Pulling energy from the ambient energy field using a coil capacitor

[Danas]

Testing and experimenting is all that matters. Definitely something here.. I just burnt my primary. Before i destroyed coil i can tell you lamp burnt for a short time with such beautiful glow that i can only describe in religious therms,, Angelic,, LOL.. so soft so pure and white, fascinating. My voltage was to high,, bummer. I was looking for nice low voltage resonator and resurrected my old project. After some measurments we can clearly see what resonace can do. Lamp is LED 110 v ac not modified and is running half intensity on differential of only 4 milliamps.  It can be seen that unloaded resonator consumes much more power that when limp is running. Going to try to repeat results with lower voltages. I am using stack of ferrite rings and going to adopt resonator to try it. See short video attached.



https://www.youtube.com/watch?v=G6j8h1-aRBY


David.


quote author=wistiti link=topic=17119.msg506201#msg506201 date=1494264299]
Hi dieter
are you saying you have test it??
If so why you don't share your results?

Thank's

[Jack Noskills]

When coil capacitor ends that have blocking diodes are connected to a capacitor, both capacitor plates are filled with like charge. Closer the plates are together more energy it will contain (Coulomb's law). This makes me think that AC capacitor that has large capacitance but low voltage rating is the best option for a charge collector. Maybe DC capacitors could be used as well, pluses connected to coil ends and minuses connected together and to ground then load between plus and minus poles. One option, might be less effective.

Induction by oscillating magnetic field (current pulsing) fills the coil with charge and charge is packed towards coil end. Voltage is developed between coil ends. When this occurs in a coil capacitor it pulls in energy that has more density than volume. Energy flows horizontally in a solenoid coil. I have observed this in my tests. Adding turns in the coil capacitor made the white spark longer but thickness remained the same. Induction by oscillating electric field (voltage pulsing) fills the coil evenly with charge, volume of charge increases. When this occurs in a coil capacitor it pulls in energy that has more volume than density. Energy flows vertically in a solenoid. This case I have not been able to test, so theory at the moment. When both induction methods are applied to same coil at the same time we get both charge volume and charge density in the coil. When this lump of charge is oscillating in a coil capacitor it will pull in energy from the ambient that also has volume and density and its ability to fill charge collector is increased.

Now we can capture horizontal energy flow in a charge collector by adding capacitor to coil end where the energy comes in. Vertically flowing energy flows through the entire length of the solenoid. How to capture it in a charge collector ? Capacitor needs to extend all over the solenoid so a normal capacitor cannot be used. This gave me prototype area of a simple system.

Take plastic tube, diameter large enough so that you can put in ferrite to test with and without core and perhaps try resonance testing. Wind one layer of aluminum foil on it, insulate layer, then another foil and insulate it. Wind it as tight as possible to get good Coulomb effect. Add leads in both ends so you can test capacitor from opposite ends and same ends. This forms the charge collector. Next three layers of bifilar windings using enameled wire (fine gauge) all over the tube. One layer is Joule thief primary, second layer is joule thief step up and third is the voltage pulser. Add the aluminum capacitor to voltage pulser coil that has diodes in place. See wistiti's drawings for connections if unclear. Now you can test several things in one build. For example, vary which layer is the joule thief primary and which is step up etc. Measure capacitance of the aluminum capacitor and use similar capacity plain capacitor instead. Resonance testing by sliding ferrite core inside the tube. Plenty of variations to test, should be interesting.

wistiti, I did not quite understand what you meant. Try the capacitor tests if possible before advancing. This way we can learn more of the behavior of capacitors as charge collectors.

dieter, your work is valuable. This is open source development, everyone does what he pleases and best solutions will come out eventually.

danas, good work!

[Jack Noskills]

To avoid any misunderstandings I made schematic of the prototype test device to experiment with vertical energy flow. There is diode bridge as a rectifier, might not be required but I put it since it is known to work at the moment. Also known is that ground improves output, floating ground might also work but it is not tested yet. If there is resonance it occurs in the joule thief secondary and voltage pulse coil, together they form one four units long solenoid. Moveable ferrite core should help in finding the sweet spot. Pick up coil capacitor winding is wound on top. There are blocking diodes in the coil ends so coil pair is in parallel. This results in a coil pair that has length of one unit so quarter wave relationship exists between primary and this pick up. The output marked as 'Load' has pure energy and 'DC Load' has hot electricity. There is safety air gap as we don't know what to expect. If you start using 1.5 volt joule thief circuit then this should be safe to experiment with.
 
If two layers of bifilar windings are added then turn offset optimization can be tested, see figure 6 in the pdf on page 2 how to connect layered coils.[/font]


Second joule thief primary can be wound over all coils to experiment with higher voltage pulses. This will replace the first joule thief winding.

[Jack Noskills]

To avoid any misunderstandings I made schematic of the prototype test device to experiment with vertical energy flow. There is diode bridge as a rectifier, might not be required but I put it since it is known to work at the moment. Also known is that ground improves output, floating ground might also work but it is not tested yet. If there is resonance it occurs in the joule thief secondary and voltage pulse coil, together they form one four units long solenoid. Moveable ferrite core should help in finding the sweet spot. Pick up coil capacitor winding is wound on top. There are blocking diodes in the coil ends so coil pair is in parallel. This results in a coil pair that has length of one unit so quarter wave relationship exists between primary and this pick up. The output marked as 'Load' has pure energy and 'DC Load' has hot electricity. There is safety air gap as we don't know what to expect. If you start using 1.5 volt joule thief circuit then this should be safe to experiment with.
 
If two layers of bifilar windings are added then turn offset optimization can be tested, see figure 6 in the pdf on page 2 how to connect layered coils.[/font]


Second joule thief primary can be wound over all coils to experiment with higher voltage pulses. This will replace the first joule thief winding.

Added diodes according to wistiti's drawings to make the schematic more complete. Output labeled 'FB' is for feedback to oscillator. Before closing the loop consider what happens to your oscillator if voltage changes from 1.5 V to 12 V. If voltage pulse increases then result is a runaway and something will break. Series capacitor connected directly to ground is a simpler option but since it is untested at the moment I left it out.[/font]
In the 'DC Load' side the charge collector plates are most likely unevenly loaded with charge. Connecting them through diodes to load to ground could be a working solution. But untested so I left it out also.[/font]

[wistiti]

Hi guys! Just let you know I have play a bit with the concept today. I try copper foil as a coil capacitor for the secondary But have not good output.

The best I have until now is with multi layer of bifilar open coil as the output.... more to come when the time permit!

Hope the best to all!