I'm going to assume that the stator is the central part of the design and you will have magnets on the ID of the 8" pipe, which sounds reasonable. However, the stator undergoes torque when the generator generates power. How would the stator be fixed to the mounting shaft and be movable at the same time? Maybe a spline...
My thoughts (and realize this is a newbie speaking) are to use 2†square tubing as used in trailer axles for the mounting shaft. The square tubing will not allow the stator to rotate on the shaft as long as the thru hole in the stator is also square. It should however give the stator enough bearing surface area to allow it to slide fore and aft even with a close tolerance fit. The square bearing surface of the stator will most likely be made of plywood for ease of construction with epoxy holding the laminates to the bearing surface.
You may be "out there" on the cutting edge when it comes to de-cogging your generator. The models for the typical motor-conversion may work, but maybe not...
The mounting surface for the coils will be a smooth cylinder with the coils mounted in the air gap. From my research this will allow zero cogging.
Have you selected a number of poles/windings yet?
For the inner diameter available, and using 1†wide magnets, 14 poles seems to be the best fit. Wound with overlapping coils will allow 3 phase, 7 coils per phase, 21 coils total.
There is never "too much flux". I hope you bench test the generator before trying to make the rotor blades. But take steps beforehand to select wire that will get you in the ballpark. Later tests will give you the cut-in speed and wire connection types that you can suitably use. Or show you need to re-wind and try again.
Single coil bench testing will be required and I'm sure I'll need help when I get to this point. Star, Delta, Jerry will also need consideration and no doubt I'll be leaning on you guys for advice.
Something very fundamental: which way are you going to stack the laminations? Hopefully you aren't going to "wrap them" around the spindle axis. The photo of your scrap iron doesn't give a scale to judge how big the circles can be cut from the strips.
The material I found is 8†wide and I'll need to cut approximately 7†O.D. rings and stack them into a laminated core. At .013†thickness I need to cut over 150 rings to make a 2†thick core. I haven't settled on an exact method to manufacture the core but I'm leaning towards building the bearing surface first and then stacking the rings over the bearing surface while using thinned epoxy to glue and clamp the whole mess together.
I would have found it far easier to adopt a standard motor core and make the magnet drum to fit, but it can be done the other way, it will take time and patience to do one disc at a time without suitable tooling to punch a disc at a time but can be done even by laser cutting if necessary.
The upside is I'm fortunate to work at a machine shop so laser cutting and other machine tools are available to me. The downside is I'm not a machinist. But I'm also trying to apply a simple approach that would be successful for anyone with a drill press and hand tools. To cut the sheet metal rings for the laminations I'll start my cutting the 8†wide strips into approximate 8†x 8†squares. A pilot hole will then be drilled in the approximate center of each square, doesn't have to be exact and probably stacking a few together at a time. A jig will then be made by inserting a pin slightly smaller than the pilot hole into a hole drill in a piece of plywood. The pre-drilled squares are then stacked on the jig (pin) a few at a time. Clamp your plywood jig on a drill press table and use an end mill cutting tool in place of a drill bit. Adjust your jig to give you the radius needed and clamp the jig to the drill press. Now all you have to do is plunge into the stack with the end mill on your drill press and rotate the stack to cut an accurate circle. Do the same for the inner circle and you end up with ring. Hundreds if needed and all exactly the same.
I don't think you will manage to slide a core on the shaft but you can try. Moving the stator axially does give a degree of control over the characteristic, I don't really like it but that is partly as a result of never running machines off magnetic centre, it doesn't really matter but there is a slight issue that you are bringing the end connections under the influence of the magnets ( probably won't matter) I would aim for the correct winding ( test coil or similar) but you could do some fine adjustment with axial displacement. I would shift the magnet drum rather than the stator bu spacers between the drum and the hub.
I have to agree, it would be best to match the alternator to the blades right from the start by running a test coil. With my inexperience and lack of knowledge on the subject I wanted to be able to compensate if I missed my target by using something similar as the air gap adjustment on an axial machine. I need to do further reading and study how alternator/blade matching is accomplished before proceeding with coil winding.
I assume these will be smooth punchings with the coils in the air gap so you have no cogging problems.
That is correct, I'm also aiming for .25 inch coil thickness and an air gap no wider than .3125 inch.
With such a small machine you can place the magnet drum over the stator by hand if the stator is securely held and you keep fingers well clear of the danger area. Alternatively you can clamp the magnet drum and lower the stator with a hoist. You could also use long jacking screws through the drum and on to the core but for such a small machine I wouldn't bother, its a slow process and the other methods work ok.
Thanks, knowing this helps a lot. I want to have a healthy respect for the power of neo magnets and not put myself or others in danger by being uneducated on the subject.
Thanks again,
CM
