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Overunity Machines Forum



Akula0083 30 Watt Self Running Generator.

Started by Grumage, March 06, 2014, 12:29:06 PM

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0 Members and 12 Guests are viewing this topic.


Dave45

You guy's still dont get it

The key to free energy is ionization

The coils (chokes) have to separated with enough distance that the charges cannot rejoin before they are collected.

Look at static eliminators

A choke pulsed with a neg pulse will have a pos bemf

A choke pulsed with a pos pulse will have a neg bemf

Dave45


verpies

Quote from: Dave45 on April 01, 2014, 07:14:30 AM
A choke pulsed with a neg pulse will have a pos bemf
A choke pulsed with a pos pulse will have a neg bemf
What is the wavelength of the driving pulse compared to the length of the choke in your scenario?

MileHigh

Farmhand:

Just to explore the loading issue and resonance some more.

The child on the swing example:  You push harder and the size of the swing increases.  Then it stabilizes at the larger overall swing amplitude.  So you have to put more energy into the push and you get a larger swing that burns off 100% of your push energy.  You can look at it another way - the resonator is adapting itself to your push to extract exactly how much energy you are willing to put into it.

If the resistance is low (air resistance in this case) then you get a higher swing for the same energy per push.  If the air is thicker the swing goes down.  Push harder and the swing goes back up.

So in essence the swing adapts itself to "match your push."  So what does that mean for the power consumption in an electrical LC resonator?  Or to put it more accurately, an LCR resonator.

Here is the question:  Can you think of the design for a circuit that will simulate the swing and the pushing?  See that can be fun.  You have a physical setup and to test it's behaviour you design a circuit and then run the simulations and play with the variables.  The goal for the test would be to make the power consumption measurement for different resistance values associated with the LCR resonator.  You could drop a power measurement probe onto the schematic, and then see what happens to the average power consumption when you change the "R" part of the resonator.

MileHigh