methods, according to type (resistive, inductive) and the value (zero to infinity) of the impedance Z<sub>n</sub> connected between the neutral and the earth:
 
* Z<sub>n</sub> = ∞ isolated neutral, no intentional neutral earthing connection
* Z<sub>n</sub> is related to a resistance with a fairly high value,
* Z<sub>n</sub> is related to a reactance, with a generally low value,
* Z<sub>n</sub> is related to a compensation reactance, designed to compensate the capacitance of the network
* Z<sub>n</sub> = 0: the neutral is solidly earthed.
 
{| class="wikitable"
|-
! rowspan = '2' |
! colspan = '6' |Methods of Neutral Earthing
|-
! Isolated
! Resistance
! Reactance
! Compensated
! Solid
|-
| Damages
| Very low
| Low
| Low
| Very low
| Very high
|-
| Temporary over voltages
| High
| Medium
| Medium
| Medium
| Low
|-
| Transient over voltages
| High
| Low
| High
| High
| Low
|-
| Touch and step voltages
| Very low
| Low
| Low
| Low
| High
|}
 
'''''Fig. B8:''''' ''Effects of the phase to earth fault current''
 
 
'''''Fig. B9:''''' ''Circulation of the phase to earth fault current''
 
{{Highlightbox|
The fault current I<sub>K1</sub> is the sum of two components:
 
* The neutral current through the impedance Z<sub>n</sub>
* The capacitive current through the phase to earth capacitors.
 
When Z<sub>n</sub> is a reactance these two currents are opposite, which means that the reactance compensate the capacitive current. If the compensation is perfect, the fault current value is zero.
}}


*Control earth fault current values, regardless of the amount of cabling within the network, and
*Eliminate most temporary and semi-permanent single-phase faults naturally by facilitating self rectification, thereby avoiding many short-term losses


[[ru:Некоторые эксплуатационные аспекты распределительных сетей ВН]]
[[ru:Некоторые эксплуатационные аспекты распределительных сетей ВН]]
[[zh:中压配电网的一些运行情况]]
[[zh:中压配电网的一些运行情况]]

Revision as of 06:38, 9 December 2014


Overhead networks

Weather conditions such as wind may bring overhead wires into contact and cause phase to phase short-circuits.

Over voltages due to lightning strokes may generate flash-over across ceramic or glass insulators and cause phase to earth faults

Temporary contacts of vegetation such as trees with live overhead conductors may also generate phase to earth faults.

Most of these faults are temporary. They disappear naturally with the interruption of the voltage. This means that the supply can be restored after a short delay following the tripping. This delay is usually named "dead time".

Hence the sequence of fault clearing and voltage restoration in an overhead network is as follow:

  • Fault detection by phase to phase or phase to earth protection
  • Circuit breaker opening, the faulty over-head line is de-energized
  • Dead time
  • Circuit breaker reclosing. Following the reclosing two situations are possible:

- The fault has been cleared by the interruption of the voltage, the reclosing is successful

- The line is still faulty, a new tripping is initiated followed again by a reclosing sequence.

  • Several sequences of tripping-reclosing may be activated depending on the rules of operation of the network adopted by the utility
  • If after the execution of the preselected number of reclosing sequences the fault is still present, the circuit breaker is automatically locked and consequently the faulty part of the network remains out of service until the fault is localized and eliminated.

As such, it is possible to improve significantly the service continuity of overhead networks by using automatic reclosing facilities. Generally a reclosing circuit breaker is associated to each overhead line.

Underground networks

Cable Faults on underground MV cables may have several causes such as:

  • Poor quality of cable laying, absence of mechanical protection
  • Bad quality of cable terminations confection
  • Damages caused by excavators or tools such as pneumatic drills
  • Over voltages generated by lightning strokes occurring on overhead line connected to underground cables. The over voltages can be amplified at the levels of the junctions between overhead lines and underground cables causing the destruction of the cable terminations. Lightning arresters, are often installed at these locations to limit the risks of damages.

The experience shows that the rate of fault occurring on underground cables is lower than the one registered for overhead lines. But faults on underground cables are invariably permanent and take longer time to locate and repair.

A loop architecture (see Fig. B10) correctly instrumented with fault detectors and motorized load break switches allow within a short period of time to identify a faulty cable, to disconnect it and to restore the supply to the whole substations included in the loop.

These procedures of faults detection, cables disconnection and supply restoration can be automatically performed in less one minute by dedicated functions commonly integrated in remote control and monitoring systems of MV networks.

Remote control and monitoring for MV network

The use of centralised remote control and monitoring based on SCADA (Supervisory Control And Data Acquisition) systems and recent developments in digital communication technology is increasingly common in countries where the complexity associated with highly interconnected networks justifies the investment required.

Remote control and monitoring of MV feeders makes it possible to reduce loss of supply resulting from cable faults by supporting fast and effective loop reconfiguration.

This facility relies on motorized switches associated with fault detectors on a number of substations in the loop and controlled by remote control units. All stations containing this equipment can have their supply restored remotely, whereas other stations will require additional manual operations.


Fig. B7: Supervisory Control And Data Acquisition System SCADA

Values of earth fault currents in MV networks

(see Fig. B8 and Fig. B9)

The values of earth fault currents in MV distribution networks depend on the MV neutral earthing system. These values must be limited to reduce their effects, mainly:

  • Damages to equipment
  • Temporary over voltages
  • Transient over voltages
  • Touch and step voltages.

The neutral of an MV network can be earthed by five different methods, according to type (resistive, inductive) and the value (zero to infinity) of the impedance Zn connected between the neutral and the earth:

  • Zn = ∞ isolated neutral, no intentional neutral earthing connection
  • Zn is related to a resistance with a fairly high value,
  • Zn is related to a reactance, with a generally low value,
  • Zn is related to a compensation reactance, designed to compensate the capacitance of the network
  • Zn = 0: the neutral is solidly earthed.
Methods of Neutral Earthing
Isolated Resistance Reactance Compensated Solid
Damages Very low Low Low Very low Very high
Temporary over voltages High Medium Medium Medium Low
Transient over voltages High Low High High Low
Touch and step voltages Very low Low Low Low High

Fig. B8: Effects of the phase to earth fault current


Fig. B9: Circulation of the phase to earth fault current

The fault current IK1 is the sum of two components:

  • The neutral current through the impedance Zn
  • The capacitive current through the phase to earth capacitors.

When Zn is a reactance these two currents are opposite, which means that the reactance compensate the capacitive current. If the compensation is perfect, the fault current value is zero.


ru:Некоторые эксплуатационные аспекты распределительных сетей ВН zh:中压配电网的一些运行情况

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