[quote= wcorey ...
" Not quite sure how to phrase this, I could be way off base here... "
____ So long as you're sure that your-own wording actually states that which makes perfect-sense as far as you know, that'll have to be reasonable enough.
You've often said something to the effect that an alternator isn't designed to produce a particular voltage (at a given rpm) but rather just 'power' and the regulation and load is what then dictates the output voltage.
____ We should first have a CLEAR definition of EXACTLY-
what 'VOLTAGE' actually is. _ Cuz since the term 'voltage' has become so vastly misused for so very long, that even well-trained people like MotoMike have come to be unaware & ignorant of it's specifically intended pure-meaning, and rather use it loosely in a non-definite manor ! _ And that leads to confusion as to what's really what concerning matters of 'voltage' & 'tension' & 'potential' !
Since well-trained technicians understand that actual 'voltage' itself doesn't always actually exist in some particular cases where 'tension' is however still certainly present,, the term 'potential-voltage' came to be, but has since become commonly-abbreviated as 'potential' (and has earned it's-OWN meaning).
So anyhow, 'voltage' is basically the
measurement of an
established-amount of 'tension', (and 'tension' is electrical-
pressure) !
Unfortunately though, most-all others have come to think of electrical-pressure and 'voltage' as merely being one & the EXACT same-thing ! _ (Which they both kind-of are the same,
but only BASICALLY,, [thus some confusion over the word's particular-meaning].)
__ That the term 'voltage' refers to measured amounts of established-tension, should be fairly clear to everyone,, as amounts of established-tension are ALWAYS referred-to as 'volts', (such-as: 1.5v; 6v; 9v; 12v; 110v, etc.,etc.) ! _ So-thus ya never hear anybody ask:
"What's the tension of that battery?", or,
"What's the potential on that battery?" ! _ RATHER instead, they always rather ask
"What's the voltage of that battery?" ____ Now with that fairly elaborated-understanding having been pointed-out, onward with my specific-response to your quoted-wording...
" You've often said something to the effect that an alternator isn't designed to produce a particular voltage (at a given rpm) "
____ If it were at all possible to 'design' an alternator to produce any specific preset voltage-amount (at
any RPM), then we wouldn't have any required need for regulation-circuits to control it.
__ So RATHER, (more-so than how you've put it),, I've always maintained that an alternator CAN-NOT (all on it's own) produce ANY
actual 'voltage' whatsoever ! _ But rather actually, it only produces (varying amounts of) 'tension' which becomes real/TRUE 'voltage'
only AFTER a connected circuit molds/fashions the tension into some resulted fixed-amount of voltage !!
__ Whereas tension is 'additive' whether combined in series OR parallel,, 'voltage' is
ONLY additive when combined in 'series' !
That any resulted voltage from the power of the alternator is the same regardless of whether it's stator-windings are arranged in series or parallel, is proof that alternators (on their own)
do-not produce any actual voltage ! _ Because IF they did
produce voltage, then the parallel-arrangement (of the two stator-windings) would thus-then only be capable of HALF the total-voltage provided by the series-arrangement. _ And it's been proven that that's NOT the actual case !
__ So the bottom-line is: on their-own,
alternators do-NOT produce actual 'VOLTAGE' ! _ (They can only be-made to merely
provide some-amount of voltage.)
" but rather just 'power'
and the regulation and load is what then dictates the output voltage.
____ Right,, the alternator basically creates only
raw potential-power and it's directly-associated electrical-tension, which can only become whatever amount of
resulted 'voltage' that only a connected-circuit itself causes to
form the supplied power/tension in-to, (as 'dictated', as you've indicated).
__ So then,, power & tension
directly-from the alternator, YES,, but 'voltage',
NO !
" It seems what we're trying to do here is make the alt produce higher relative voltage by using more turns (more wire) on the coils , "
____ You've just misused the term 'voltage' in the common-manor that most-everyone does,, since an alternator doesn't produce any actual/true 'voltage', in the first-place.
(Your use of that term, is much akin to saying that the heat within an oven has developed a high 'Fahrenheit' [rather than a high 'temperature'].*)
(* Wherein- 'heat' = 'power' ; 'temperature = 'tension' ; 'Fahrenheit' = 'voltage' .)
__ The inclusion of extended lengths of wire will increase
TENSION and potential-power (which can possibly
yield a higher max-voltage, depending-on the circuit-parameters that it's connected-to).
" something I've inquired about in the past and just gotten a lecture on 'power' vs voltage. "
____ I can't seem to recall that instance, but I'm sure that I must've been more descriptive than that, as I wish to rather extensively clear-up people's conceptions of what's actually what within the related field.
So I would've been glad to further specify, if you had bothered to mention that my presented explanation had left you still rather unclear on any related aspect.
__ If I've still failed to straighten-out any related aspect, then please ask another question (on whatever you think still needs further clarifying).
" So what ARE we doing here? "
____ Certainly it must be apparently clear that if each power-coil only had just ONE loop-turn of wire-length, then the created tension & power would be
much REDUCED,, so by further lengthening the amount of wire fitted-within,
it's logically expected that a resulting power-increase will naturally become included.
As we are-NOT choosing a thinner wire-gauge because it happens to be more-suited to working with typical 12v.current-flows, but quite-RATHER because we can then FIT longer lengths of winding-wire around the stator. - (Which certainly would-not be a good-thing if matched-together with a
3v.load-system.)
__ Now since you must already be aware of at-least that much, I'm left to
assume that you had quite possibly had consideration concerning something-else as well, (that probably has to do with your opening quoted-wording of mine).
So does it have to do with the fact that a 12v.load only requires half the current as an equivalent 6v.load ? _ Or, exactly what are you actually trying to get-at ?
" Why do the alt windings (for 6v vs 12v output) need a different gauge wire to handle different current if the voltage 'in the alt' is the same (is it?) regardless of the regulated output? "
____ I'm not-sure where this question is actually meaning-to come-from.
An alternator doesn't really 'NEED' to have directly-varied wire-gauges in particular-accordance to the specific ratio of voltage-to-current dictated by the particular set-voltage of the associated load-system,, as ALL load-systems would just-as-soon that the alt.power-windings be as thick of a gauge as possible. _ It's just that the 12v.circuit-loads aren't as dependent on as thick of a wire-gauge (as the equivalent 6v.circuit-loads are).
__ By-now you should understand that there is NO 'voltage' involved within the alternator-itself alone.
Now if you had actually meant 'tension' (rather than 'voltage'),, then logically understand that equal lengths of gauge-#10 & gauge-#40 would both produce the same-amount of tension, but a 2v.system would sensibly require far better current-handling capability than a load-equivalent 24v.system would ! _ So likewise, a 12v.system can get-by with #23-gauge better than a 6v.system could,, as otherwise, a hefty 6v.load would make the
power-winding become THE 'bottle-neck' to the entire circuit. - (And the bottle-neck always drops the greatest amount of power !)
__ I'm thinking I've possibly still missed the-mark on exactly what you had meant to get-at,, so if-so, then please ask a refined question pertaining-to your particular inquiry.
Hopeful-Cheers,
DCT-Bob
but this statement not quite right Bob. The alternator produces power due to the strength of the magnetic field, from the magnets, and the speed of rotation. We take this power off by using a coil of wire to turn the power into an electrical form.