Pulling energy from the ambient energy field using a coil capacitor

[wistiti]

Hi Sky!
Nice to ear you will try it too!
My primary is not a joule thief... ( I try it first) Now I use a radiant oscillator, from Sultech, I have build as the primary source. I connect it on the primary coil who is open... Hope to be clear... not sure...

I think the best primary power is one who can deliver hv and variable frequency... but it need more testing (that's why am happy you be here!!) Since now with my little research I found amp is not much a matter... It seems all about Voltage and frequency Like Jack have said.

In my last test I use just one leg of the primary to extract power. (as Jack suggest) I found I can have much power when grounding (maybe antenna will also work) the other leg of the fwbr.   

Let us know about your experimenting!

Sincerely!   

[pomodoro]

Here is a quick tip. Its not about Jack's circuit but about the AV plug.The AV plug must end quickly at the capacitor. That's all
No antennas, wires, leads to meters etc after the plug. It must also be a foot or more above ground.  Its best to use LEDs , filament bulbs, etc as you can't measure the v on a small cap with a 1OM meter all that well when the circuit is off.  If you have any wires at all after the AV plug you are capacitely coupling to earth , or just to the free space capacitance of the metal object, drawing big current thru the  wire to the AV plug .
Perhaps it don't matter with Jack's free energy, but if you do it with a freq gen, it will suck power out of it.

[wistiti]

Hi Promodoro.
Yes I haved realised that the "excited" legs go to the half of the bridge (AV plug) but the strange thing here is this "excited" leg are blocked by a diode BEFORE the av plug...  So normally nothing should reach the av plug.....

I did not know about the rest of the reference you give about how to optimize the av plug output.... Interesting!
Thank you!

[pomodoro]

The diode that blocks the av plug could have some capacitance, be too slow for the dV/dt or suffer some avalanche or zener breakdown. These factors and perhaps some I have not thought of need to be looked at first.  Another factor is that a coil opened at both ends excited by another can pass large currents if a small length of wire is attached to the ends or even just one end. Its easy to show this using a small Tesla coil with both ends of the secondary not grounded.  If a small filament bulb  has one terminal attached to just one end of the secondary, and a short wire is attached to the other terminal of the bulb, just into space, enough current can flow to make the filament glow, even with a totally insulated wire to stop a corona discharge. Electrons are pumped to and fro the dangling wire, which has some capacitance. Again, this doesn't mean Jacks circuit isn't doing something special, but Im trying to explain to you the behavior of high voltage spikes or high frequency signals on single ended wires. Tesla explained this when he lit his famous bulbs with one wire

[dieter]

As I mentioned a couple of times before, any diode is conductive in both ways for the very first few nanosecs or microsecs of a Pulse. As the open secondary is basicly two open secondaries, connected by a load, the actual spike is very short, as it penerates even a HF schottky diode both ways.


Shorting the open secondary (instead of a lightbulb load) will simply make it one normal secondary with no load attached, no surprise there.




Bringing the open ends close together, so a sparkgap is taking place, clearly showed in my (1000vdc on primary pulse) experiment that the secondary in fact has high voltage, maybe 1 to 2 kV. Yet, the LED was not fried, but when I recently tested the DC resistance of this blue 100mA 3V LED (5 LEDs in parallel internally), my meter showed something like 5 megaohm, I think that is not normal. However, it is still working.


No matter how low the resistance of the load is you connect to this open ends secondary, the secondary will always be like a standard secondary with absolutely no load attached, and that is the beaity of it.


I think we should therefor concentrate on a secondary with a huge amount of turns and copper, induced by a very efficient inductive coupling design.


thanks for your attention.