Possible solutions for power-system harmonics: Difference between revisions

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== Standard capacitors  ==


{| style="width: 793px; height: 14px" cellspacing="1" cellpadding="1" width="793" border="1"
The presence of harmonics in the supply voltage results in abnormally high current levels through the capacitors. An allowance is made for this by designing capacitors for an r.m.s. value of current equal to 1.3 times the nominal rated current. All series elements, such as connections, fuses, switches, etc., associated with the capacitors are similarly oversized, between 1.3 to 1.5 times the nominal ratings.
|-
| bgcolor="#0099cc" | Harmonics are taken into account mainly by oversizing capacitors and including harmonic-suppression reactors in series with them
|}


===== Passive filter  =====
Standard capacitors can be used if the percentage of non-linear loads is lower than 10% (N<sub>LL</sub> ≤ 10%).


(see '''Fig. L28''')<br>'''Countering the effects of harmonics<br>'''The presence of harmonics in the supply voltage results in abnormally high current levels through the capacitors. An allowance is made for this by designing for an r.m.s. value of current equal to 1.3 times the nominal rated current. All series elements, such as connections, fuses, switches, etc., associated with the capacitors are similarly oversized, between 1.3 to 1.5 times nominal rating.<br>Harmonic distortion of the voltage wave frequently produces a “peaky” wave form, in which the peak value of the normal sinusoidal wave is increased. This possibility, together with other overvoltage conditions likely to occur when countering the effects of resonance, as described below, are taken into account by increasing the insulation level above that of “standard” capacitors. In many instances, these two counter measures are all that is necessary to achieve satisfactory operation.
== Capacitors with increased current rating ==


----
Capacitors with improved current capability ("heavy duty") can be used in order to increase the safety margin. The technology of these capacitors allows a higher overcurrent compared to what is strictly requested by the standards.


<br>[[Image:FigL28.jpg|left]]<br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br>'''''Fig. L28:''' Operation principle of passive filter''
Another possibility is to use capacitors with increased rated current and voltage.  


----
As the same reactive power must be generated, the capacitors must have the same capacitance.


'''Countering the effects of resonance<br>'''Capacitors are linear reactive devices, and consequently do not generate harmonics. The installation of capacitors in a power system (in which the impedances are predominantly inductive) can, however, result in total or partial resonance occurring at one of the harmonic frequencies.<br>The harmonic order ho of the natural resonant frequency between the system inductance and the capacitor bank is given by <br><math>h_o=\sqrt{\frac{Ssc}{Q}}</math><br>where<br>Ssc = the level of system short-circuit kVA at the point of connection of the capacitor<br>Q = capacitor bank rating in kvar; and ho = the harmonic order of the natural frequency f<sub>o</sub> i.e.<br><math>\frac{f_o}{50}</math>&nbsp; for a 50 Hz system, or&nbsp;&nbsp;<math>\frac{f_o}{60}</math>&nbsp;&nbsp; for a 60 Hz system.<br><br>For example:&nbsp;<math>h_o=\sqrt{\frac{Ssc}{Q}}</math>&nbsp; may give a value for h<sub>o</sub>of 2.93 which shows that the natural frequency of the capacitor/system-inductance combination is close to the 3<sup>rd</sup> harmonic frequency of the system. From <math>h_o=\frac{f_o}{50}</math>&nbsp; it can be seen that f<sub>o</sub> = 50 h<sub>o</sub> = 50 x 2.93 = 146.5 Hz
With a rated voltage U<sub>N</sub> (higher than the system voltage U), the rated current I<sub>N</sub> and the rated power


The closer a natural frequency approaches one of the harmonics present on the system, the greater will be the (undesirable) effect. In the above example, strong resonant conditions with the 3rd harmonic component of a distorted wave would certainly occur.
Q<sub>N</sub> will be given by the formulas:


In such cases, steps are taken to change the natural frequency to a value which will not resonate with any of the harmonics known to be present. This is achieved by the addition of a harmonic-suppression inductor connected in series with the capacitor bank.
<math>\frac{I_N}{I}=\frac{U_N}{U}</math> and <math>\frac{Q_N}{Q}= \left ( \frac{U_N}{U} \right )^2</math>


On 50 Hz systems, these reactors are often adjusted to bring the resonant frequency of the combination, i.e. the capacitor bank + reactors to 190 Hz. The reactors are adjusted to 228 Hz for a 60 Hz system. These frequencies correspond to a value for h<sub>o</sub> of 3.8 for a 50 Hz system, i.e. approximately mid-way between the 3<sup>rd</sup> and 5<sup>th </sup>harmonics.  
Capacitors with improved current rating can be used if the percentage of non-linear loads is lower than 20% (N<sub>LL</sub> ≤ 20%).  


In this arrangement, the presence of the reactor increases the fundamental frequency (50 Hz or 60 Hz) current by a small amount (7-8%) and therefore the voltage across the capacitor in the same proportion.<br>This feature is taken into account, for example, by using capacitors which are designed for 440 V operation on 400 V systems.<br>
== Connection of Power Factor Correction capacitors with detuned reactors  ==


===== Active filter  =====
In order to attenuate the effects of harmonics (significant increase of capacitor current as well as high current and voltage distortion ), reactors should be associated to capacitors. Reactors and capacitors are configured in a series resonant circuit, tuned so that the series resonant frequency is below the lowest harmonic frequency present in the system (See {{FigureRef|L31}}).


(see '''Fig. L29''')
The use of detuned reactors thus prevents harmonic resonance problems, avoids the risk of overloading the capacitors and helps reduce voltage harmonic distortion in the network.  


Active filters are based on power electronic technology. They are generally installed in parallel with the non linear load.
{{FigImage|DB422602_EN|svg|L31|Simplified circuit diagram}}


Active filters analyse the harmonics drawn by the load and then inject the same harmonic current to the load with the appropriate phase. As a result, the harmonic currents are totally neutralised at the point considered. This means they no longer flow upstream and are no longer supplied by the source.<br>A main advantage of active conditioners is that they continue to guarantee efficient harmonic compensation even when changes are made to the installation. They are also exceptionally easy to use as they feature:
The tuning frequency can be expressed by the relative impedance of the reactor (in&nbsp;%, relative to the capacitor impedance), or by the tuning order, or directly in Hz.  


*Auto-configuration to harmonic loads whatever their order of magnitude
The most common values of relative impedance are 5.7, 7 and 14 (14% is used with high level of 3rd harmonic voltages).
*Elimination of overload risks
*Compatibility with electrical generator sets
*Connection to any point of the electrical network
*Several conditioners can be used in the same installation to increase depollution efficiency (for example when a new machine is installed)


Active filters may provide also power factor correction.  
{{tb-start|id=Tab1338|num=L32|title=Correspondance between relative impedance, tuning order and tuning frequency|cols=3}}
{| class="wikitable"
|-
! Relative impedance(%)
! Tuning order
! Tuning frequency @50Hz (Hz)
! Tuning frequency @60Hz (Hz)
|-
| 5.7
| 4.2
| 210
| 250
|-
| 7
| 3.8
| 190
| 230
|-
| 14
| 2.7
| 135
| 160
|}


----
In this arrangement, the presence of the reactor increases the fundamental frequency voltage (50 or 60Hz) across the capacitor.


<br>[[Image:FigL29.jpg|left]]<br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br>'''''Fig. L29:''' Operation principle of active filter''
This feature is taken into account by using capacitors which are designed with a rated voltage U<sub>N</sub> higher than the network service voltage U<sub>S</sub>, as shown on the following table.  


----
{{tb-start|id=Tab1339|num=L33|title=Typical values of capacitor rated voltage|cols=3}}
{| class="wikitable"
|-
! colspan="2" rowspan="3"|Capacitor Rated Voltage U<sub>N</sub> (V)
! colspan="5"|Network Service Voltage U<sub>S </sub>(V)
|-
! colspan="2"|50 Hz
! colspan="3"|60 Hz
|-
|-
! 400
! 690
! 400
! 480
! 600
|-
| rowspan="3"|Relative Impedance (%)
| 5.7
| 480
| 830
| 480
| 575
| 690
|-
| 7
| 480
| 830
| 480
| 575
| 690
|-
| 14
| 480
|
| 480
|
|
|}


===== Hybrid filter  =====
== Summary ==


(see '''Fig. L30''')<br>This type of filter combines advantages of passive and active filter. One frequency can be filtered by passive filter and all the other frequencies are filtered by active filter.
Practical rules are suggested in {{FigRef|L34}}, for selection of the suitable configuration, depending on the system parameters:


----
*S<sub>SC</sub> = 3-phase short-circuit power in kVA at the busbar level
*S<sub>n</sub> = sum of the kVA ratings of all transformers supplying (i.e. directly connected to)the busbar
*G<sub>h</sub> = sum of the kVA ratings of all harmonic-generating devices (static converters,inverters, variable speed drives, etc.) connected to the busbar.
:If the ratings of some of these devices are quoted in kW only, assume an average power factor of 0.7 to obtain the kVA ratings


<br>[[Image:FigL30.jpg|left]]<br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br><br>
{{tb-start|id=Tab1340|num=L34|title=Simplified rules|cols=4}}
 
{| class="wikitable"
'''''Fig. L30:''' Operation principle of hybrid filter''
|-
 
! colspan="4" | General rule (for any size of transformer):
----
|-
 
| <math>G_h\le \frac{S_{sc} }{120}</math>  
[[ru:Возможные решения, связанные с гармоническими составляющими напряжения]]
| <math>\frac{S_{sc} }{120} < G_h\le \frac{S_{sc} }{70}</math>
| <math>\frac{S_{sc} }{70} < G_h\le \frac{S_{sc} }{30}</math>
| <math>G_h > \frac{S_{sc} }{30}</math>
|-
| Standard capacitors
| Heavy Duty capacitors or capacitors with voltage rating increased by 10%
| Heavy Duty capacitors or capacitors with voltage rating increased by 20% + detuned reactor
| Harmonic filtering necessary See chapter [[Power harmonics management]]
|-
! colspan="4" | Simplified rule (if transformer rating ≤ 2MVA):
|-
| style="height: 45px; vertical-align: middle;" | <math>G_h \le 0.1 \times S_n</math>
| style="height: 45px; vertical-align: middle;" | <math>0.1 \times S_n < G_h \le 0.2 \times S_n</math>
| style="height: 45px; vertical-align: middle;" | <math>0.2 \times S_n < G_h \le 0.5 \times S_n</math>
| style="height: 45px; vertical-align: middle;" | <math>G_h > 0.5 \times S_n</math>
|-
| Standard capacitors
| Heavy Duty capacitors or capacitors with voltage rating increased by 10%
| Heavy Duty capacitors or capacitors with voltage rating increased by 20% + detuned reactor
| Harmonic filtering necessary<br>See chapter [[Power harmonics management]]
|}

Latest revision as of 09:48, 22 June 2022

Standard capacitors

The presence of harmonics in the supply voltage results in abnormally high current levels through the capacitors. An allowance is made for this by designing capacitors for an r.m.s. value of current equal to 1.3 times the nominal rated current. All series elements, such as connections, fuses, switches, etc., associated with the capacitors are similarly oversized, between 1.3 to 1.5 times the nominal ratings.

Standard capacitors can be used if the percentage of non-linear loads is lower than 10% (NLL ≤ 10%).

Capacitors with increased current rating

Capacitors with improved current capability ("heavy duty") can be used in order to increase the safety margin. The technology of these capacitors allows a higher overcurrent compared to what is strictly requested by the standards.

Another possibility is to use capacitors with increased rated current and voltage.

As the same reactive power must be generated, the capacitors must have the same capacitance.

With a rated voltage UN (higher than the system voltage U), the rated current IN and the rated power

QN will be given by the formulas:

[math]\displaystyle{ \frac{I_N}{I}=\frac{U_N}{U} }[/math] and [math]\displaystyle{ \frac{Q_N}{Q}= \left ( \frac{U_N}{U} \right )^2 }[/math]

Capacitors with improved current rating can be used if the percentage of non-linear loads is lower than 20% (NLL ≤ 20%).

Connection of Power Factor Correction capacitors with detuned reactors

In order to attenuate the effects of harmonics (significant increase of capacitor current as well as high current and voltage distortion ), reactors should be associated to capacitors. Reactors and capacitors are configured in a series resonant circuit, tuned so that the series resonant frequency is below the lowest harmonic frequency present in the system (See Figure L31).

The use of detuned reactors thus prevents harmonic resonance problems, avoids the risk of overloading the capacitors and helps reduce voltage harmonic distortion in the network.

Fig. L31 – Simplified circuit diagram

The tuning frequency can be expressed by the relative impedance of the reactor (in %, relative to the capacitor impedance), or by the tuning order, or directly in Hz.

The most common values of relative impedance are 5.7, 7 and 14 (14% is used with high level of 3rd harmonic voltages).

Fig. L32 – Correspondance between relative impedance, tuning order and tuning frequency
Relative impedance(%) Tuning order Tuning frequency @50Hz (Hz) Tuning frequency @60Hz (Hz)
5.7 4.2 210 250
7 3.8 190 230
14 2.7 135 160

In this arrangement, the presence of the reactor increases the fundamental frequency voltage (50 or 60Hz) across the capacitor.

This feature is taken into account by using capacitors which are designed with a rated voltage UN higher than the network service voltage US, as shown on the following table.

Fig. L33 – Typical values of capacitor rated voltage
Capacitor Rated Voltage UN (V) Network Service Voltage US (V)
50 Hz 60 Hz
400 690 400 480 600
Relative Impedance (%) 5.7 480 830 480 575 690
7 480 830 480 575 690
14 480 480

Summary

Practical rules are suggested in Fig. L34, for selection of the suitable configuration, depending on the system parameters:

  • SSC = 3-phase short-circuit power in kVA at the busbar level
  • Sn = sum of the kVA ratings of all transformers supplying (i.e. directly connected to)the busbar
  • Gh = sum of the kVA ratings of all harmonic-generating devices (static converters,inverters, variable speed drives, etc.) connected to the busbar.
If the ratings of some of these devices are quoted in kW only, assume an average power factor of 0.7 to obtain the kVA ratings
Fig. L34 – Simplified rules
General rule (for any size of transformer):
[math]\displaystyle{ G_h\le \frac{S_{sc} }{120} }[/math] [math]\displaystyle{ \frac{S_{sc} }{120} \lt G_h\le \frac{S_{sc} }{70} }[/math] [math]\displaystyle{ \frac{S_{sc} }{70} \lt G_h\le \frac{S_{sc} }{30} }[/math] [math]\displaystyle{ G_h \gt \frac{S_{sc} }{30} }[/math]
Standard capacitors Heavy Duty capacitors or capacitors with voltage rating increased by 10% Heavy Duty capacitors or capacitors with voltage rating increased by 20% + detuned reactor Harmonic filtering necessary See chapter Power harmonics management
Simplified rule (if transformer rating ≤ 2MVA):
[math]\displaystyle{ G_h \le 0.1 \times S_n }[/math] [math]\displaystyle{ 0.1 \times S_n \lt G_h \le 0.2 \times S_n }[/math] [math]\displaystyle{ 0.2 \times S_n \lt G_h \le 0.5 \times S_n }[/math] [math]\displaystyle{ G_h \gt 0.5 \times S_n }[/math]
Standard capacitors Heavy Duty capacitors or capacitors with voltage rating increased by 10% Heavy Duty capacitors or capacitors with voltage rating increased by 20% + detuned reactor Harmonic filtering necessary
See chapter Power harmonics management
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