Electrotek,
"... high energy discharge between the first and second anodes is transferred to the charge receiving means ..." Discharge between anodes - HV anode and LV anode, and energy transferred to the grid, it didn't say discharge to the grid. It is exactly the line that caused me to think about tube meaning.
And it is the best way Gray could explain energy on the load.

Mike: It also doesn't say "...(some kind of energy within the) high energy discharge between the first and second anodes is transferred to the charge receiving means ..."

However, statements later in the patent do give this impression. That's why the mechanism of operation is hard to determine from reading the patent.

Boguslaw: I like your line of reasoning. After you first started talking about this, it occurred to me that maybe the CSET is the high frequency capacitor, at the end of a single wire circuit.

But I think 42 is a switch which connects the motor's inductive kick to the battery - after the motor is pulsed.

Can you make pancake coils to test your circuit?

Thought I'd throw a little something into the mix. Here is a comparison so you can see the old and new circuits side by side. This may give some insight on what Grey was doing or trying to do with the CSET.

I almost forgot, Here is the other one.

great comparison beshires1!!!

makes it a lot easier to see whats going on there and compare

Charging through the grid

I have to side with Mike on this. I don't see anything in the patent that even implies that the spark should jump to the grids. If this was the intent, then why are the grids constructed the way they are, with a significant surface area? It either has to be for radiant energy receiving, or to provide a capacitance, or both.

I don't doubt that this is a great way to charge a storage cap. It just doesn't look to me like what is described in the patent. Although I haven't popped a coil, I did prove tonight that I can charge a cap from the energy coming off the grid without any arcing to the grids.

Granted, I only charged a 10uF cap to 20-30V, but it only took a few seconds, and I'm only using a cordless drill battery chopped up through an ignition coil. Given my puny attempt at recreating that effect, I think it's within reason to accept that Gray's motor could have done a much more effective job of charging cap 38 and driving a load. He was using some very powerful supply batteries, a much higher frequency, and I suspect his carefully tuned circuit resonance would make that job a lot easier.

Just my two cents for this evening. Good night.

4595975, patent say. Capacitor 16 is charged wit high voltage DC potential. It ain't supposed to do nothing but set there a charging up. Then when the commutator contacts align up it then switches on the low voltage, the capacitor 16 discharges into the tube (Between the anodes , And this high energy pulse is electrostatically coupled to the grids. Pulsing the inductive load (Coils) As the field collapses the BEMF charges capacitor 38 Because the commutator has removed the supplying circuit, and thats the only place for it to go. Capacitor 38 discharges this stored energy into the Battery for recharge purposes. This means that the tube will not work unless the electrodes are spaced to the breakdown voltage of the capacitor. Capacitor 16 discharges into the tube, pulsing the coils, Capacitor 38 discharges into the Battery, Not back thru the load (coils). This is How the tube works. Read Items 20 thru 60, patent 4595975. Without the commutator doing the things it has to do durning this process, the tube will not work.The amount of energy will be preportional to to the amount of time allowed to charge the capacitor and the intensity of the high voltage used to charge the capacitor.
This is my two cents and is in line with the patent. And quite frankly it should work.

resonant charging choke

I've built several variations of the older one and they all work.

In one schematic I posted not too long ago, I showed the resonant charging choke coming off the coil. The output of the ignition coil thru diode through coil then to the cap is a "resonant charging choke". Simply it limits current, which isn't an issue in this case anyway since it is the output of the ignition coil but what is relevant to this is that you get 2 pulses for the price of 1 to the cap and this is one of the reasons the cap charges quicker. One pulse goes through the diode and through choke to the cap.When the choke collapses, the inductive spike leaving it moves to the cap as well since it is the only place for it to go when the diode shuts at the front of the choke. 2 pulses for the price of one.

This is the same concept that Meyer used on the VIC.

I used that method for a long time on the WFC for both choking current and getting 2 pulses for the price of one to the wfc. In this case, the cap isn't a water capacitor that is getting charged.

I believe Mark McKay showed this in some Mallory ignition system varations as possibilities of how the caps were charged. It is a very standard thing to do and simply makes the cap charge better with the same input.

http://www.energeticforum.com/43338-post418.html

Expirments: Not all sparks are equal...

Hi all,

I've done some experiments during the weekend and I noted that not all sparks are equal. When I hook up my tube to a flash-circuit from a cheap one-time-use camera, I am able to draw about 4 sparks a second over a very small spark-gap. It's about 0.1 – 0.3 mm, I guess.

When I connect a energy-saving light bulb to the LV-rod, it flashes brightly, but a neon bulb connected to the “grid” doesn't light at all. However, when I connect the light bulb trough a coil, it does, although just visible (connecting nothing to the LV rod gives the same result).

So, loading the LV rod with a coil and a bulb does not appear to influence the coupling of the rod to the grid. Also, the coil I used attracks a piece of iron - the coil I used is a pull-relay from an old cash register. Not all coils are equal, thfough. I could connect two similar coils, which appear to have thin wires inside, and the bulb would flash and the coil continues to attrack the iron. With some other coils in series with one of these, no flashing. With a 12V DV motor from a battery-operated drilling machine in series with my pull-coil also flashes tfhe bulb, but no (visible) movement from the rotor.
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Connecting the flash circuit the other way around, does not appear to make any difference.

I hooked up the scope to the circuit with the “positive” (3 connections) coil-end of the flash circuit connected as ground and the common connection of the flash circuit connected to the HV rod.

At the HV rod, I saw a negative bias of about 350 - 400 V (digital Volt meter said about -370V) and a positive discharge pulse shaped more or less like a half sine, with a peak of about 40 V and a pulse width of about 1 millisec.

At the LV rod, I saw a sudden voltage drop to about -200 V, which more or less graduall rises to about -250V and then discharges to ground. There also appears to be a very short (negative) spike at the beginning of the pulse, but I'm not 100% sure. Anyway, the voltage drop at the beginning is very sharp, the scope can't follow it, but it appears to involve a sudden spike, settles at about -200V and then gradually drops further to about -250 V over a period of about 1 millisec, in sync with the HV pulse, and then drops off like a classic RC discharge in maybe 2-5 millisecs (don't remember exactly).

Every now and then, I get an arc, with a sissing sound. Then, the large cap in the flash circuit gets discharged (at least much further), and the bulb lights up for a longer period of time, but not to full brightness. After that, it takes a while for the circuitry to recharge the cap before the sparks appear again.

At the LV rod, I can draw tiny sparks into the coil and light bulb and make them attrack c.q. flash, but it is quite difficult, since the gap needs to be very tiny.

To sum this up: with the flash circuitry, I can get a light bulb to flash to full brightness and have a piece of iron attrack by a coil, at about 4 Hz, with pulses/sparks with a duration of about 1 millisec.


I also experimented with an old car ignition coil. The behavior was very different. The neon bulb connected tot the grid would still flash weakly, and I was able to draw considerable sparks from the LV rod. At least 5 mm, when widening the gap further, sparks started to jump directly from the rod to the grid. However, no flashing of the bulb and no attracking by the coil. When sparks jumped from the rod to the grid, the neon bulb would flash brighter, but no full-bright blue flashes.

However, the whole circuit would become much more unpleasant to handle. I got several shocks while accidentally touching the circuitry (like when disconnecting a coil, etc). And also, at first I used my computer to operate a relay. I had the ouput of my sound-card connected to my right speaker, and used the output to the left speaker to drive the relay. On the computer I ran “siggen”, which would generate a pulsing, triangle or saw-tooth signal to operate the relay and I could vary the frequency. Worked like a charme, .... , until a spark from the LV rod hit the wire from the speaker to the relay. It appears my soundcard wasn't to happy with that, so I now use a simple RC oscillator around a second relay.

To sum this up: with a car ignition coil, I get much stronger sparks, but no flashing of the light bulb, and no attracktion of the iron by the coil.

It would be interesting to see on the scope what the difference is. I suspect the key difference is the duration of the spark, but I don't think I can measure this directly with the scope, because the voltages are probably much higher. Maybe I can try a 100-1 voltage divider using two resistors?

All in all interesting observations. With sparks of only 2-300V I get a bulb flashing to full brightness and with sparks much stronger, I get nothing.

Oh, and the tube construction does not appear to make any difference with respect to the flashing and coil attracktion. When I have the spark jump directly into the coil, the bulb also flashes. Also the small neon bulb connected to the grid continues to flash just visible.

comments

If anybody draws out on paper the positive potential of the HV rod side and the + potential of the grid side and where it is all located - basically simultaneously at every point of the grid at the same time (extension of the dipole or cap 38)...and all over the HV rod at the same time..you will see that they are of course repelling each other.

If the grid wasn't a grid and was just a point, it couldn't "squeeze" down all around the rod to give a biased pre-compression before it is even triggered and recompressed against the diode. The cap 38 point would just repel the potential at HV rod at that one point and wouldn't do a good job at repelling it all over giving it a pre-compressed nature.

Also, the description of the energy leaving the discharge and moving to the grid is of course the original explanation that just about everyone has been introduced to for a long time and the inductive collapse of the load to cap 38 is already what the patent says the cap 38 is there for.

Besides this, if something leaves the rods and goes to grids to power load, that applied power to the load will charge cap 38 anyway...load shuts off and cap 38 gets a second pulse. In either case, cap 38 will be charged up and I don't believe at these frequencies this machine was supposed to run at will simply give up everything to a battery..I believe it won't simply be toppep up either because it will explode with what it is getting so it has to release what it has in a big way....colliding against the front side potential as I described to power the load.

The load can be powered by either cap in a collision manner with a HV into a LV for the basic effect or HV into HV for enhanced effect.

Also, even if there is not simply a "spark" jumping from rods to grid to power a load, which it won't, this in absolutely no way excludes the power supply of the ignition coil from jumping from HV rod to grids to chage the cap 38 without charging the load. Does anyone believe that if the front side cap is charged and the ignition coil is pulsing at the HV rod that the ignition coil sees a dead end when LV switch is open? It doesn't see a dead end it sees a path to ground through the grid and cap 38 will receive a charge from this.

When the load collapses, of course it will move to cap 38 whether 38 charges the load or just receives the kickback because it is disconnected from the rods, it is like Beshires says is the only place to go. Diodes and gaps can serve the same purpose.

That is the same thing as the resonant charging choke after the ignition coil...the choke collapses and it has nowhere to go but to the cap..2 pulses for the price of 1...quicker charging.

In either case, the simplified spark circuit that I have showed and several variations of it does exactly what the tube can do - it does the desired effect.

One thing to consider is that because a patent says something means nothing. This doesn't mean that I think the patent is lying but it doesn't mean that I think it is telling the truth either. I think the answer was already given in the publicity articles from way back. And I think what is obvious is obvious.

With the diagram Beshires is working on replicating, I don't believe the extra power is simply from the timing of discharges of caps into 2 coils at the same time and they repel. You can take the same power input into 2 coils isolated (not in same circuit without common ground) and you will find that it has a certain repulsion or attraction.

Now do it like the diagram where the two HV potentials are colliding into each other and forced to the common ground...it is stronger and faster therefore, the strength of the repulsion is not from the timing of the two caps into two coils...it is from the collision effect that causes them to discharge faster and that is where the extra strength comes from.

In all cases, it still comes down to an inductor in series with a cap that is forced to discharge faster because of the collision effect. In my opinion. And, the green impulse keeps showing up.

i tried out my vacuum pump on the grey tube yesterday....and at one point the spark gap was making this strange popping sound...which was odd.......hadn't seen that before....if i left the pump on for a while then the sparks just stop. So you only need it on for a very short time...

Photo Flash Circuit

@lamare:

Here's the circuit diagram for the photo flash unit. Notice the similarity between this and the Water Sparkplug circuit.

Thanks for posting your results.

Electrotek,
Got loaded question for you, Based on your experience. Do you know what the inductance of 110V coils sequential or parallel is? (I do believe that what Gray used in his motor.)

Based on my experience as a professional electrician, I don't use series or parallel inductances. This is something from electronics.

Mark Mckay recently posted a statement by a magnetics expert who said that coils in oppostiton have minimal inductance.

I wanted to calculate approximate resonant frequency of grid, coils and cap used in Gray's motor.