Power factor correction (capacitor in parallel with inductive load)

AI Thread Summary
Installing capacitors in parallel with inductive loads is essential for effective power factor correction, as real and reactive currents are parallel rather than series. A parallel capacitor operates at supply voltage, compensating for fixed inductive currents without needing to change its value with load variations. In contrast, a series capacitor would require a larger size and would introduce variable voltage drops, negatively impacting load performance. The voltage across the load is influenced by transmission line characteristics, which can cause additional drops. Overall, parallel capacitors ensure that the real load receives the full supply voltage, stabilizing performance.
FionaZJ
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Why we must install capacitor in parallel to inductive load? Why not install it in series?
 
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The real and reactive currents of a partially inductive load are not in series, they are in parallel. The real component of current is load dependent. The inductive component, or magnetising current is usually independent of load.
A parallel capacitor will operate at the supply voltage and needs to compensate most of the fixed inductive current. It can be quite a small capacitor.

If a series capacitor was used it would be necessary for the real current also to flow through the correction capacitor. It would need to be a big capacitor and the value would have to be changed with load.
 
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Is it capacitor will draw all the voltage source in parallel?
 
FionaZJ said:
Is it capacitor will draw all the voltage source in parallel?
Voltages across the inductive load and the capacitor will be equal since they are in parallel. But the capacitor voltage may not be equal to the source voltage as there can be some resistance in between the source and the inductor.
 
Oh.okay. All of you Thank you!
 
I guess if you add capacitor in series to load, then you're introducing an additional 'current-dependent voltage drop' element across line.

V load = V source - V capacitor.

So if load changes, then load current changes, so the voltage drop across capacitor will also change as it depends in Load current times the Xc, so the voltage available for load will also change. Not sure we want that.
At low voltage motor torque will reduce, and bulbs will go dim.
 
So if we install capacitor in parallel, there will be full voltage supplied available?
 
Not really. The transmission line will have inherent inductance, resistance, and capacitance which depend on:
length of line
proximity to other conductors
whether ac or dc voltage

So voltage across load is source voltage minus the transmission line voltage drop.

Not sure if I am right with the below part:
Capacitors are put in series in lines to improve over all voltage regulation. This is done at source end. The series capacitor will nullify the line inductance to some extent so the line impedance reduces.

While at the generating end we have capacitors in parallel or tap changing transformers to keep voltage constant.

Likewise even inductors are installed in series and parallel. A series reactor is useful to limit short circuit current and starting current.
A shunt reactor is useful during light loads. At light loads the system is highly capacitive due to the C banks. This causes high voltage. So the shunt reactor absorbs this VAR.
 
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Too hard to understand[emoji28]
 
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FionaZJ said:
So if we install capacitor in parallel, there will be full voltage supplied available?
Yes. The inductive magnetising current will be stable when running. The power factor correction capacitor will have the full supply voltage across it so it will cancel most of the inductive component. The real load will have the full supply voltage across it.

jaus tail said:
Not really. The transmission line will have inherent inductance, resistance, and capacitance which depend on:
length of line
proximity to other conductors
whether ac or dc voltage

So voltage across load is source voltage minus the transmission line voltage drop.
I think jaus tail is writing about neutralisation of regional transmission lines while I am writing about neutralisation of local electric motors.
 
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