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Gadolinium cube
Toroid's are hard to come by; Here's a picture of the 1" cube I ordered:
Toroid's are hard to come by; Here's a picture of the 1" cube I ordered:
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Last edited by Allen Burgess; 05-15-2019, 02:01 AM. -
Gadolinium oscillator
This schematic shows an overhead permanent magnet that is heated above the gadolinium currie point of 68 degrees Fahrenheit: This idea would allow two Peltier Arduino modules; One to heat the permanent magnet and the other to cool the non-magnetic floor:Last edited by Allen Burgess; 05-15-2019, 02:01 AM.Comment
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Imagine placing a hot cup of water over a permanent Neo magnet disc with a gadolinium piston underneath suspended over an ice cube. The oscillation should be perpetual and frequent, as the heat from the cup of water reinforces the magneto heating from the PM, and the cooling from the base module causes the gadolinium to transition back to it's magnetic state after it drops to the cooling base.Comment
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This inventor calls the overhead permanent magnet the "Hot Reservoir" A steam iron and a laser thermometer could easily help trigger an oscillation in the gadolinium cube between the magnet and the "Cold Reservoir" underneath!Last edited by Allen Burgess; 09-06-2018, 06:15 PM.Comment
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Single Peltier.
One 12 volt Peltier Module attached to a heat sink can cool the base and heat the magnet through convection from the heat sink cooling fan. The colder the base the warmer the air circulating over the roof magnet.
This combination would work anywhere regardless of environmental temperature. The Arduino can hit the junk drawer too.Comment
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Hallbach array
A "Hallbach" array would work best as a "Hot Reservoir" roof magnet primarily because it doubles the field strength while halving the heating mass. A disc of wedges in a ring holder can focus the doubled attraction strength in a downward direction. A CPU heat sink would position over the "Hallbach Array" and circulate ducted hot exhaust from the Peltier module underneath to heat the magnets over 68 degrees Fahrenheit.Comment
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piston coil
I imagined molding a gadolinium pot and screwing the coil inside. Secondly; The pot can nest in a cold fluid receptacle at the base and recess into the hot reservoir magnet roof. Thirdly; internal contacts can send output through a square axle with spring on top.
The gadolinium pot will not interfere with the faraday effect, while non magnetic, as the pot oscillates it's internal coil wraps inside the powerful Hallbach flux field.Last edited by Allen Burgess; 09-09-2018, 11:27 AM.Comment
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The magntic teperature is 91 degrees farenheit and nonmagnetic 96.Last edited by Allen Burgess; 05-15-2019, 02:01 AM.Comment
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EM trigger
These electromagnets raise the temperature of the Gadolinium cube through the MCE: The EM's act as a transistor base for the gadolinium flux gate, at the currie point.
Last edited by Allen Burgess; 09-22-2018, 02:40 PM.Comment
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Anomaly
The gadolinium cube has no attraction to the 12 volt D.C. stator coil electro magnet when both the electro magnet attracts ferrite and the permanent magnet adheres to the gadolinium?
This is really weird folks; I've never seen anything as tricky to explain.
I tried it on a standard electro magnet and there's zero attraction. The attraction to permanent magnets remains intact.Last edited by Allen Burgess; 09-22-2018, 10:36 PM.Comment
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Gadolinium shielding effect.
https://www.youtube.com/watch?v=I8b-6v9HSYU
Furthermore; The gadolinium not only has no attraction to the electromagnet, but it blocks the attraction of the attached ceramic magnets to the EM coil from overhead.Last edited by Allen Burgess; 09-23-2018, 10:45 AM.Comment
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follow up strength comparison test.
https://www.youtube.com/watch?v=a0PifA2dYxc
motor concept;
https://www.youtube.com/watch?v=QvvPC6_Wq50Last edited by Allen Burgess; 09-23-2018, 12:08 PM.Comment
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shunt rotor.
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gadolinium magnet shields /in red\ would eliminate rotor drag at the currie point;
Last edited by Allen Burgess; 09-23-2018, 07:45 PM.Comment
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