cnh1995 said:
Is it reduction in the generated voltage or a part of it being used to overcome synchronous reactance? If it is later, how does that reactance work??
Armature reaction and synchronous reactance are two names for the same thing, and reflect two ways of thinking about it.
The math works out nicely to treat it as an internal reactance, you'll probably see it treated that way in your books and on phasor diagrams.
Let's really simplify our thinking down to a synchronous machine with a one turn armature and a permanent magnet rotor.
We'll allow the complication that the rotor is machined to produce sine shaped flux, though.
Recall that voltage and flux have a derivative/integral relationship meaning our sine shaped flux gives a cosine shaped voltage
because e = - n*dΦ/dt
and cosine is 90 degrees out of phase with sine. That's a quarter cycle.
so--- peak voltage appears at the flux zero crossing
and zero voltage appears at the flux peak
because of that sine-cosine relation.
Do we all accept that unity pf current is in phase with terminal voltage ?
and zero pf current is 90 degrees ahead or behind it ?
............
We'll make our simple one turn machine with only one pole pair so electrical and mechanical degrees are the same, 90 deg = ¼ turn.
Okay,
please -
pardon my crude sketch i just don't do well with computers.
The circles are my one-turn armature windings. I've freeze-framed my thinking as mentioned earlier, so these would be like high speed photographs.
Left sketch:
Flux from armature zero pf(real) current is perpendicular to flux from field
so there is little interaction beyond a phase shift, and that's why there is a power angle.
At this instant, zero pf current is zero so it does nothing.
Right sketch:
A quarter turn later (or earlier) when unity pf (real?) current is zero
and reactive(zero pf) current is maximum,
look where the rotor is !
That's why zero pf current in the armature adds or subtracts directly to field flux. It peaks when rotor pole is right underneath the armature turns.
You should stick with the notation in your textbook
but i find this mental image useful to understand why there's such a thing as synchronous reactance. It's not same as leakage reactance.
It does affect terminal voltage by reducing flux in the machine(,or raising it )
but the external characteristics are same as if it were another circuit element
and that's how most authors present it.
Is that any help ?
old jim