@GK
Always a pleasure seeing and learning about the effects of your works.
As a side note, I have started to migrate stuff from my house to my newly built garage.
This will clear up some great space in the house for a bigger OU lab right beside my existing office/lab.
For guys that would like to see my garage build on time lapse (hahaha) you can go here...
http://www.youtube.com/channel/UCA6T7xOfANBi-onm-9IX8OwCan't wait to get started again. But while I catch up I wanted to share with you (and other OUphites) some of my "thinkings" about SMs TPUs which I have had the last few months to ponder about and muddle over all the devices, functionings, parallels of each, etc, etc, as we all have done for years now.
So let's just start.
Regarding the SM-LTPU (I'm saying SM because now we have a GK-LTPU hehehe), I think that if you looked very closely to the videos and also the LTPU wiring diagram I produced way back, it is very evident that on each of the ltpu center toroids, the two halves are connected in parallel. Seems like because the center toroids are wound in bucking mode style with the four wires coming out individually and only in the ltpu we see the two halves are paralleled from each end of their windings, that maintains a uni-directionality of the field in one toroid and this could be turning energy or the field in one direction each. The second toroid is the same but if it is connected in the reverse direction this would equate to the two fields going in opposite directions.
If two half toroid coils were wound on a standard ferrite core, the vast majority of the field impressed towards the coil would be stuck inside the core as we all know such toroids do not readily cause remote static unless you find the right frequency, width and amplitude to pulse the toroid that would be sympathetic to any specific remote outer rings or coils that would catch the transmission. I had shown this many times in my Pulsing Coils youtubes. This could then mean that the toroid cores are not ferrite type. One option is what if they were enamelled aluminium cores. Each coil pulse would draw in the ether field that could not enter the alu core but be reflected back outwards and available to the outer rings. Like calling in the ether brigade without a landing site. It will just leave but with a good reflector the leaving may be more dramatic then your standard air coil dissipation of the field back from where the ether came. Since we are always in motion, the ether dissipation is left behind as we move ahead and ahead into what the ether sees as us moving through it so fast that anything dissipated would leave the origin. The capture time would be very small.
Put it this way. If I was working at Big Bang Central Station and Universal Observatory and was asked, "where is @GK", while I am looking and pointing outwards from the very point of the BB, I would maybe say something like, "he's just grazing around in the milky way galaxy that is moving at xxx xxx xxx miles per hour". That movement is real and even our solar system does not feel it but it also means when a coil is pulsed while it is moving through space at high speed, the ether lands on the object like a bird lands on a sea going vessel (pulse on) that is caught in high winds. If the ship sinks in the next second (pulse off), the bird just flies with the wind and is taken away until it sees another ship (if ever again). The same ether will never be, always renewed and always there.
Sorry for veering off... hahaha.
One center toroid was in the ftpu, otpu, stpu, 6tpu's and mtpu. In those SM must have used each of the two toroid coils individually but one half pulsed at 0 and the other at 180 degrees off. In the ltpu he is using two toriods, each one with the two coils paralleled then each full toroid was pulsed one at 0 the other at 180 degrees off. What does that do. Consider that the ltpu outer vertical wind(s) (receivers) is or are obviously stationary. The verticals do not move. But curiously, if the 2 toroids are at a small enough distance apart but far enough for each field to end in a different position around the fixed outer rings, then you now have two opposing fields each one hitting the outer rings at 180 offset and at different physical locations. There is the physical movement of the fields. It is toroid one pulses then off then toroid two pulses then off and so on. This will MOVE two opposing fields over the outer vertical rings. The pulsing frequency is to be discovered of course but if the logic holds in the mind it has a much better chance of working on the bench. hehehe
So...let's go a little further.
Also, regarding SMs statement of the consequences of two fields moving in opposite directions, myself and I guess everyone else that has delved in the SM devices have always thought that the two field directions are relative to the outer rings having two coil winds that are pulsed in opposite directions, but, what if this is partially the case. What if the toroids are the ones initiating the two field dance. It would be like a dual blade food blender creating some great wiped cream ether energy available inside the LTPU verticals where the outer coils catch this and transfer it into the output.
That would explain why the sliced MTPU pie showed so few wires. The MTPU ran with one center toroid and was producing around 400 volts with all its outer coils, so in the LTPU catching 600-800 volts would not be a problem but then the question of amperage arises. This is where we should start to think about paralleling the outer vertical rings to increase amperage. Two halves or four quads on vertical would be a first suggestion. Even eight depending on how much voltage each could produce. It could even be each vertical is only one or two turns then all of them are paralleled. That would hold with SM statement of "one wire pulsed over 1000 wires". This can all be worked out once the main system is functional. But there is more.......
I would like to now relate to your last build of the GK-LTPU as specified above. From what I can understand from your videos and posts, this build incorporates the following but please correct me if I am wrong.
1) Two toroids with two coils each wound in bucking mode (140 degrees around each) with their four wires coming out of each. Core or not is not important right now to just see the minimal effect.
2) One vertical wind going 360 degrees around the outer periphery.
3) Three horizontal rings top, center and bottom of one turn consisting of dual conductor speaker wire.
So now I have these observations and recommendations to try with your build if you can.
A) If your center toroid coils are wound in bucking mode, put them coils in parallel. If you look at the toroid from the top with the coils going left to right, one over the top half and one over the bottom half of the core, put the left wires together and put the right wires together to get your parallel.
B) Make two outer vertical winds with your existing one wind and put a dioded cap on each one. Put a volt meter across each dioded cap.
C) Now about the three vertical rings of two conductors and of one turn only. This is not good to have only one turn since half of that is doing nothing thus you would not be able to cover 360 degrees of pulse activity with only one turn. So just put the two conductors in series to make one ring of two turns instead of two rings with one turn per top, center and bottom horizontal ring.
D) Connect one of the top horizontal ring (H-ring) wires in series to one of the paralleled toroids and do the same with the bottom horizontal ring in series to the other toroid but make sure that one is opposite the other. You will have one wire free from each toroid and each H-ring. Now when a toroid pulses it will also pulses one of the top or bottom rings. Think of it like the toroids provide + and - potentials and extends these pulses into the outer ring system via the top and bottom horizontal rings.
E) Leave the modified center H-ring alone for now as I will be getting to that soon enough. hehehe
D) Ok let's find out the best frequency of operation. If you have just two frequency generators even with their small output capacity, connect one fg to the free wires of the first toroid/H-rings pair. Now it's time to play with the FG frequency, width, amplitude etc to find the settings that produces the highest gain in the outer vertical winds that are dioded and capped. Try again with the diode on the other cap end and see if one is better then the other and keep the best.
E) Now take your second FG and do the same with the other toroid/H-ring pair while the first FG is still active. If you ever see the voltage rising very high in the verticals, you will need to add a load on each cap/diode and whatever you do, do not turn off the FG if the vertical outputs are full of juice as this could create a back spike and ruin the fg.
F) OK once you have identified a good frequency range, it's time to build two solo circuits that can be battery driven and provide the same pulsing effect as the FGs. The criteria for the circuit is that is must start with only 1.5 volts but it must be able to then increase its voltage throughput and control. You can do this by testing it with one 1.5 volts battery then adding more batteries in series.
G) Try the two circuits and make sure they are providing the same function as the FGs with comparable results in your vertical output coils.
H) Now you need to make a small radiant energy circuit (REC). The well known circuit with caps and diodes that we have all used before. You probably have one lying around already.
I) Now remove the batteries from your pulse circuits and connect the REC + and - to the battery input of your circuits.
J) Now connect the REC antenna side to the center H-ring.
K) Now if the antenna can produce 1.5 volts that device should start up on its own or with some help via a moving magnet. When the 1.5 volts is available to the pulse circuits and they start pulsing, this will increase the radiant energy available in the outer rings thus increase what the centre H-ring antenna can send back to the input of the circuits so this would be a very simple method of looping the energy back to the source.
This would be a good place to then continue on the R&D. With the above build strategy, what are the energies involved since this is much more then your regular two coils on a core coupling?
a) The toroids will pulse to a frequency that is sympathetic to the outer vertical coils and reach them via air to air coupling.
b) The top and bottom H-rings will also extend the toroid air to air with a more direct proximity pulsing.
c) All the activity in the outer coils and rings will create more and more radiant energy available to the center H-ring that resupplies the toroid drive with energy.
d) As the energy increases in the outer coils and rings, the resupply to the source also increases and the total system should now function with gain.
It may be a good idea to put a 1 amp fuse on the REC antenna just in case you get a runaway.
Sorry for such a long post. I just had to give you this input although I do realize it is rather redneck theory derived from ether impress and spin conveyance. I will talk more about this in my older thread. If both exist, then the above should show some interesting results.
I would say the frequency will be in the audio band where we know feed back but this is just a very educated guess when considering all the times some rock band feed back forced everyone to cover their ears in horror, feed back is a nasty b&t$h wait'in to crush your ears. (Ouuuu that was bad.)
I will have to build this and try it myself in smaller scale then your LTPU to see the effects. I'll try the ftpu format again because it is the first tpu and hopefully any runaways will be minimal and the build is easy. Hmmmm.
In the control circuit, it has to be simple and I am inclined to think that he was using zenor diode breakdown to make or could I say engage the pulse. I don't know how yet but I do know the ftpu had diodes and I am sure radio shack sold identical looking zenors as well. hahaha
One last thing. Try to keep your classical hand held ammeter like SM tried around the ltpu to see if you can maybe play around with the toroid placement in the ring. When positioning the toroids into place, I don't think this was randomly placed but rather a well thought out affair, This could explain why he had that amprobe handy. He did not place the two toroids in perfect center but rather offset from there. I am sure he had a reason to lock it there. Sometimes when I was pulsing coils, just a small change in distance would make a world of difference in results. I think SM was using his ammeter not only to measure the ambiant discharges around the toroids and rings as the system is running in demo, but more importantly, to best position the toroids as well. Just hold the probe above the toroids as you move both around in the ring and see where it plays louder. hehehe
Have a good one man.
wattsup
PS1: I'll be back soon enough.
PS2: For all other OU developers, I think that while a TPU is developed, maybe consider the radiant energy circuit to be all you have to start up the tpu. Put the antenna of that circuit inside your coils and see what happens. Is it possible that Tesla was not kidding. Who said the receiving plate (or antenna) has to be in open air 200 feet high. I think he would have used a very big version of this to energize his Wardencliffe and send electricity around the world for free. Basically, imagine having your antenna inside the transmitter.
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Topic: The final answer... (Read 128400 times)
