Kapanadze Cousin - DALLY FREE ENERGY

[itsu]

@all,

Did some testing with the KT926A transistor using up till 150V on the collector.
It had the toroid (6 turns) in series with a 1 Ohm csr and a scs106 Flyback diode installed.

It shows that up to 60V on the collector the base signal coming from the nano-pulser at max. width (765nS) is able to fully close the transistor.

So if i again modify my nano-pulser and use the 100KOhm pot (instead of the 10K now) perhaps i can increase the pulse width even more to fully saturate the transistor at even higher collector voltage.

Also a nice steady signal across the csr is there in contrary with the same signal when using the MOSFET.
It looks to me that at about 40V on the collector and 450mA Ic the toroid hits saturation.

Video here: http://www.youtube.com/watch?v=m837lYQKo7w&feature=youtu.be

By the way, see DSRD circuit experiments also here:
http://www.overunityresearch.com/index.php?topic=1556.msg26278;topicseen#msg26278

Regards Itsu

[T-1000]

@all,

Did some testing with the KT926A transistor using up till 150V on the collector.
It had the toroid (6 turns) in series with a 1 Ohm csr and a scs106 Flyback diode installed.

Hi itsu,

I think it is time to put all circuit together then see how it works with fully assembled 2 generators mixing on coil.
Also Dally did not had perfect nanosecond pulse I believe and he did not use MOSFET too.

Cheers!

[verpies]

@Itsu,

Is this the schematic diagram of your magnetic saturation measurement setup?
(BJT is exchangeable with a MOSFET in this circuit)

[itsu]

@Itsu,

Is this the schematic diagram of your magnetic saturation measurement setup?
(BJT is exchangeable with a MOSFET in this circuit)

Almost; the probe tip /ground is reversed, so the probe tip is at the junction csr / filter cap, and the ground on the junction flyback diode / csr, see at 13:59 in the video.

Regards itsu

[verpies]

@Itsu

It looks like you have observed saturation,  see the attached scopeshots.
The slope of the green line represents your unsaturated inductance and the slope of the yellow line represents your saturated inductance.  The blue dot placed at the knee of the current trace represents what is known as the "saturation point".

The slope of the green line should evaluate to 173μH (your 6-turn inductance) and the slope of the yellow line should evaluate to 30nH (as if the 6t winding was wound over the air, which has μ_r = 1 ). 
Unfortunately I cannot verify these slopes, because I can't see your scope's vertical & horizontal scales.

It is also entirely possible that these traces are curving up because of switching characteristics of the BJT, instead of the magnetic saturation effect. 
You can disprove this terrifying hypothesis by temporarily shorting out the winding/inductor.  When you do this, the current pulse should become rectangular, if the BJT is switching quickly enough.