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http://prometheusfusionperfection.com/2 ... the-scene/
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University of Sydney Makes Small Polywell
University of Sydney Makes Small Polywell
Engineering is the art of making what you want from what you can get at a profit.
That's about half the size of the dimunitive WB-2, but the coil forms do space the coils.
I did not notice the insulator material, but I get the impression it is a plastic. You could not drive it very hard, but it does appear to be a nice first step. I've been hoping to see amateur fusion efforts on this scale.
I did not notice the insulator material, but I get the impression it is a plastic. You could not drive it very hard, but it does appear to be a nice first step. I've been hoping to see amateur fusion efforts on this scale.
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John Gallagher
- Posts: 20
- Joined: Sat May 10, 2008 3:35 pm
- Location: Winter Park Florida
This was also mentioned at the IEC conference and here:
http://pajamasmedia.com/instapundit/90204/
They apparently drove it to 1T and 250V drive depth.
http://pajamasmedia.com/instapundit/90204/
They apparently drove it to 1T and 250V drive depth.
I used a little Macor while at EMC2 myself. Good stuff.
We also used a lower grade green unfired clay from MMC. It was machineable in the green form, then you fired it. Manassas has a ceramics shop that teaches clay arts, and has several local artisans making their wares. For five bucks they would include our parts in their next firing.
They have classes in porcelean, and I always wanted to try my hand at making specialized e-gun parts there.
My observation was that any of these materials, placed at cusps of a Polywell, would produce fireworks when you attempted to drive a deep well. We thought, rather than insulating, they were "charging up" with electrons and then encouraging ions to strike. You can't cheat with insulators.
So, while that insulated magrid is probably good for some low-energy and beam trajectory studies, it is not suitable for actually driving an high-energy well. For that you need a metal surface, and you need to not have an insulator or conductor at any cusp, including the "funny cusp".
But it is a start, and I'm glad to see them working on it.
We also used a lower grade green unfired clay from MMC. It was machineable in the green form, then you fired it. Manassas has a ceramics shop that teaches clay arts, and has several local artisans making their wares. For five bucks they would include our parts in their next firing.
They have classes in porcelean, and I always wanted to try my hand at making specialized e-gun parts there.
My observation was that any of these materials, placed at cusps of a Polywell, would produce fireworks when you attempted to drive a deep well. We thought, rather than insulating, they were "charging up" with electrons and then encouraging ions to strike. You can't cheat with insulators.
So, while that insulated magrid is probably good for some low-energy and beam trajectory studies, it is not suitable for actually driving an high-energy well. For that you need a metal surface, and you need to not have an insulator or conductor at any cusp, including the "funny cusp".
But it is a start, and I'm glad to see them working on it.
Thanks for sharing that, I was wondering how that would work.My observation was that any of these materials, placed at cusps of a Polywell, would produce fireworks when you attempted to drive a deep well. We thought, rather than insulating, they were "charging up" with electrons and then encouraging ions to strike. You can't cheat with insulators.
Here's the ppt:
http://fti.neep.wisc.edu/static/TALKS/1 ... tthewc.ppt
If you can't open ppt:
http://fti.neep.wisc.edu/static/TALKS/1 ... tthewc.ppt
If you can't open ppt:
Size limitations and inductance argument dictate we should use a small number of turns and provide a large base load current.
To achieve 1 Tesla of magnetic field in polywell faces of 6cm diameter, we require a current of 10kA.
10 turns is a middle ground between size and inductance limitations, and the need for a more practical base current of 1kA.
10 turns reduces asymmetry effects from feed lines
Critically damped current pulse from a capacitor in near short circuit conditions.
Our capacitors are 1.5mF Aluminuim electrolytic
Voltage rating of 450Vdc
By using only ten turns per coil, we have kept our resistance and inductance low, close to critical damping conditions.
Forming potential wells with the polywell is definitely possible
Achieved floating potentials as deep as 250V
Time scales vary over 3-5ms
Explore; pressure, field strength, electron injection energy, electron injection current, and injection angle.
Have you tried Open Office? It is free. Supported by Sun.Tom Ligon wrote:I really need to get a .ppt reader for this old computer. Right now only my laptop has PowerPoint, and it is momentarily unavailable.
I really like AskMar's policy of posting .pdf files instead of .ppt.
http://www.openoffice.org/
Engineering is the art of making what you want from what you can get at a profit.
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kunkmiester
- Posts: 892
- Joined: Thu Mar 12, 2009 3:51 pm
- Contact:
How old, what operating system? For Windows 2000 or later try Microsoft PowerPoint Viewer 2007Tom Ligon wrote:I really need to get a .ppt reader for this old computer. Right now only my laptop has PowerPoint, and it is momentarily unavailable.
Otherwise, if you trust they won't scrape your email for spam, try http://www.freepdfconvert.com/
Or OpenOffice.
For anyone wanting to create PDFs for free, my recommendation the last three years is http://www.cutepdf.com/
In theory there is no difference between theory and practice, but in practice there is.
It seems like just making the polywell (the virtual anode) without using to fuse anything seems to be not too hard, at least not impossible for someone like me. I may make one when I'm in grad school.
Anyone know, without fusing anything, if you continue the operation, would the virtual anode be okay? There's nothing there to thermalize or anything.
Anyone know, without fusing anything, if you continue the operation, would the virtual anode be okay? There's nothing there to thermalize or anything.
Throwing my life away for this whole Fusion mess.
The description of the device above suggests pulsed magnets, very high current for microseconds. They evidently don't aim for a sustained well.
WB2 would run for seconds to a minute depending on the magnet current. I believe the peak field strength was maybe a couple of kilogauss on-axis. Pulsed it could have hit higher.
Nobody, to my knowledge, has ever built a WB2-sized unit with the WB6 form factor (spaced coils with circular cross-section). This is a challenging construction project, but I would think it would be in the range of possibility for a graduate research project or even a determined amateur. It is probably too small to have any hope of DD fusion. WB2 was unable to stand 5 kV (we fried it a little over 4 kV), but could handle 1 kV and a well-built model might handle more.
WB2 would run for seconds to a minute depending on the magnet current. I believe the peak field strength was maybe a couple of kilogauss on-axis. Pulsed it could have hit higher.
Nobody, to my knowledge, has ever built a WB2-sized unit with the WB6 form factor (spaced coils with circular cross-section). This is a challenging construction project, but I would think it would be in the range of possibility for a graduate research project or even a determined amateur. It is probably too small to have any hope of DD fusion. WB2 was unable to stand 5 kV (we fried it a little over 4 kV), but could handle 1 kV and a well-built model might handle more.
I did a question and answer with project leader Joe Khachan:
http://prometheusfusionperfection.com/2 ... e-khachan/
http://prometheusfusionperfection.com/2 ... e-khachan/