> As far as I know, a longer core length with the same winding details leads to a reduced air gap flux density and consequently lower torque and HP.
No, that would not be my conclusion. My conclusion is that it's unknown, but probably a wash. I'm going back to my comments 4 Mar 23 21:10
V / N ~ B * A = B L W (where L is coil length and W is width as in span. )
IF we assume magnetic linearity
[ul]
[li]The product B L is constant. That means flux density B will decrease by the same fraction that the L increased (10%).[/li]
[li]T = R N I L B cos(theta) where theta is angle between the flux and current which is roughly constant.[/li]
[li]Since the product of (B L) is constant, then I think you can reach a given torque with the same current as before.[/li]
[li]The stator and rotor resistance will increase. The component of resistances associated with the slot will increase by 10%. The component associated with the endwindings / endrings increases by 0%. The total resistance increases somewhere between 0 and 10%, let's say 5%[/li]
[li]So for a given torque load:[/li]
[li]The current remains the same[/li]
[li]I^2*R losses increase due to increasing R[/li]
[li]core losses decrease due to decreasing B.[/li]
[li]In terms of efficiency at a given load, i'm not sure off the top of my head which factor we'd expect to dominate: 2 or 3. It may be the the 3rd factor (which is relatively load independent) dominates at low loads and the 2nd factor (which increases with load) dominates at high loads.[/li]
[li]in terms of rpm, the increasing R2 will cause increasing slip for a given load. Slightly lower speed at the same torque means slightly lower power, but it's a very small effect ... if slip increases by 5% the decrease in speed is much lower. Let's say sync speed 1000rpm, original slip 40rpm, new slip 42rpm, original speed 960rpm, new speed 958rpm, speed decrease 2/960 = 0.2%. That was assuming a large slip to begin with (4%)... if you had a smaller slip than the speed decrease is even less. Even f we stick with 4% initial slip than this whole speed thing gives you a derating of 0.2% horsepower... irrelevant in the bigger scheme of things imo.[/li]
[/ul]
If we don't assume magnetic linearity, the product of L B is going to increase (rather than remaining constant) as we increase L... and that favors the lengthened core to perform even better.
There is a minor effect on flux density not considered before that X1 is going to increase which might decrease the flux density at full load slightly (that effect is not considered in the initial equation V / N ~ B * A = B L W). It's a relatively small effect. As a first swag L is typically 0.1pu but it doesn't cause a 0.1pu drop in magnetizing branch voltage because the full load current is closer to resistive than inductive.
All in all I think I'd feel comfortable to keep the rating and FLA and efficiency estimate the same for most purposes but no matter how you slice it, it's a rough estimate in comparing competing effects. If you give more details about the motor it may be possible to improve estimates somewhat. For example from full nameplate (and preferably performance data) the equivalent circuit parameters could be estimated. Then for L1 we could say it increases by some fraction between 0 and 10% (I'd have to think a little more about that fraction) and then try to estimate what the effect on full-load B would be. No doubt any number we come up with will be a rough estimate though... it's a separate question how much confidence you want in your answers and the uncertainty around them. If it's a super critical application with no room for error and you don't have time or resources for detailed analysis, then it could certainly be a
conservative approach to assume a 10% derating (undoubtedly overconservative for most purposes, but conservative nonetheless).
