First Bi-Toroid Transformer Test.

The transformer works reading voltage on both sides with the central primary connected to a 120 volt A.C. wall power source. Next I plan to connect the secondaries to loads and run some comparison tests. So far so good! When I turned it on for the first time, all the stators audibly locked into place with a powerful jolt.

Morin transformer power test.

I tested the "Morin" version transformer ( Name based on Haa D's video description).

The power from the wall outlet to the two 9 watt (18) total fluorescent bulb ballast is 22 watts, 110 volts at .20 amps.

The power from the wall outlet reads 110 volts A.C. Connected to the transformer. The output voltage from the upper four coils in series reads 80 volts; So it's stepping down. Nothing special happening here. What's interesting is that the transformer is outputting .068 A.C. volts with no power connected.

The transformer reads between 12 and 5 A.C. volts if the stators are not PMH locked. After the locking takes place, it delivers 80 A.C. volts which is sufficient to light two 9 watt florescent bulbs rated for 110, but they flicker at around 1/2 hertz. The input amperage measurement taken by "Haa D" in his video has to be incorrect. He's measuring .02 amps from the wall outlet, ten times less then it should be.

These readings are important because they give me some idea of what to expect from the Bi-Toroid transformer's twin output secondaries. Frankly, the way "Haa D" has this transformer wired delivers a really terrible performance, at best around 50% efficient. We can consider that a Hoax video. Inserting stators through all the coil cores has to improve on that poor a COP.

I will begin to test this Bi-Toroid version for the "Thane Heins O.U. Effect" soon.

Overunity generated by Bi-Toroid transformer.



I pushed two stators through the bottom coil, one leg through each core hole, with two to the outside, plus an additional two stators through the top four coils so all four stator legs attached and locked. I measured 74 watts input (110 volts at .68 amps) and 90 watts output (90 volts output at 1 amp) while lighting the two 9 volt fluorescent bulbs to full brightness. That's a COP of 1.21 over unity. Very exciting results! The wiring's the same as I showed in the "Morin Transformer" photographs in the comment above; The four top coils are shorted in series between the center electrodes and the outside electrodes connect to the load.

It apparently only takes 1/2 of the envisioned design to get the intended "Thane Heins Bi-Toroid O.U." results. The "Haa D Quatro Stator". I really hit the Jackpot this time around. This is not a hoax folks! Take a close look at the configuration and see if you can visualize the flux paths. It's channeling the BEMF around to the outside through the secondaries. You need four synchronous washtub pump motors to replicate this experiment. Try for older used models if possible, because the newer plastic housing coils (Like the one on the bottom) will not fit over the stators side by side like the exposed coils on the top.

Quatro stator twin.



Here's a four stator twin with the two 9 volt fluorescent bulbs in the back ground. This is a modified Bi-Toroid design based on the sucessful test results of the first four stator model.

The first test of this design was not favorable; It showed the power coil drawing .70 amps and running very hot. The single central power coil is not a viable approach for this kind of A.C. input with four secondaries. The stators are saturated and unable to draw flux away from the primary, so too much BEMF channeling back to the primary for the wraps to handle. This design defeats itself. Too congested!

It would work much bettor simply to daisy chain the "Haa D Quatro". Five in a shoe box would deliver COP 2, and run much cooler. I tried to loop the quarto and all the coils very forcefully jumped up to the stator tops with the recycled current.

Measurement errors.

I set the four stator "Haa D" transformer back up for further testing and noticed a big difference between amperage reading depending on where I measure along the output wire.

On closer examination, I've concluded my original measurements were influenced by the proximity of the measuring instrument to the transformer, and that there's really nothing special going on with it. This is a new meter and I'm just starting to get used to it.

I plan to move forward with the testing of my original concept with the six stators and the central stator air gap. I still have hopes for replicating the Thane Heins effect with this configuration.

No gain.

I'm not getting anywhere with the six stator transformer tests. The idea looked good on paper, but continued testing has shown it to not be delivering any special results.

Still waiting on the spring loaded push button switches.

Bucking coil transformer.

I am experimenting with two four set bucking coils and a ceramic magnet core central output coil. I had more success with the unipolar D.C. pulse than the A.C.

PH effect video and Induction motor video.

Two more tricks with the "Wash Tub Motors";

PMH effect by George Chaniotakis:

https://www.youtube.com/watch?v=uGv4fLyWfao

Roberts33 Electromagnetic induction motor:

https://www.youtube.com/watch?v=FHgw_l-Z_s0

1st Uxcell spring pressure switch



This switch is the central component for the GAP oscillator coil. The attraction from an overhead magnet presses the switch closed and triggers a power coil in between that releases it and disconnects the power to attract again and repeat the stroke.

DPDT momentary press spring switch



This switch has two normally closed contacts that direct the coil output to source after it's released.

Switch contacts test.

This switch works perfectly. The switch is completely non-magnetic. The power connects to the two off set pins in the center, blades facing each other. Of the four pins in a row, the two pins on the outside are "Normally Closed" when the switch is not depressed. The two pins in the center are "Normally Open".

When the button is depressed the two center pins come on and the two outer pins turn off. Naturally, the power coil will connect to the center pins and the storage capacitor to the two out side pins.

I plan to run a dowel through the 1/4 inch center hole of a 3 inch Neo disk with a power coil seated on top. The Neo tube will depress the switch in attraction from overhead. When the circuit is energized, the power coil will release the over head tube and allow the switch spring to send it up. The power coil has discharged and the natural attraction brings the magnet back toward the Neo disk only to re-trigger the power coil and so on. In the mean time, when the switch contacts separate, the two outside contacts close and send power from the power coil to the storage capacitor from the oscillating tube magnet. Voila!

This switch may need to interface with one or two 12 volt relays. I just got it and need to do more testing.

What an elegant solution to the commutator problem. I know I'm going to fall in love with this setup. It took a long time to develop this simple a device. We may go over unity with this one. There's a lot of magnetic force sandwiching the pulse coil. The real power is generated by the displacement of the backing magnet field in the pulse coil. I'll try and upload a video of the working oscillator soon.

The Uxcell switch seated in the pump housing and the eight components:

The central component is the washtub pump housing that seats the Uxcell press spring switch perfectly with a conduit for the wires:



The eight components:

Through conduit and inverted view of Uxcel switch contacts

Completed setup.

A powerful 3-1/2 inch "Neo Disk" magnet is positioned over a PVC spacer. The pulse coil is resting over the "Neo Disk". The dowel can be seen protruding from the grommet in the center of the coil. This dowel runs through a 1/4 inch hole in the "Neo Disk" and presses on the Uxcel DPDT spring pressure switch:



Here's the completed setup with the trigger ceramics on top depressing the spring pressure switch dowel, ready to turn on and begin oscillating:

4 pin 12 volt 30 amp relay and schematic.




The power source to the switch is separate from the power source to the pulse coil. The center pins of the DPDT switch connect to the two center pins of the relay. The pulse power connects in series to the coil through the relay terminals to the side. A second identical relay connects directly to the destination source from the outside pins of the DPDT press button switch. These relays cost only a few dollars apiece here in Costa Rica. 30 amps can generate a tremendous amount of magnetic force in a pulse coil!

Steam punk logic will tell you the pulse will never match the return power; We need to apply the "Space Quanta Theory" to understand where the over unity sources from! We're looking at a nuclear reactor here not just a mechanical device.