Yep another experiment
Probably some are thinking that i am too much diversified, but i do not think so.
All this back and forth testing , in very different research arena, are forcing me to adapt my mind and tey are progressively widening my
education.
I think that in these very unsecured time we all need to be ready to open our mind and try new solutions good or not.
That's why i test all systems that i find (at my very poor scientific level ) doable, and see what happen. So i am not an expert at all, but an experimenter.
So for this experiment, i used the well known 555 timer with a variable Duty and frequency possibility.
So i can test a lot of different coils , without or with ferrite core , air or steel core , different windings config to see if we can really get some power from the "kick back return " of the coil., and if this can be multiplied up to be usefull.
And especially if we can , by precise tuning, build up more and more energy from this forgotten flashback energy, and this by applying progressively the right " tuning incantation " i mean, to tune rightly the system .
Good evening ladies and gentlemen. This is Whoopi speaking. I apologize for making yet another diversion in my research, but I truly believe that all of these experiments I am doing right now are probably leading toward something unique. That is why I test every proposition people send to me. I test everything carefully.
If we go back to the Eupopolitics experiment on cold electricity using a single coil, this is the circuit being used. We have the coil here, the diodes, the lamp, a power supply, a MOSFET, and a timer. The timer is a 555 timer with two potentiometers: one controls the duty cycle and the other controls the frequency. Below that is a capacitor, allowing the frequency range to be varied. From pin 3, the output of the timer goes through a 470-ohm resistor to the gate of the IRFP460 MOSFET. Down here there is also a 47K resistor to ensure proper shutdown of the MOSFET.
Tonight I am using only one MOSFET instead of the six used by Eupopolitics, but it is more than enough for the tests I want to perform. The timer itself is powered by a separate 9V battery, isolated from the main power section. The power section uses 36 volts feeding the coil through an ultra-fast UF diode. We also have the oscilloscope probe connected here, along with a 230-volt 11-watt CFL lamp.
Here you can already see the 555 timer setup with several small capacitors used to test different frequency ranges. One control adjusts the duty cycle, while the other changes the frequency depending on the capacitor selected. There is the MOSFET with a small resistor and a small diode placed between the drain and source. For tonight’s experiment, the coil is the primary transformer from a microwave oven.
The two UF diodes go to the lamps. For tonight, I am using two lamps for comparison. The black lamp is connected to the experimental circuit, while the white lamp is connected directly to the electrical grid. This allows us to make a simple comparison between the two. The 9V battery activates the timer, and this 36V power supply powers the coil.
Just for information, I tested several different coils today. This one is the primary winding of the same transformer used here, but separated as a standalone coil, and it worked very well. Another coil I tested was this one, a 3.7-ohm coil taken from an electric hammer, which also worked perfectly. Finally, I tested half of a TV yoke from an older experiment, and that worked very well too. So the coil itself is not really a major issue. You have to test everything. You can experiment with many different configurations.
Now let us see if it works. First, I check that both potentiometers are set to zero. Then I apply the 36 volts. I will begin slowly. You will see the LC effect appear. As I slowly increase the setting, you can see the LED indicator here showing that the system is operating. I increase the duty cycle gradually. The current rises, and we are now at full output, around 60% duty cycle. At this point the lamp still shows nothing. But now I increase the frequency and we will see what happens.
Ah, now you can see it glowing orange. It suddenly comes on stronger and then reaches full brightness. And what do we have now? Around 100 to 300 milliamps. Now what happens if I connect the neighboring lamp directly to the electrical grid? You can see that this one appears whiter, while the experimental lamp has a more orange tone. The grid-powered lamp turns on instantly, while the experimental one sometimes needs a moment before reaching full brightness, and even now it is not completely at full power. Very interesting.
Now we will look at what happens on the oscilloscope. I shut everything down and return both potentiometers to zero. Then I move the camera so we can observe the scope more closely.
Now I repeat the process. I increase the duty cycle slowly - more and more - until we are again at around 60% duty cycle. Then I increase the frequency. It is difficult to see clearly, but the lamp is lit. Now we can lower things a little, but I want to show you something important. We have about 100 volts here. Now I increase the duty cycle further. I hope the lamp will not explode. Slowly, slowly, slowly...
Oh, the lamp becomes incredibly bright. And now - look - it suddenly jumps again, as if we have 100, 200, maybe even 250 volts steady. Very interesting indeed.
Now we bring everything back down and shut the system off completely. Ah yes... this Eupopolitics coil setup can be very interesting. What do you think? Perhaps there is still much more left to test.
Thank you very much for watching, and good night to everyone.
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