Mark
I don't think that would work. Even with the arrangement your going to get input power coming in and going out briefly from the discharge side. Unless you use only one slot on the commutator, and that will lower the overall performance of the motor.
I think its better to just keep it separate. With the right timing mechanism in place the output can be stepped up and looped back to the front end easily. With little to no speed loss in the motor. This will dramatically lower the input.
What I have been thinking about is using is a bifiliar. 2 zig zag coils with a diode at the end. But the diode would be 180 out on both coils.
This might improve performance.
I have a blank rotor I am going to try it on sometime soon.
Matt
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Off Topic
Rave154,Originally posted by rave154 View PostIf this post isnt considered relevent to this thread then ill start a new one obviously, but i think it plays a part.
Peter, i recently re-watched your very enjoyable Electric Motor Secrets Video, however one thing seems to be in error as far as i can see.
Early on in the video you show a demonstration of 2 DC motors mechanically coupled so that the motor on the right is acting as a motor (and a generator inside )....and the motor on the left is acting only as a generator, it also has a volt meter across it.
4V is applied to the motor on the right and it draws around 3.0Amp, meanwhile the "generator" on the left via the meter is showing a generated voltage of around 3.2V.
Here is my problem, lets say the meter has an internal impedance of say 10M Ohm, this means that overall the "generator" is generating a voltage of 3.2V across a "load"(resistor) of 10 M Ohms. From this we can calculate the current flow..
I = 3.2 / 10,000,000 = 0.00000032 Amps
from this the power through the "load"
P = 3.2 * 0.00000032 = 0.000001024 Watts
youre overall assumption is that the CEMF is always around 3/4 of the applied voltage, in the above example this is true.......but now lets leave everything the same and measure using a different meter that has an internal impedance of 5 M Ohms..
we know the power through the load will be the same..so..
P = V^2 / R ...so V^2 = P * R = 0.000001024 * 5,000,000 = 5.12
so V^2 = 5.12 therefore V = 2.26 V on the meter
now the CEMF "appears" to be only just above half of the applied voltage and not 3/4.
in other words, it seems erroneous to me to simply stick a meter onto a DC motor(acting as a generator in this case) and from the measurement taken then simply say that the CEMF is 3/4 of the applied voltage.....since the voltage developed by the "generator" will be dependent on whatever "load"(the meter in this case) it has across it.
I.E a 10 M Ohm meter wil show a voltage of 3.2 V and a 5 M Ohm meter will show a voltage of 2.62 V.
If im in error in all this then id greatly appreciate someone pointing out where ive gone wrong.
Thanks
First, this is really OFF TOPIC for this thread. Second, you are missing the point, as the Back EMF is a constant function inside the motor and it is not related to how it is represented on any given meter. The "3/4ths" is not some "rule of thumb" that applies to CEMF in general, but only to the example shown, as evidenced by the meter readings. Third, this is a speculative exercise on your part. If you would really like some insight into this, you should repeat the experiment yourself and observe what happens on the bench.
The fact that the current moving through the generator both lights the light bulb (first energy manifestation) and activates the reverse motor torque (second energy manifestation) illustrates the point I am making, regardless of any meter readings.
Peter
PS Do not respond to this in this thread!!! Either start a new thread or post it in the first EMS thread.Leave a comment:
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Thanks for the heads up Peter. I wish I had a scope and knew how to use one.Originally posted by Peter Lindemann View Post
One thing I'm concerned about is that when comparing the modified to the stock motor I'm not seeing any significant advantage like I expected. Matts setup without collecting the spike and collecting the generated output appears to be better. Your reflection on this would be appreciated. I'm wondering if a 6 brush set up would be better on the 4 pole motors. I havent started working on the 2 pole motor yet so maybe things will be different with that one. Don't know a lot to learn still.
MarkLeave a comment:
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Matt
With your stock brush set up you must be using the commutators and brushes that are 180 degrees apart if you have an internal diode. If you used brushes and commutators that are 90 degrees apart you could remove the internal diode. Then your 2 output brushes would be 180 degrees out of phase. I wonder if that setup would be any better.
Pault
Looking forward to here some results on your set up.
MarkLeave a comment:
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Meter Sampling Rate
Mark,Originally posted by Mark View Post
Bedini and I saw things like this all of the time. Our best explanation of it is that you are seeing an artifact of the digital meter's sampling rate, which intersects (and samples) the "chatter" sometimes, and other times does not. In any event, these types of signals are very hard on digital meters, when looked at directly. We eventually moved to looking at this stuff with a current probe connected to a fast digital scope. Even then, odd waves would move through the data stream that John believed were related to "gravity waves" because of their long period. I never did postulate an alternative explanation of the phenomena.
We got to the point where we just used analog meters in these cases, as they gave us the "average" readings that were reasonably accurate when checked against the area under the curve on a digital scope.
PeterLast edited by Peter Lindemann; 01-23-2011, 05:34 PM.Leave a comment:
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pics
Pulling the original windings off:
http://img401.imageshack.us/img401/5069/img0097wx.jpg
30 turns of 18awg, just before first run at 12VDC:
http://img831.imageshack.us/img831/9620/img0098yc.jpg
ptLeave a comment:
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There are a few others here that are using or intend to use this motor.Originally posted by Mark View Post
Yes, very good point.... just pull the spring back and onto the side and the rotor goes on sooo easy. The other motor is such a pain compared to this one. It would be nice to find a way to keep the brushes the way they are.
ptLeave a comment:
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I would stick with 2 commutator section on the 16 pole motor.
It runs on 3 sections but the voltage steps up to high and must be arching inside. It immediately runs the cap up to near 100 volt. BUT, the motor draws 4 amp at 72 volt. NOT GOOD.
It becomes a basic step up voltage transformer. And I would expect it does not spark much it really isn't any stronger that it was before. So that is an indicator that most of the power that is coming in is going out to the discharge side.
MattLeave a comment:
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Yes that is the motor, I bought 2 of them. 18 awg, ok I thought it was a little small but I was just eye balling it. I have quite a bit of 18 and 20 awg so I can go either way.Originally posted by pault View Post
I pulled one of the motors apart and put it back together and I just love the brush assemblies, just pull the spring back and onto the side and the rotor goes on sooo easy. The other motor is such a pain compared to this one. It would be nice to find a way to keep the brushes the way they are.
So at 72 volts the other motor draws only .5amps. Huh, what the hell is going on there.
Something else funny is going on with my 24 volt motor. When I'm collecting the back spike into a cap or battery and have a meter hooked up to it the reading jumps around. It will be steadily climbing lets say from 30 volts and then all of a sudden will read like 3-12 volts for a split second then go back to where it was and continue to climb. Like its getting some AC voltage or something. I've tried some ulta fast diodes, 1n5408, and a FWBR externally and also have a 1n5408 on the winding internally and it still does it. It happens every 5 to 10 seconds or so. It just hiccups for a second and then continues on where it left off on the voltage climb. Even with a battery hooked up, the voltage will suddenly read 3.27 volts or something and then go back to battery voltage. Do you have any idea what going on there, or is my meter ready to take a crap again. I've only ruined 5 or so already in that last 2 years, lol.
MarkLeave a comment:
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That one kinda got screwed up. I built it 90 deg out. and when I turn it everything gets too tight on one side.
I am expanding the commutator now.
I tried 72 volt last night and it runs 1/2 amp. and charges a cap almost immediately to 50 volt.
But you like said 60 volt takes 1 amp. I am not sure whats up with that.
If you put the out put directly to a battery thats a big load, and that why its bogging down. If you could switch the power off of the caps real quik while the discharge coil is unhooked on the commutator. You could get the power out with out even slowing the motor down.
MattLeave a comment:
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Mark, is it this one?:Originally posted by Mark View Post
12 VDC MOTOR | AllElectronics.com
That's the one I'm working on. I took a sample of the wire to an electronics supply place and the guy measured it with electronic calipers and said "probably 18awg". Felt that way when I compared with 16/18/20. The caliper reading could have been off, due to left-over varnish.
I got the rewound motor running with 30 turns, 18 awg.
Yeah, the 2nd set of brushes will be a puzzle. First, I'm going to check the direction of rotation and figure out which side of the existing brushes the new brushes need to go. [Oh, I can choose the direction of rotation by choosing which lead is +ve and -ve.]
One thought is to remove the outrigger springs and replace them with internal compression springs (plugging the end of the brush casing) to free up space to the right of the brushes.
I'd love to hear any other ideas.
ptLeave a comment:
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Hey Matt,
I was going back thru some of the posts and seen the one where you posted pictures with your commutators moved. Why haven't you tried to bolt that one on the motor or is the cover different?Leave a comment:
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48 volts is the max I can run. At 60 volts the motor bogs down and the amps jump up. With 48 volts my 300uf cap would chaarge up to almost 100 volts. The amp draw of the motor @ 48 wolts was 450ma with the cap but if I hooked the back spike up to a 12 volt battery the input would jump up to 1 amp.Originally posted by Matthew Jones View Post
My other 2 motors arrived today. They are 12 volt, 2 pole motors. The rotors have 10 slots and the commutators are twice the size of the 24 volt motors and are very well constructed. Someone else had posted pictures of one a few pages back. The rotor slots are pretty wide and magnets are quite a bit larger then the 24 volt motor ones. The wire on the rotor now looks like 20awg to me. Adding 2 commutators will be the problem with this one because the boards aren't complete circles. It looks like I maybe able to cut one board and glue it to the top of the other. The commutators are pretty long and there should be enough clearance.Last edited by Mark; 01-23-2011, 04:35 AM.Leave a comment:
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First light
I wound the armature, but stopped after 30 turns of 18awg. That's about all that would fit.
It ran on a 12VDC slab for some seconds.
I could see, and smell, arc's through the entry hole for the leads (I didn't replace the grommet yet), so I quit, pending the addition of the 2nd set of brushes. Nothing seemed to be getting hot.
- To get it to start itself, I marked the shaft and positioned it so that the brushes were "on" before applying power. (It took me only one false no-start to figure this out
).
- Replacing the cowling (with the magnets glued in) was a pain. As soon as I got close, the magnets would suck the armature up and out of the brushes, and the brushes would snap shut. The best way to keep the brushes away from the shaft while re-inserting the armature seems to be by pulling the spring lever arm right out from the brush casing and pinning it to the back of the casing until the shaft is in place.
- The commutator assembly is offset from the armature such that when I positioned the coil directly in the middle of the magnets, the brushes touched two commutators each. I picked one set and went with them. This turned out to be the commutator two slots away from the coil. [This model has 10 slots].
- The 18awg was hard to work with. I unwound my work a few times before getting reasonably flat / tight windings. Had to pull hard when setting each winding in its slot. It still looks like it was hand-wound by someone who hasn't wound a motor in decades...
ptLeave a comment:
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I'll give that ago Matt. I wish I wouldn't have moved my brushes yet so I could have played some with the generator action like you have.Originally posted by Matthew Jones View Post
What kind of rpm's are you getting at 36 and 48 volts? I also noticed that with the 20awg wire I wasn't getting very big spikes and am wondering if not moving the brushes would cause much harm to them. What are your thoughts on this Matt. And how is your brush wear?Leave a comment:
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