Matchless
Matchless
Jim,
Just another stone in the bush as we say.
I noticed some wiring diagrams for bikes using the FET R/R that have Delta configured stators, cannot recall the models now off the top of my head. I was wondering if the use of these would now be more "efficient and reliable" together with the FET 50A R/R.
Honda did try a model (VFR) or so with delta wound stators a few years ago and I think the charging on that bike was not very reliable and there were many problems with R/R's at the time and all sorts of fixes.
There are also star "heavy duty" stator rewinds and aftermarket ones advertised as giving say an extra 20% and being more robust etc etc.
Some great analysis work you have done here. I am looking forward to the comparison summary table between the two units!!
Keep up the good work.
I don't know that I can say anything definitive about those specific designs, but I did review the differences between the Y and Delta configurations. Basically it appears as if you use the same wire thickness and the same number of turns, then the power output will be the same. The main difference is in the form of the delivered power re; voltage and current.
In the "Y" configuration, the current in each leg is the same as the current in that leg of the stator coil. However when you measure the voltage across two legs, you are seeing the voltage across two sets of windings and it turns out that the voltage is sqrt(3) larger (multiply by 1.732) than an individual coil voltage.
The dual is true of the delta configuration. When you measure the voltage across two leads, it is the voltage across one coil. The current though is from two coils so the current is increased by the same sqrt(3).
Here are some links that explain this.
http://www.allaboutcircuits.com/worksheets/deltawye.html
http://en.wikipedia.org/wiki/Y-%CE%94_transform
http://www.allaboutcircuits.com/vol_2/chpt_10/5.html
http://www.allaboutcircuits.com/vol_2/chpt_10/5.html
? Δ-connected three-phase voltage sources give greater reliability in the event of winding failure than Y-connected sources. However, Y-connected sources can deliver the same amount of power with less line current than Δ-connected sources.
Since the typical GS stator is a Y configuration, that produces higher output voltage. From the testing I did and what we know the output voltage is marginal at 1200 RPM and gets worse with the OEM/Honda regulators due to higher diode losses than the FET implementation.
If a Delta was used you would think that there would need to be more wraps in the coils and so smaller wire to lower the current and increase the voltage to an acceptable level be make up for the fact that you now lost sqrt(3) factor on output voltage.
In theory at least, there might be a sweet spot where you can reduce the size of the wire, increase the packing density and thereby get more wraps (reduced no air gaps) between the insulated windings for the same volume under the stator cover. If you think about it with very fine wire you can get more copper to wrap around stator.
With a whole bunch of wraps you might even exceed the sqrt(3) factor in voltage and you can go to a delta configuration and maintain the minimum output voltage level. The delta is a a safer configuration as per the comment above. The only way to really improve reliability is to get more copper per turn if comparing Y to Y or Delta to Delta.
If you can confirm that delta configurations have much thinner wire, then you would be validating my analysis. Elsewise there is something else going on.
As far as how much this is related to the R/R? I think the critical constraint in the power deliver is that you need more than 13 volts to adequately charge the battery. Increasing current capacity of a delta will not fire your coils if it is at 7.5 volts output. (13/sqrt(3)). You have to increase the winding to get back to 13V. A lossy R/R with 3 volts of diode drop is going to make it harder to achieve the 13V limit. If the delta and the FET R/R are used together that makes sense if you can't get your wire small enough to get the voltage high enough, then the FET R/R doesn't need as much voltage to produce the 13V (less internal drop) and the reliability of the delta can be implemented while still getting the minimum 13V at idle.
The constraint ,if you think about it is that the stator cover only allows a certain amount of wire to be wrapped on the stator within the space confines. There really is no leap in technology that is going to allow you to pack more copper under the cover. You might get some super conducting copper perhaps, but on a 30 year old bike???? More than likely someone could produce a rotor with stronger magnets and get more power out that way.:lol: You would have to rethink the stator configuration depending upon what can be done with the magnets.
Good luck on that, you are now trying to solve an engineering problem with motor design.
Pos
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