Protection of LV/LV transformers: Difference between revisions

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These transformers are generally in the range of several hundreds of VA to some hundreds of kVA and are frequently used for:  
LV/LV transformers are generally in the range of several hundreds of VA to some hundreds of kVA and are frequently used for:  
 
* Changing the low voltage level for:
* Changing the low voltage level for:
** Auxiliary supplies to control and indication circuits
** Auxiliary supplies to control and indication circuits
** Lighting circuits (230 V created when the primary system is 400 V 3-phase 3-wires)  
** Lighting circuits (230 V created when the primary system is 400 V 3-phase 3-wires)
* Changing the earthing system for certain application such as safety services, medical IT, or certain loads having a relatively high capacitive current to earth (computer equipment) or resistive leakage current (electric ovens, industrial-heating processes, mass-cooking installations, etc.)
 
LV/LV transformer shall be protected against short-circuit and overloads.
 
{{Highlightbox|text=
When energized, a LV/LV transformer draws [[#Transformer-energizing inrush current|a very high inrush current]]. This very high inrush current (and its time/current characteristics) should be taken into account when [[#Protection for the supply circuit of a LV/LV transformer|selecting the overcurrent protection]], to avoid nuisance tripping.}}
 
'''Notes''':
*LV/LV transformers may be supplied with embedded protective systems, such as over-temperature sensors. Refer to transformer manufacturer documentation.
*In the particular cases of LV/LV safety isolating transformers at extra-low voltage, an earthed metal screen between the primary and secondary windings is frequently required, according to circumstances, as recommended in European Standard EN 60742.
 
==Transformer-energizing inrush current==
 
When energized, LV/LV transformers draw very high inrush currents which must be taken into account when choosing overcurrent protection devices. (see {{FigRef|N33}})
 
The peak value of the first current wave often reaches 10 to 15 times the rated rms current of the transformer, and may even reach values of 20 to 25 times the rated current for transformers < 50 kVA. This transient current decreases rapidly, with a time constant 𝜏 of the order of several ms to severals tens of ms.
 
This can be compared to the maximum short-circuit current, which is the nominal current divided by the short circuit impedance voltage of the transformer in %. For example, when the short circuit impedance voltage is 5%, the short circuit current is In / 5% = 20 In, e.g. the same order of magnitude as the transformer energizing inrush current. The main difference is that the inrush current when energizing decreases very fast.
 
{{FigImage|DB422663_EN|svg|N33|Transformer-energizing inrush current}}
 
Note: the actual magnitude of the current peak can vary a lot, and depends on:
*The value of voltage at the instant of energization
*The magnitude and polarity of the residual flux existing in the core of the transformer
*The characteristics of the load connected to the transformer
 
==Protection for the supply circuit of a LV/LV transformer==
 
The [[#Protection of LV/LV transformers, using Schneider Electric circuit-breakers|selection of the protective device for the supply circuit of a LV/LV transformer]] must avoid the possibility of incorrect operation due to the inrush current when enegizing the transformer, described above. It is therefore necessary to use:
 
===Selective (i.e. slighly time-delayed) circuit-breakers, such as Compact NSX with electronic trip-unit===
(see {{FigRef|N34}})
 
{{FigImage|DB422664_EN|svg|N34|Tripping characteristic of a Compact NSX with electronic trip-unit}}
 
Where:
* I<sub>n</sub> = nominal current of the transformer,
* I<sub>r</sub> = Long Time Protection (overload) setting of the circuit breaker
* I<sub>sd</sub>, t<sub>sd</sub> = Short-Time Protection (short-circuit) setting of the circuit breaker, which should be selected according to the time/current characteristics of the transformer energizing inrush current,
* I<sub>i</sub> = Instantaneous Protection (short-circuit) setting of the circuit-breaker
 
===Circuit-breakers having a very high magnetic-trip setting, such as Compact NSX with TMD thermal-magnetic trip unit or Acti 9 curve D===
(see {{FigRef|N35}})


* Changing the method of earthing for certain loads having a relatively high capacitive current to earth (computer equipment) or resistive leakage current (electric ovens, industrial-heating processes, mass-cooking installations, etc.)
{{FigImage|DB422665_EN|svg|N35|Tripping characteristic of a Acti 9 curve D}}


=== Example ===
(see {{FigRef|N36}})


LV/LV transformers are generally supplied with protective systems incorporated, and the manufacturers must be consulted for details. Overcurrent protection must, in any case, be provided on the primary side. The exploitation of these transformers requires a knowledge of their particular function, together with a number of points described below.
A 400 V 3-phase circuit is supplying a 125 kVA 400/230 V transformer (In = 180 A) for which the first inrush current peak can reach 12 In (value provided by the transformer manufacturer), i.e. 12 x 180 = 2160 A.


This current peak value corresponds to a thermal equivalent rms value of 2160 / √2 = 1530 A.


Note: In the particular cases of LV/LV safety isolating transformers at extra-low voltage, an earthed metal screen between the primary and secondary windings is frequently required, according to circumstances, as recommended in European Standard EN 60742.
A Compact NSX250N circuit-breaker with I<sub>r</sub> setting of 200 A and I<sub>sd</sub> setting at 8 x I<sub>r</sub> (= 1600 A) would therefore be a suitable protective device.  


{{FigImage|DB422666_EN|svg|N36|Example}}


{| cellpadding="1" style="border: 1px solid #8888aa; background: #f7f8ff; padding: 5px; "
==Typical electrical characteristics of LV/LV 50 Hz transformers==
|  
 
'''Contents:'''
These values are given as an example, always refer to the manufacturer's technical data.
* [[Transformer-energizing inrush current|Transformer-energizing inrush current]]
 
* [[Protection for the supply circuit of a LV/LV transformer|Protection for the supply circuit of a LV/LV transformer]]
{{tb-start|id=Tab1366a|num=|title=|cols=4}}
* [[Typical electrical characteristics of LV/LV 50 Hz transformers|Typical electrical characteristics of LV/LV 50 Hz transformers]]
{| class="wikitable"
* [[Protection of LV/LV transformers, using Merlin Gerin circuit-breakers|Protection of LV/LV transformers, using Merlin Gerin circuit-breakers]]
|-
! colspan="24" | 3-phase (&le; 80A)
|-
| style= "width: 110px;" | kVA rating||  5 || 6.3 || 8 || 10 || 12.5 || 16 || 20 || 25 || 31.5 || 40 || 50 || 63 || 80
|-
| No-load losses (W) || 100 || 110 || 130 || 150 || 160 || 170 || 270 || 310 || 350 || 350 || 410 || 460 || 520
|-
| Load loss at rated power (W) || 250 || 320 || 390 || 500 || 600 || 840 || 800 || 1180 || 1240 || 1530 || 1650 || 2150 || 2540
|-
| Short-circuit voltage (%) || 4.5 || 4.5 || 4.5 || 5.5 || 5.5 || 5.5 || 5.5 || 5.5 || 5 || 5 || 4.5 || 5 || 5
|}
|}
{{tb-start|id=Tab1366b|num=|title=|cols=4}}
{| class="wikitable"
|-
! colspan="24" | 3-phase (&ge; 100A)
|-
| style= "width: 110px;" | kVA rating|| 100 || 125 || 160 || 200 || 250 || 315 || 400 || 500 || 630 || 800
|-
| No-load losses (W) || 570 || 680 || 680 || 790 || 950 || 1160 || 1240 || 1485 || 1855 || 2160
|-
| Load loss at rated power (W) || 3700 || 3700 || 5900 || 5900 || 6500 || 7400 || 9300 || 9400 || 11400 || 13400
|-
| Short-circuit voltage (%) || 5.5 || 4.5 || 5.5 || 5 || 5 || 4.5 || 6 || 6 || 5.5 || 5.5
|}
{{tb-start|id=Tab1367|num=|title=|cols=4}}
{| class="wikitable"
|-
! colspan="15" | 1-phase
|-
| style= "width: 110px;" | kVA rating
| 8
| 10
| 12.5
| 16
| 20
| 25
| 31.5
| 40
| 50
| 63
| 80
| 100
| 125
| 160
|-
| No-load losses (W)
| 105
| 115
| 120
| 140
| 150
| 175
| 200
| 215
| 265
| 305
| 450
| 450
| 525
| 635
|-
| Load loss at rated power (W)
| 400
| 530
| 635
| 730
| 865
| 1065
| 1200
| 1400
| 1900
| 2000
| 2450
| 3950
| 3950
| 4335
|-
| Short-circuit voltage (%)
| 5
| 5
| 5
| 4.5
| 4.5
| 4.5
| 4
| 4
| 5
| 5
| 4.5
| 5.5
| 5
| 5
|}
==Protection of LV/LV transformers, using Schneider Electric circuit-breakers==
For up-to-date tables to choose the appropriate circuit breaker for protection of LV/LV transformers, refer to the latest [https://www.se.com/ww/en/download/document/LVPED318033EN/ Complementary Technical Information - Selectivity, Cascading and Coordination Guide].

Latest revision as of 16:51, 29 October 2021


LV/LV transformers are generally in the range of several hundreds of VA to some hundreds of kVA and are frequently used for:

  • Changing the low voltage level for:
    • Auxiliary supplies to control and indication circuits
    • Lighting circuits (230 V created when the primary system is 400 V 3-phase 3-wires)
  • Changing the earthing system for certain application such as safety services, medical IT, or certain loads having a relatively high capacitive current to earth (computer equipment) or resistive leakage current (electric ovens, industrial-heating processes, mass-cooking installations, etc.)

LV/LV transformer shall be protected against short-circuit and overloads.

When energized, a LV/LV transformer draws a very high inrush current. This very high inrush current (and its time/current characteristics) should be taken into account when selecting the overcurrent protection, to avoid nuisance tripping.

Notes:

  • LV/LV transformers may be supplied with embedded protective systems, such as over-temperature sensors. Refer to transformer manufacturer documentation.
  • In the particular cases of LV/LV safety isolating transformers at extra-low voltage, an earthed metal screen between the primary and secondary windings is frequently required, according to circumstances, as recommended in European Standard EN 60742.

Transformer-energizing inrush current

When energized, LV/LV transformers draw very high inrush currents which must be taken into account when choosing overcurrent protection devices. (see Fig. N33)

The peak value of the first current wave often reaches 10 to 15 times the rated rms current of the transformer, and may even reach values of 20 to 25 times the rated current for transformers < 50 kVA. This transient current decreases rapidly, with a time constant 𝜏 of the order of several ms to severals tens of ms.

This can be compared to the maximum short-circuit current, which is the nominal current divided by the short circuit impedance voltage of the transformer in %. For example, when the short circuit impedance voltage is 5%, the short circuit current is In / 5% = 20 In, e.g. the same order of magnitude as the transformer energizing inrush current. The main difference is that the inrush current when energizing decreases very fast.

Fig. N33 – Transformer-energizing inrush current

Note: the actual magnitude of the current peak can vary a lot, and depends on:

  • The value of voltage at the instant of energization
  • The magnitude and polarity of the residual flux existing in the core of the transformer
  • The characteristics of the load connected to the transformer

Protection for the supply circuit of a LV/LV transformer

The selection of the protective device for the supply circuit of a LV/LV transformer must avoid the possibility of incorrect operation due to the inrush current when enegizing the transformer, described above. It is therefore necessary to use:

Selective (i.e. slighly time-delayed) circuit-breakers, such as Compact NSX with electronic trip-unit

(see Fig. N34)

Fig. N34 – Tripping characteristic of a Compact NSX with electronic trip-unit

Where:

  • In = nominal current of the transformer,
  • Ir = Long Time Protection (overload) setting of the circuit breaker
  • Isd, tsd = Short-Time Protection (short-circuit) setting of the circuit breaker, which should be selected according to the time/current characteristics of the transformer energizing inrush current,
  • Ii = Instantaneous Protection (short-circuit) setting of the circuit-breaker

Circuit-breakers having a very high magnetic-trip setting, such as Compact NSX with TMD thermal-magnetic trip unit or Acti 9 curve D

(see Fig. N35)

Fig. N35 – Tripping characteristic of a Acti 9 curve D

Example

(see Fig. N36)

A 400 V 3-phase circuit is supplying a 125 kVA 400/230 V transformer (In = 180 A) for which the first inrush current peak can reach 12 In (value provided by the transformer manufacturer), i.e. 12 x 180 = 2160 A.

This current peak value corresponds to a thermal equivalent rms value of 2160 / √2 = 1530 A.

A Compact NSX250N circuit-breaker with Ir setting of 200 A and Isd setting at 8 x Ir (= 1600 A) would therefore be a suitable protective device.

Fig. N36 – Example

Typical electrical characteristics of LV/LV 50 Hz transformers

These values are given as an example, always refer to the manufacturer's technical data.

3-phase (≤ 80A)
kVA rating 5 6.3 8 10 12.5 16 20 25 31.5 40 50 63 80
No-load losses (W) 100 110 130 150 160 170 270 310 350 350 410 460 520
Load loss at rated power (W) 250 320 390 500 600 840 800 1180 1240 1530 1650 2150 2540
Short-circuit voltage (%) 4.5 4.5 4.5 5.5 5.5 5.5 5.5 5.5 5 5 4.5 5 5


3-phase (≥ 100A)
kVA rating 100 125 160 200 250 315 400 500 630 800
No-load losses (W) 570 680 680 790 950 1160 1240 1485 1855 2160
Load loss at rated power (W) 3700 3700 5900 5900 6500 7400 9300 9400 11400 13400
Short-circuit voltage (%) 5.5 4.5 5.5 5 5 4.5 6 6 5.5 5.5


1-phase
kVA rating 8 10 12.5 16 20 25 31.5 40 50 63 80 100 125 160
No-load losses (W) 105 115 120 140 150 175 200 215 265 305 450 450 525 635
Load loss at rated power (W) 400 530 635 730 865 1065 1200 1400 1900 2000 2450 3950 3950 4335
Short-circuit voltage (%) 5 5 5 4.5 4.5 4.5 4 4 5 5 4.5 5.5 5 5

Protection of LV/LV transformers, using Schneider Electric circuit-breakers

For up-to-date tables to choose the appropriate circuit breaker for protection of LV/LV transformers, refer to the latest Complementary Technical Information - Selectivity, Cascading and Coordination Guide.

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