Thread: Eric Dollard
View Single Post
 
Old 07-16-2012, 05:47 AM
garrettm4 garrettm4 is offline
Senior Member
 
Join Date: Oct 2010
Location: Orbiting Sol somewhere in the Milky Way
Posts: 178
The work of Dr. Stiffler; Relavent to the CRI?

Wow! I honestly about shat myself when I came across Dr. Stiffler's work on his SEC circuits! Those YouTube videos are priceless and have opened my eyes to some alternative uses for the Tesla Transformer and a general overview of one-wire circuit topologies.

Call me out of the loop, but I hadn't the slightest awareness of his existence and work until three days ago. I want to point out that I don't particularly agree with his theory of the "energy lattice" let alone the vibrating Bose condensate / phonon stuff Frank Znidarsic has come up with. Although, they seem to be in agreement in experimental results / theoretical explanations, which says a lot. Also, Dr. Stiffler seems to have a working theory as to how and why, that's backed up by all his various experiments, which also says a lot. However, I'm not here to say he's right or wrong (nor am I qualified to even give an opinion), I just wanted to point out that there is a lot that he has shown and done which parallels whats going on here in this thread on the CRI.

I think he has done much good in, inadvertently, showing the general principle of what I believe to be an alternate mode of excitation, the one-wire inductive discharge mode as opposed to the two-wire mutual induction (through a primary loop to the secondary).



I believe Mr. Dollard had called this arrangement the "Steinmetz Coil" connection. I never could quite grasp this circuit arrangement until I watched the YouTube videos that Dr. Stiffler had put up.



If one were to shrug off all the explanatory details of Dr. Stiffler's circuit, and just examine the circuit for what it is, you would see a transistor passing a pulsed current through an inductance coil, with a second coil connected at the junction between the two. This is in essence an inductive impulse circuit, there is no mutual coupling as far as I'm aware. The collapsing field of magnetic induction is directed towards the transistors collector terminal, it just so happens this is where the other coil is connected. I believe this collapsing induction, as a time-variant E.M.F., is what actually triggers the second coil into oscillation from its distributed constants. If the first coil were to discharge at the proper frequency the second coil would go into a resonant state.

If we examine the second coil as a one-wire transmission line, when driven at its natural resonant frequency we would see a large E.M.F. developed at the end-terminal or free end. Now insert an "AV plug" (at the end-terminal) and some sort of DC load (on the "plug"), and boom! You have a one-wire back to two-wire transformation, and you now are charging a capacitor or powering a neon or LED. Cool stuff indeed.

I honestly believe that the coils Dr. Stiffler uses ("cardboard coils", long skinny solenoids) are limiting his performance. If you were to use the coil design outlined by Mr. Dollard (equal width to height, spaced windings, etc.) you would see an immense increase in performance of the SEC circuit, due to higher magnification ratios seen from better coil design. So for anyone who has built a model coil based on Mr. Dollard's engineering plans you might want to look into Dr. Stiffler's SEC and give it a whorl and see what you can achieve.

A method to turn up the power level, to dangerous, would be to build a resonant inductance coil triggered by a thyratron, this would be a Steinmetz coil type connection to a Tesla coil. This arrangement has the possibility of very high energy operation and is much more immune to damage than semiconductor switches, however it is limited to low frequency operation. You might be able to see new effects that just aren't present at lower power levels. Although, you could most likely achieve the same results with properly designed vacuum tube or even transistor based circuits.

On another note, the use of a Guillemin Pulse Forming Network (PFN) could also be used to drive the Tesla coil, I don't think anyone has really talked about this method of connection. I'm foggy on the details, but I believe this network, when designed properly, acts as a transverse to longitudinal converter so you would be driving the Tesla coil longitudinally and thus with a one-wire inter-connection between the two. This is similar to, but not the same as, the Steinmetz coil connection.

I believe there are a few more interesting methods of excitation, but the Guillemin Line and Steinmetz coil connection are the modes I'm going to investigate, this of course, after I finish construction of my Secondary / Extra coil. Also, from watching Dr. Stiffler's videos, I found a very interesting one where he shows how two capacitors that have the same effective values, but huge differences in mass, have different effects. I think this corroborates what Mr. Dollard has been saying about matching the mass of the primary loop and its attached resonant capacitor. This is definitely something worth looking into.

*One more thing, I would be thrilled to see someone get the "concanted" configuration working between their secondary / extra coil. From what I understand this results in a half wavelength spanned across the entire setup, whereby each coil is operated at 1/4th wavelength. Curiously, instead of the half-wave spread across the two coils as a single wave node (rise to fall), you have two 1/4th waves nodes (rise to maxima) that are in the same direction, or the node polarity / phase is the same across each coil. This means that the voltage across the entire transmission line is doubled, and is additive like batteries in series! I don't think any ordinary configuration can actually do this, so this is definitely something to strive for. Also, I would be interested in seeing a concanted configuration hooked up to a SEC circuit, I dare say the effects would be magnified immensely.

Garrett M
__________________
 

Last edited by garrettm4; 08-06-2012 at 05:26 PM.
Reply With Quote