Armature Reaction in Alternator or Synchronous Generator

Every rotating electrical machine works based on Faraday’s law. Every electrical machine requires a magnetic field and a coil (Known as armature) with a relative motion between them. In case of an alternator, we supply electricity to pole to produce magnetic field and output power is taken from the armature. Due to relative motion between field and armature, the conductor of armatures cut the flux of magnetic field and hence there would be changing flux linkage with these armature conductor. According to Faraday’s law of electromagnetic induction there would be an emf induced in the armature. Thus, as soon as the load is connected with armature terminals, there is an current flowing in the armature coil. As soon as current starts flowing through the armature conductor there is one reverse effect of this current on the main field flux of the alternator (or synchronous generator). This reverse effect is referred as armature reaction in alternator or synchronous generator.
We already know that a current carrying conductor produces its own magnetic field, and this magnetic field affects the main magnetic field of the alternator.

It has two undesirable effects, either it distorts the main field or it reduces the main field flux or both. They deteriorate the performance of the machine. When the field gets distorted, it is known as cross magnetizing effect. and when the field flux gets reduced, it is known as demagnetizing effect.
The electromechanical energy conversion takes place through magnetic field as a medium. Due to relative motion between armature conductors and the main field, an emf is induced in the armature windings whose magnitude depends upon the relative speed and as well as the magnetic flux. Due to armature reaction, flux is reduced or distorted, the net emf induced is also affected and hence the performance of the machine degrades.

Armature Reaction in Alternator

In an alternator like all other synchronous machines, the effect of armature reaction depends on the power factor i.e the phase relationship between the terminal voltage and armature current.
Reactive power (lagging) is the magnetic field energy, so if the generator supplies a lagging load, this implies that it is supplying magnetic energy to the load. Since this power comes from excitation of synchronous machine, the net reactive power gets reduced in the generator. Hence, the armature reaction is demagnetizing in nature. Similarly, the armature reaction has magnetizing effect when the generator supplies a leading load (as leading load takes the leading VAR ) and in return gives lagging VAR (magnetic energy)to the generator. In case of purely resistive load, the armature reaction is cross magnetizing only.
Let’s discuss in details
The armature reaction of alternator or synchronous generator, depends upon the phase angle between, stator armature current and induced voltage across the armature winding of alternator.
The phase difference between these two quantities, i.e. Armature current and voltage may vary from – 90° to + 90°
If this angle is θ, then,
$-\;90^o\;\ge \theta \ge +\;90^o$
To understand actual effect of this angle on armature reaction of alternator, we will consider three standard cases,
1) When θ = 0
2) When θ = 90°
3) When θ = – 90°

Armature Reaction of Alternator at Unity Power Factor

At unity power factor, the angle between armature current I and induced emf E, is zero. That means, armature current and induced emf are in same phase. But we know theoretically that emf induced in the armature is due to changing main field flux, linked with the armature conductor.
As field is excited by DC, the main field flux is constant in respect to field magnets, but it would be alternating in respect of armature as there is a relative motion between field and armature in alternator. If main field flux of the alternator in respect of armature can be represented as
$\phi_f\;=\;\phi_{fm}sin\omega t\cdot\cdot\cdot\cdot\cdot\cdot\cdot\cdot(1)$
Then induced emf E across the armature is proportional to, dφ_f/dt.
$Now,\;\frac{d\phi_f}{dt}\;=\; -\;\omega\phi_{fm}cos\omega t\cdot\cdot\cdot\cdot\cdot\cdot\cdot\cdot(2)$
Hence, from this above equations (1) and (2) it is clear that, the angle between, &phi_f and induced emf E will be 90°.
Now, armature flux φ_a is proportional to armature current I. Hence, armature flux φ_a is in phase with armature current I.
Again at unity electrical power factor I and E are in same phase. So at unity pf, φ_a is phase with E. So at this condition, armature flux is in phase with induced emf E and field flux is in quadrature with E. Hence, armature flux φ_a is in quadrature with main field flux φ_f.
As this two fluxes are perpendicular to each other, the armature reaction of alternator at unity power factor is purely distorting or cross-magnetizing type.
As the armature flux pushes the main field flux perpendicularly, distribution of main field flux under a pole face does not remain uniformly distributed. The flux density under the trailing pole tips increases somewhat while under the leading pole tips it decreases.

Armature Reaction of Alternator at Lagging Zero Power Factor

At lagging zero electrical power factor, the armature current lags by 90° to induced emf in the armature.
As the emf induced in the armature coil due to main field flux. The emf leads the main field flux by 90°. From equation (1) we get, the field flux,
$\phi_f\;=\;\phi_{fm}sin\omega t$
$Therefore,\; induced\; emf\;E\;\propto \;-\;\frac{d\phi_f}{dt}\;\Rightarrow\;E\;\propto \;-\;\omega\phi_{fm}cos\omega t$
Hence, at ωt = 0, E is maximum and φ_f is zero.
At ωt = 90°, E is zero and φ_f has maximum value.
At ωt = 180°, E is maximum and φ_f zero.
At ωt = 270°, E is zero and φ_f has negative maximum value.
Here, φ_f got maximum value 90° before E. Hence φ_f leads E by 90°.
Now, armature current I is proportional to armature flux φ_a, and I lags E by 90°. Hence, φ_a lags E by 90°.
So, it can be concluded that, field flux φ_f leads E by 90°.
Therefore, armature flux and field flux act directly opposite to each other. Thus, armature reaction of alternator at lagging zero power factor is purely demagnetizing type. That means, armature flux directly weakens main field flux.

Armature Reaction of Alternator at Leading Power Factor

At leading power factor condition, armature current I leads induced emf E by an angle 90°. Again, we have shown just, field flux φ_f leads, induced emf E by 90°.
Again, armature flux φ_a is proportional to armature current I. Hence, φ_a is in phase with I. Hence, armature flux φ_a also leads E, by 90° as I leads E by 90°.
As in this case both armature flux and field flux lead induced emf E by 90°, it can be said, field flux and armature flux are in same direction. Hence, the resultant flux is simply arithmetic sum of field flux and armature flux. Hence, at last it can be said that, armature reaction of alternator due to a purely leading electrical power factor is totally magnetizing type.

Armature Winding ,Pole Pitch, Coil Span, Commutator Pitch

Now we are going to discuss about armature winding in details. Before going through this section, we should understand some basic terms related to armature winding of dc generator . Pole Pitch Definition of Pole Pitch The pole pitch is defined as peripheral distance between center of two adjacent poles in dc machine. This distance is measured in term of armature slots or armature conductor come between two adjacent pole centers. This is naturally equal to the total number of armature slots divided by number of poles in the machine. If there are 96 slots on the armature periphery and 4 numbers of poles in the machine, the numbers of armature slots come between two adjacent poles centers would be 96/4 = 24. Hence, the pole pitch of that dc machine would be 24. As it is seen that, pole pitch is equal to total numbers of armature slots divided by total numbers of poles, this can alternatively referred as armature slots per pole . Coil Span or Coil Pitch Coil of

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