The Resonance Energy Device Secret Revealed

[Lakes]

Can I have a "naked jesus ufo" mockaloackachocablocker to go please?

[Jimboot]

I do like your videos TK,, they are fun and often educational.

Your circuit must be at a fairly high rate since I can see no flicker in the light.  I suppose it does not need to be so high for my eye not to see it.

Me too! Not so curmudgeony

[hope-hope]

thank you Void, thank you TinselKoala ,

i don't have a working prototype yet,  i am facing problems with the pick up coils,i have a request for TinselKoala, can you please refer me to the schematics, i read about the QEG and i know it generate reactive electric energy as of my system E-TBC, i am waiting your reply thanks in advance 

[TinselKoala]

@hope-hope:
Thanks for asking.

You probably should buy or make yourself an inductance meter. This will help greatly in tuning your systems. An Arduino can be made into a very good inductance (and or capacitance) meter with only a few extra components, or they are available cheaply from China, or you can use your oscilloscope and a known capacitance to determine inductance.

The two resonance etc. calculators I like are:
http://www.1728.org/resfreq.htm
http://www.sengpielaudio.com/calculator-XLC.htm

I give full details of the microQEG in the playlist:
http://www.youtube.com/playlist?list=PLml9VdOeqKa-k7J7vO_I22fVc-h8wcdLf

Please watch all the videos, in order, before you jump to any conclusions.  And please note that in spite of the slight "spoof" character of some of the videos they all have important messages and are all 100 percent true, nothing at all is faked as the moderators at PESN have falsely accused me of doing.
The schematics are shown in the videos or linked in the descriptions, and they have also been posted in the QEG thread on this forum.

Basically, I'm using the concepts of resonating a LC tank circuit and near-field coupling of tuned air-core resonators. By choosing the specific components (coils, capacitors, semiconductors) you can work in many frequency ranges with the same basic circuits, depending on the effects you want to emphasize. If you want "cold electricity", "radiant", tune your system for high frequency operation, 1 MHz or above. If you want great _peak_ power values from flyback transformers, most will resonate between 20 and 30 kHz. If you want good power throughput in wireless power transmission systems, 750 kHz or so will do the trick. If you want good heating in inductive heater systems, 80-150 kHz seems to work well for most workpieces.  You will set these frequencies by your choice of inductances and tank capacitors. In all cases your capacitors should be voltage-rated well over your power supply rating since they will be experiencing voltage rise due to the resonance in the tank circuit. 5x or 10x over your input voltage is good. Use mica for the highest frequencies, poly film types for mid and low frequencies, and it's good to build up the needed capacitance from smaller units in parallel as this will put less stress on the caps.

The "receiving" circuits I use are pretty much the same as the ones you have posted, but no wire connection to the "transmitter" is necessary, although it can be used. Use polarized electrolytic caps only _after_ a rectification stage.

Good luck, feel free to ask me any questions either here or on the YT video comments, and please report your progress and results!

[hope-hope]

thank you TinselKoala 

i saw your videos they are nice, wish to have a laboratory as yours !    in fact i don't have an oscilloscope neither a frequency meter or L/C meter.

I have a new idea consist of working with higher frequency to achieve standing wave, i think this is the best way to avoid problems in the pick-up coils, using the natural resonance frequency in L2 coils will solve our problems to collect the available power using an E-TBC

standing wave created when the reflected wave meet the original wave in exactly a division or multiplication of the  wave length of the working frequency... with this the created standing wave will have a fixed position along the L2 coil regardless of the presence of High capacitance electrolyte capacitors ( very low impedance in high frequency which cause the die out of reactive energy which in turn isn't able to do real work ) 

An E-TBC work according to the same concept NATURAL RESONANCE because the capacitor is involved inside the coil in a unified state, i suppose the reflected waves see the coil ends as a capacitor plates! 

http://en.wikipedia.org/wiki/File:Standing_wave_2.gif

the work of a standing waves is reversed compared to an E-TBC, in our E-TBC the capacitor exist in one point but in a self-resonating coil the capacitor exist in the edges... in other words this look like the past light cone of an operating E-TBC but in repulsion force manner which increase positive energy, the voltage and current both has the same frequency and bouncing in the same wire, because of that, the resulting standing waves will occupy the same positions, this of course will correct the phase between current and voltage since the standing waves is related directly to wire length!


i did some reverse engineering calculations and i found the best practical frequency to work with should be around 20MHZ, this will give a quarter wave length of 3.75M? I attached a photo of the specification of L2 coil such as the wire tubing diameter  etc....
working with two coils wound CW + CCW is better, when the phase between current and voltage is correct, collecting the available energy will be easy.

the E-TBC  should have a very few turn, one turn is good and a capacitance of around 1 nano farad, i welcome anyone could help us with experiments and result, so we could go further more with this project ...