Harmonic distortion indicators - Power factor: Difference between revisions

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The power factor λ is the ratio of the active power P (kW) to the apparent power S (kVA). See Chapter [[Power Factor Correction|Power Factor Correction]].


== Definition  ==
<math>\lambda = \frac {P (kW)}{S (kVA)}</math>


The power factor PF is the ratio between the active power P and the apparent power S.  
The Power Factor must not be mixed-up with the Displacement Power Factor (cos φ), relative to fundamental signals only.


<math>PF=\frac{P}{S}</math>&nbsp;
As the apparent power is calculated from the r.m.s. values, the Power Factor integrates voltage and current distortion.


Among electricians, there is often confusion with:  
When the voltage is sinusoidal or virtually sinusoidal (THD<sub>u</sub> ~ 0), it may be said that the active power is only a function of the fundamental current. Then:


<math>\cos \phi=\frac{P1}{S1}</math><br>Where<br>P1 = active power of the fundamental<br>S1 = apparent power of the fundamental<br>The cos<span class="texhtml">φ</span> concerns exclusively the fundamental frequency and therefore differs from the power factor PF when there are harmonics in the installation.
<math>P \approx P_1 = U_1\ I_1\ \cos\varphi</math>


== Interpreting the power factor  ==
'''Consequently:'''


An initial indication that there are significant amounts of harmonics is a measured power factor PF that is different (lower) than the measured cos ϕ.
<math> \lambda = \frac {P}{S} = \frac {U_1\ I_1\ \cos\varphi}{U_1\ I_{rms} } </math>
 
As: <math>\frac {I_1}{I_{rms} } = \frac {1} {\sqrt {1+THD_i^2} }</math> (see [[Definition of harmonics]]),
 
hence: <math> \lambda \approx \frac {cos\varphi}{\sqrt{1+THD_i^2} }</math>
 
{{FigureRef|M6}} shows a graph of λ/cosφ as a function of THD<sub>i</sub>, for THD<sub>u</sub> ~ 0.
 
{{FigImage|DB422615|svg|M6|Variation of λ/cosφ as a function of THDi, for THDu ~ 0}}

Latest revision as of 09:48, 22 June 2022

The power factor λ is the ratio of the active power P (kW) to the apparent power S (kVA). See Chapter Power Factor Correction.

[math]\displaystyle{ \lambda = \frac {P (kW)}{S (kVA)} }[/math]

The Power Factor must not be mixed-up with the Displacement Power Factor (cos φ), relative to fundamental signals only.

As the apparent power is calculated from the r.m.s. values, the Power Factor integrates voltage and current distortion.

When the voltage is sinusoidal or virtually sinusoidal (THDu ~ 0), it may be said that the active power is only a function of the fundamental current. Then:

[math]\displaystyle{ P \approx P_1 = U_1\ I_1\ \cos\varphi }[/math]

Consequently:

[math]\displaystyle{ \lambda = \frac {P}{S} = \frac {U_1\ I_1\ \cos\varphi}{U_1\ I_{rms} } }[/math]

As: [math]\displaystyle{ \frac {I_1}{I_{rms} } = \frac {1} {\sqrt {1+THD_i^2} } }[/math] (see Definition of harmonics),

hence: [math]\displaystyle{ \lambda \approx \frac {cos\varphi}{\sqrt{1+THD_i^2} } }[/math]

Figure M6 shows a graph of λ/cosφ as a function of THDi, for THDu ~ 0.

Fig. M6 – Variation of λ/cosφ as a function of THDi, for THDu ~ 0
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