The Idea is:
 a high voltage capacitor that is made from two plate coils.
The capacitor is discharged by using impulses.
This is done in an unique way.
L1 is pulsed and creates voltage impulses.
L2 is series resonant and recieves the impulses from L1.
L1 and L2 are close coupled, this reduces the power draw (proven in the past).

one of the capacitor plates is the L2 coil. It is series resonant (low impedance) and impulsed.
These impulses change the voltage of the plate, and thus the voltage of the capacitor.
 
The other plate of the capacitor is the L3 coil. It is parallel resonant (high impedance), this coil is grounded by a series high voltage capacitor.
This plate is given a negative voltage DC offset, which can be created by the impulses (or an external HVDC power supply). This way the L2 L3 form a high voltage capacitor.

As a dielectric between L2 and L3 I use a mixture of epoxy resin, and titanium dioxide (k=110). This is made air free in a vacuum chamber.

L2 and L3 are LMD resonant, their voltages are out of phase. If needed, L3 can be flipped over, and this makes the voltages in phase.
But flipping over is depended of the inflow of Aether current from the collapse of the coil capacitor. This inflow, should assist the L3 parallel resonance (needs testing).

The impulse is fast, and the resulting inflow of Aether current is also fast, Therefor It is wise to make L3 high in frequency, so it will use both the impulse and the inflow of current, to generate a power full resonance. This means L3 is a higher octave of L2. L3 and L1 will have the same resonant frequency, although L1 is only resonant for a half period.

L1 is only resonant when the voltage impulse is created by L1, it results from the transformation of the magnetic field of L1 that build up during the pulse (mosfet on for 50% duty at Fres of L2).
L1's magnetic field energy is thus transformed into a high voltage impulse, that flows through L2 (low impedance path to ground from being series resonant) to ground.

I will use a 5L bucket to poor the epoxy titanium dioxide mixture in. The coils will be Phi ratio coils. the distance between L2 and L3 will be a fraction of the coil center hole diameter.

The distance between the L2 and L3 coils, is related to the amount L3 DC offset voltage. This is based on the Townsend Avalance,
https://en.wikipedia.org/wiki/Townsend_discharge
Which is the principle that makes a geiger muller tube work.
https://en.wikipedia.org/wiki/Geiger%E2%80%93M%C3%BCller_tube
 (L1 and L2 produce beta radiation, when the impulses are tuned correctly).


This is a continuation of the "advancing the Solid State Tesla hairpin circuit" thread:
https://open-source-energy.org/?topic=3424.0
This is a continuation from my work with the Radiant power circuit of of April 2019:

https://youtu.be/1Flj1i0zQ-8

The question rises, should L2 and L3 which form the plates of the capacitor be equal size or not?

equal size gives a balanced capacitor, wherein the Faraday tubes are parallel.

if the negative DC offset L3 is made smaller than L2 by using thicker wire (equal coil mass of L2 and L3) the dielectric field of the high voltage dc capacitor will not have parallel Faraday tubes.

the Faraday tubes will converge from the relatively positive L2 (ground) towards the negative dc offset L3.

During the impulse implosion of the field the aether inflow then is different?
to theoretical... need to build and test

If L3 is properly amplified, a fourth coil (L4) will be close coupled to L3, to get the power out.
L4 is rectified to DC and caps are charged.
L4 is not grounded to earth as L3 is high voltage offset and I don't want to risk spark over.

the charged caps from L4 cant be grounded, so best is to use an isolation transformer to get the power out and reference it back to ground. but that is for the future.

L4 loads down L3, and that will be good.
Since L3 has the same high frequency as the L1 impulses, its parallel tuning capacity will be small, and thus its voltage high.
L4 when loaded will limit this

giving the L3 coil a hv dc offset has many benefits.
the series tuning cap of L2 has no DC component anymore, so i can tune using the cap switch board.

L3 is parallel tuned so there is no dc offset over that dc cap neither, altough it will be tricky dangerous to tune it, as a ground can discharge the HV dc. So I will need to be careful with them.

I might make a new board for L3, using Np0 caps, of low value.

L1 does not necessarily need to be tuned with a parallel cap over the high winding. PVC is a good dielectric. but it isnt good at those high frequencies. So here probably a low value Np0 cap will also benefit the impulse. Although it will slownit down a bit, it will better release the energy again. I hope...
because I still see bumps of energy coming later, after the impulse, before the switch closes again to charge L1 up with a magnetic field again.

about that charging up of L1, I would expect it to be at the speed of L1s resonant frequency. but ot seems to be able to charge up much longer, as it doesn't saturate, due to not using a ferrous core.

This means at low frequencies L1's magnetic field is charged up with lots of energy, giving a powerfull impulse.

Soon I will close couple L1 and L2 again, and the power will drop again. while still producing hv impulses. I wonder How efficient I can get it.

tomorrow my vacuum pump and chamber will arrive. then I can start testing the titanium dioxide epoxy mixture, and make a hv capacitor out of it.

using microwave transformer and diodes, with 2 high voltage caps and no resistance or load, I get a 180V ripple at
2400V dc.

I'll have to put in a current limiting resistance between the caps (just like tube amps have) to trim that ripple down.

vacuum chamber for epoxy has arrived.
and it works. now I can start mixing the titanium dioxide with epoxy to find the right mixture. then use the vacuum chamber to pull all the air bubbles out. can have that in the high voltage dielectric

made my first test batch of dielectric...
100gr basis 50gr hardener.
slowly added titanium dioxide.
I need to seeve this first, it had many lumps.

everything stayed pretty liquid until I had added 51.72+25.48+21.60+31.12
it started to get thicker.
then I added another 20.19 to get equal weight ratio. this was too much. it didn't flow properly anymore. it dripped frim the mix stick. to  much...

I made 2 capacitors from copper plated epoxy, distanced by 3x 5mm nylon rings each.

in the vacuum chamber the mix came up but didn't go down. I tried 5 times the air was not released from the mix.

going to let this dry and try less TiO2 next time. 75:100 epoxy is best probably.

the caps have hardened out and they show a value of 70pF each.

now I will have to compare it to the capacity of an equal cap, without the epoxy titanium dioxide deielctric material

note that the copper plates are 5mm distanced, and the plates are small, around 3x4 cm

I compared the capacitance of an air cap, that has slightly larger plate area ( I chipped off the corners, so it could fit in the cups).
The air cap, is slightly larger than the two parallel caps. those have together a 140pF capacity.

the slightly bigger air cap (also 5mm distanced by 6 nylon rings, equal as the 2 caps) has a measured capacity of 26pF

the open leads of measurement are 2pF so I will substract that.
68*2=136/24=5.67 more capacity, rounded of to 6 because of the smaller plate size.

I think this measurement has a high error rate, and I can do better, by using less titanium dioxide in the epoxy mix.
Might even get better results, If I can get the air bubbles out.

So far so good. It works

edit, after letting the hv caps set for a few days the values dropped to 61pF

N Tesla said in a document referring to Roentgen rays, that a disruptive capacitor discharge induces longitudinal waves.
He didn't say it like that, he had a picture showing, a box, with an isolated plate inside, that was charged up. He the stated that when the plate was connected to ground, a longitudinal wave was produced. I'll have to look it up again.

This says to me, a dielectric field that is fast discharged, sets the Aether into a longitudinal motion.
When it is slowly discharged, the faraday tubes move side ways, and create a transverse magnetic aether vortex.

But if smart enough, these faraday tubes produce a longitudinal aether wave. It is as if the Aether is bound to these faraday tubes, and when these tubes loose potential very fast, the surrounding Aether that was bound to the faraday tubes, glides off.

I dont know how to properly put it into words, but volumes of Aether glide along the axis of the faraday tubes.

And this hv cap discharge, is done, (soon) by fast impulses.
And these impulses are cheap, when L1 and L2 are close coupled, very low power is needed for impulse production.

when making my next batch of epoxy titanium dioxide mix,
I will heat up my chamber up. higher then the 19C of last time.
I might even put the vacuum chamber on a heater, to get the temperature to 25C.

The goal for this, is to get the epoxy viscosity to the point it will release more air. And, to cast the mix between the coils and extract the air out of it.

I have thought about casting it in 2 steps, but will not do that.
It will be one cast.
Still thinking about how the coils should be.

The 5L bucket is somewhat smaller im diameter, and the PHI ratio hole is relatively bigger then what I worked with.

It makes the coils smaller. and less windings. less inductance  less capacitance. It will require larger tuning caps to get the resonant frequencies low enough.

Then there is also the question if I shall mirror one of the coils (flip it over, so it is counterwound).
With LMD resonance this makes the sine waves in phase giving an equal voltage difference.

I guess I'll just  have to test and see. Or, ask before going to sleep

L3 will get a dc offset. and I am wondering if the size of the series capacitor will make any difference.

the cap will hold the DC offset, while L3 is parallel resonant.

when L2 is impulsed, the idea is the cap needs to hold its voltage steady.
so the vacuum created will draw in the ambient aether.

If the cap is small, the field strength might be to small, which could male the dc voltage offset drop.

I made a new drawing, with more detail of the circuit that I'm working on. Still not fully build, but tested the DC offset of L3 and it works.

 Just made a small mistake, putting the L3 tuning cap to ground, instead of to the outside rim of the coil.
This put the DC offset over the tuning caps it worked fine until I went over 1000Vdc offset. then the switches sparked over.

These mistakes can occur, but when working with High Voltage... its ... scary.
But I am taking safety measures. discharging everything, measuring, and one hand ....
I use the High voltage probes to measure the DC voltage. works fine.

ok tested again, now with the parallel tuning cap correctly connected to L3.
It works. easily could make 2.5kV impulses, and 2.5kV dc offset on L3, using a 630nF 4kV cap, made out of 4 series parallel 2kV caps.

jikes thats 1.97 Joules (at 2.5kV) in that cap, ready to discharge within a fraction of a second.

3kV is 2.8J better be careful.

C1 is parallel over one of the windings of L1. It can regulate the duration f the impulse by lowering the resonant frequency of L1.

But more importantly it can handle faster frequencies. L1 has a soft pvc coating that acts as a dielectric, but it is not suited for handling the high frequency impulses.

best would be Np0 caps and as the value will be low (100 to 500 pF) I will order some high voltage ceramic  capacitors that can handle 3kV

this blog about working with electricity has good high voltage work instructions

http://www.blog4safety.com/2017/02/safety-precautions-to-take-when-working-with-electronic-equipment/

not feeling well. Not sure if its from the coils or not. Didn't test for a few days, but when I did it was with high  voltage impulses.

I need a solution for this. Better body grounding, maybe even grounded plates.

I keep feeling the aether is set in motion along the direction (longitudinal) of the Faraday tubes that make up the dielectric field, being collapsed by the impulses.

this moving of aether is moving way past the coils.
If it can create a close loop the energy can circulate, but if not, my capacitive body is an end terminal.

also been thinking about impulsing L2 at a lower octave, using less series capacity will drive the frequency and voltage up.
L3 still can be tuned to the lower octave impulse frequency.

this way the voltages get much higher, and a better interaction with the surrounding aether is made.
the field of the coil needs to be charged and that needs high voltage, as the coil capacity is so low.

pff still tired. sleep like a log

Are you sure you're not suffering low iron levels in your blood stream on account of the AC induction coupling effect eating away on the iron itself, either by oxidizing it or making it "not suitable" to carry oxygen in your red blood cells?

And yes, I'm no MD at all, I'm more like a curious amateur in the field of medicin :)

Quote from Lynx on March 21st, 2021, 11:39 AM

Are you sure you're not suffering low iron levels in your blood stream on account of the AC induction coupling effect eating away on the iron itself, either by oxidizing it or making it "not suitable" to carry oxygen in your red blood cells?

And yes, I'm no MD at all, I'm more like a curious amateur in the field of medicin :)

I think it's more to do with the PH levels of my body. This translates to cell voltage. When the voltage of the cells is high (negative charged) than PH is high (alkaline) and then I feel fine.
This is what the "ascension seat" helps me do.

While experimenting, my cell voltage might drop (become more positive). This translates to a low PH level, which makes my body acidic. then I am tired and prone to sickness.

I now am conducting tests not only with the wrist wrap to ground (that has a 1 or 10M ohm resisitor) but also with directly touching ground. and staying far away from the coils, and this seems to work.

I am feeling vital again. And the chair is helping me greatly (its the radiant power circuit of 2019 tuned to 44kcps and I sit on L3.

I was lost for a few days. brought me to my knees. but now its clear again. The vision is this:

4 coils stacked.
L1L3 - - - L2L4

L1 pulsed, producing impulse. close coupled to
L3 parallel resonant (high current)
L3 forms a capacitor with 15mm gap with L2
L2 is series resonant impulsed.
L4 is close coupled to L2 and produces the output.

All coils bifilar pancakes
L2 is positive hV dc offset charging L3 L2 coil capacitor.
L3 could be negative hV dc offset but L1 is grounded so this has its limits.

no coil is flipped over.
L4 is rectified to dc and stored in capacitorbank and loaded.

L4 should not be grounded, so caps also not grounded. isolation transformer is needed if grounding is required.
Not clear if L4 is made resonant, but it will give high voltage, as the load with bring that down again

energy is feeding back from L1 into L2 (impulse) and from L2 into L3 (current amplification) and then back from L3 into L1.

L2 is low impedance by being series resonant which makes it perfect for output into L4 (and giving low impedance path to ground for L1 impulses).

If L3 is made from thicker coil than L2 it will step up the current. L2 and L3 need to be equal copper mass, as L2 and L3 are made LMD resonant (out of phase voltages) but if the current has an issue between L1 amd L2 then tem resonance needs to be used or the L2 is flipped over (or L1 is reverse connected)

L2 to L4 is stepping up the voltage, but doesn't need equal copper mass, so L4 has less wingings then L2.

Ideally all coils are same diameter, but center hole is vital, it needs to be big enough.
L1 also doesn't need to be equal mass, so could be made with higher inductance then L2. as this seems to work best.

first tune without L4.
use a resistive load on l3 and no parallel capacitor.
tune L2 for highest current over the L3 load

Then load L2 with L4, and no load in L3.
tune L3 for max current with parallel resonant capacitor , without changing L2 capacity.

If impulses are to fast (rippling L2) a parallel cap over half of L1 can be used of several pF.

High voltage is key to succes. high voltage impulses, high voltage DC offset.
if impulses are 3kV then Dc between L2 and L3 can be made 6kV (2x from positive and negative dc) as long as L3 and L1 are properly isolated while being close coupled. maybe using ferrite, but that introduces hysteresis.

Ok I'll print this out and hang it on the wall. for if I loose confidence again...

Lets make this work. its time.

L1= 1,5mm2 big coil (should be equal diameter)
L3= 4.0mm2 small coil close coupled to L1 in the middle of the stack
L2=2,5mm2 medium size coil.

L3 is tuned with 61nF parallel
L2 is tuned with 26nF in series
L1 has no cap (but needs one to slow lengthen the impulse duration, to get rid of the ripple yellow))

Fres is 65.1kcps
power input is 1,16A 2x15,6V

The electric field meter is going bezerk when I crank up the power, to get more impulse speed. seems it is almost having a heart attack its racing high in frequency.

I first measured L3 current, with a 4 ohm load, and no parallel capacitor. For maximum current. Then I removed the resistor and added capacity parallel over L3 until it gave a sine in current and voltage.
I needed to reduce L2 capacity, as the L3 parallel tuning board was at its maximum (61nF)
I need to have more caps than 61nF, maybe I should order some 22nF caps...

blue is square wave of mosfet gate,
yellow is L2 voltage 200v/div
orange is L3 voltage 100V/div
green is L3 current 2A/div

I like having the L2 voltage high (1000V pp) as it will be loaded down in the future by L4 coil with resistive load.

now quick back to the chair and recharge

started making new phi coils for the coil capacitor.
17cm diameter uses 449cm 2.5mm2 wire, giving 13 windings
not much windings or copper.
will measure a 1.5mm2 coil after this.

I will use the biggest inside ring of the pentagram

for the 1.5mm2 same coil size, I need 537cm.  It also works nicer, it rolls easier.
more windings 15 instead of 13(2.5mm2)
1.5mm2 also has its wires closer together giving more capacitance. the choise is made. L2 and L3 will be 1.5mm2
537cm plus 2x 40=80cm for hookup,
total 617cm 1.5mm2 per coil
Ok I'll cut 2 pieces of the same length.
including extra wire for hookup.

made 2 Phi ratio coils, for the L2 L3 coil capacitor. was easy to roll. didn't fixate with much hot glue so the epoxy will stick better

I made another coil made out of 0.75mm2 wire, this time I did not measure length or copper mass, just made it equal diameter as L2 and L3.
I will use this as the L1 coil (close coupled to L3)
It will have higher resistance inductance and capacitance then the l2 and L3 coil, which will slow the impulse down, making it longer in duration.
I hope this will avoid the ripple effect on L2.

now I need another coil for L4.
this will be the output coil, and is close coupled to L2 (low impedance).
thick or thin or equal? hmm... don't know yet. let me sleep on it.

I made the 4th coil (L4) also out of 0,75mm2 just like the L1 coil, but I used less wire.
L4 has the same diameter as the rest (17cm) but the inner hole diameter is larger(9,5 cm, instead of 5,7cm)

close coupled a s a single stack of 4 coils, I loaded L3 (close coupled to L1) with a 4 ohm resistor.
L4 is open (will be loaded when L3 is tuned).

I was surprised at how high the impulse voltage was. The L2 tuning capacitor sparked over (above 1300V) As here is the DC offset present.

when I zoomed into the impulse, I saw it had only a 300nS duration, I would not have suspected it to be able to become this fast, as the 0,75mm2 L1 and 1,5mm2 L2 have larger resistances then the 2,5mm2 wire I am used to use.
But I also use less wire lenght...
Maybe I should measure the coils, for inductance and resistance (and capacity, altough that only is when the series connection is opened).

the photo shows L4 on top.

I will still need a cap parallel over L1 to slow the impulse down.