- #246
jim hardy
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Okay, back now , tended to some pressing matters.
Same number of turn and same voltage? That says flux stayed the same, same flux over more area is smaller B.
B would drop.
well, inductance varies as square of N
and varies in direct (not square) proportion to urelative ,
and for your fixed voltage B is in inverse proportion to N
so would we need to find how urelative varies as f(B) , then see how much it changes for the proposed change in N , and for A? Partial derivative wrt B ?
Thats why i suggested looking at data...
or this one from 230 ?
You seem to be driving toward maximizing inductance.
Remember the very basic definition,
inductance is flux linkages per ampere ,,, NΦ/I
Is not volt-seconds basically NΦ ? ∫Vdt = N∫Φ ?
[/QUOTE]
Say I wanted to design an inductor to be as big as possible[/QUOTE] you mean most Henries achievable? [/QUOTE] at a certain voltage and frequency, [/QUOTE] okay constant voltage and frequency
To get more inductance I'd need more turns, but if I do that the flux will drop, so to maintain μMAX I'd need to drop the area, but I don't want to do that, infact I want to increase the area.
This is my point, is there some fundamental limit on how big an inductor can be for a given V.s at μMAX? [/QUOTE]
By defining uMAX you've defined flux density B and urelative
By defining V.s you've defined NΦ, the volt-seconds to reach flux Φwhere μ = umax,
so if you add turns you'll have to add area to keep B same but that'd increase volt-seconds
L=N^2 U0μrelativeArea/Length
what's left to adjust ? Length ?
Looks to me like once you define volt seconds and flux density for a given core length you've defined the inductor.
That's how you design one, pick an operating flux for the core then size it for volts per turn.
Heaps and heaps of turns will get you operating in a really low flux region.
There won't be much core loss of course.
L = N * Φ/I where Φ and I are both small numbers.
BH curve has some slope at zero, but as you observed there's a liftoff".
okay , i follow that.tim9000 said:I assume when I was putting on to the 400 turn coil and load the 50V rms at 50Hz, that I was at μmax because that's when we got maximum impedacnce (theirfore max inductance).
What did you change? Just area of core?But say I was to slide onto the core more sheets of lamina: increasing A, Than would Bnotdrop because of Brms = Vrms/(N*A*2*pi*f)
Same number of turn and same voltage? That says flux stayed the same, same flux over more area is smaller B.
B would drop.
,, yes, so would BOr if I wound more turns, increasing N, than V.s/N would drop wouldn't it?
Is this just for the increased turns?So L = N2 μrelative μ0 Area / Length of path might
increase OVERALL, but haven't we moved from μMAX down to the left, to a lower point on the BH curve, closer to H = 0?
so L is up but μ and B are down, the A(?) and N terms of the equation outweigh the drop in μ?
well, inductance varies as square of N
and varies in direct (not square) proportion to urelative ,
and for your fixed voltage B is in inverse proportion to N
so would we need to find how urelative varies as f(B) , then see how much it changes for the proposed change in N , and for A? Partial derivative wrt B ?
Thats why i suggested looking at data...
?? This BH curve from post 233 ?tim9000 said:Conceptually and practically they should be the same should they not, that's the point of design?
Well let's look at some data:
Those curves are wL = 2*pi*f*50/0.6 *400^2 * (B/H)
so everything is constant except permeability (B/H). I got max impedance to be 1260 Ohm at 50Vrms at 50Hz, (and you saw the BH curve in post #233) mplying that we get maximum impedance when B = 0.72988689 T
I imagine that if current is controlled to be the same that THEN you could just wrap heaps of turns around the core and get heaps of flux. But if it's V.s that is to be the same, then it doesn't seem like I can do that.[/QUOTE]implying that we get maximum impedance when B = 0.72988689 T
You seem to be driving toward maximizing inductance.
Remember the very basic definition,
inductance is flux linkages per ampere ,,, NΦ/I
Is not volt-seconds basically NΦ ? ∫Vdt = N∫Φ ?
[/QUOTE]
Say I wanted to design an inductor to be as big as possible[/QUOTE] you mean most Henries achievable? [/QUOTE] at a certain voltage and frequency, [/QUOTE] okay constant voltage and frequency
okay you've chosen to operate this core a little below the knee [ QUOTE]we were able to do that before by using the cross sectional area of A = 0.000555 m^2 but say I want even more inductance.to get to the biggest it's like I want to design to stay on μMAX to make the most out of my steel,
To get more inductance I'd need more turns, but if I do that the flux will drop, so to maintain μMAX I'd need to drop the area, but I don't want to do that, infact I want to increase the area.
This is my point, is there some fundamental limit on how big an inductor can be for a given V.s at μMAX? [/QUOTE]
By defining uMAX you've defined flux density B and urelative
By defining V.s you've defined NΦ, the volt-seconds to reach flux Φwhere μ = umax,
so if you add turns you'll have to add area to keep B same but that'd increase volt-seconds
L=N^2 U0μrelativeArea/Length
what's left to adjust ? Length ?
Looks to me like once you define volt seconds and flux density for a given core length you've defined the inductor.
That's how you design one, pick an operating flux for the core then size it for volts per turn.
probably so. I was thinking of slopes , small excursions of current and voltage.{I think I recall you saying that the inductance curve always matched the permeability curve, however that only seems to be true for a constant current, not a constant V.s}
I can't find that post, butIs it like that inductor we were talking about for 1260Ohm that is as efficient as you can get for 50Vrms@50Hz, any bigger than that you're doing so with a smaller flux density? So like μ gets down after an increase of heaps and heaps of turns to stay at μinitial (where μ is at H = 0) and you can only increase the inductance with μ = μinitial?
Heaps and heaps of turns will get you operating in a really low flux region.
There won't be much core loss of course.
L = N * Φ/I where Φ and I are both small numbers.
BH curve has some slope at zero, but as you observed there's a liftoff".