One of the things that seems to plague home-built wind turbines is the variability of furling and therefore stator heating. It would be nice to have a simple additional way to protect these things that we spend so much time building, so there needs to be some method of limiting output when the stator current gets above a certain point
Hi Beaufort,
I came up with a wild idea the other day when I was walleye fishing. I decided to build a new delta generator for my 13 foot 12 volt and incorporate an automatic star/delta switch in it. I decided to go with delta because I only want three wires coming down the tower instead of six for IRP. I left all six wires in it for right now because I have a manual star/delta switch at the base of the tower so I can test it before I built my automatic thing that's going to mount on the turbine.
I didn't really take many pictures of the deal because other people have done this before and it's not really all that ground-breaking. About the only picture I have is one I took when I was winding the stator and laying it out in my new steel stator mold that I built:
I wound the new stator so it fits under 10" generator rotors instead of the 14's that were on it, and I used 1/2" wedge mags in it instead of 1 x 2 x 1/2" bars. And I wound the stator with a single strand of AWG 14 wire. It's wound for proper cut-in speed in delta.
When I put the thing up it works good in star in low winds. It start putting out 1 amp at about 5 mph and it will get up to about 14 amps and that's as far as it will go - it's only turning at ~100 rpm. I throw the switch to delta, the rotor takes off into the wild blue yonder, and away she goes. I also turned the furling way up on it because I wanted to test this AWG 14 to see what it would take in delta (according to my guesstimates, single strand AWG 14 in delta is about the same as two-in-hand AWG 14 in star).
Yesterday we had 25-35 mph wind, sustained, pretty much all day. I found out the new generator will get to 20 amps in star in pretty strong wind but it just won't go above that. The rotor is going so slow you can count the blades going by. I thew the thing into delta and it was like, holy ^&%$, it started pushing 80 amps on my Fluke meter, and was still climbing. I looked up and it wasn't even attempting to furl yet. So in a panic I threw the switch back to star. I don't know exactly how big the power surge was, but I know I saw 160-something on my Fluke meter. But it was very brief and then it died down to 18-20 amps and the rotor was turning real slow again. I threw the shorting switch and it brought the turbine to a crawl, even in the strong wind.
I didn't see any smoke come out of the generator so I decided I had to try this again. If the gen goes I'll just clear the blast zone and hope for the best.
I actually ended up running that same test at least a half dozen more times, then decided to leave it in star until I get the furling turned down on it to more reasonable levels. I dropped the tower this morning and adjusted the furling on it and inspected the generator. There's no apparent damage to it from pushing 80+ with surges over 150 several times, for brief periods. Then I forgot about until I read your post because I'm busy building my automatic switching outfit.
Here's my wild idea - why can't a person build a delta generator like this that starts in star, switches to delta, then switches back to star for braking at a pre-set point? It appears to me that it worked just as good as shorting it except that the turbine continues to put out a low amount of power after it spools down. I don't know what sort of wind it would take to get it to come out of stall in star, but even if it did I suspect if the furling was set properly it would furl anyway.
This would all take some sort of electronic controller that I don't have the slightest clue how to start building. But, based on what I saw in my experiment, I think it would work.
--
Chris
