Sucahyo

If you take the original Bedini SSG circuit using the 3055 transistors with an input of 24 volts and output going to a battery operating normally and you disconect the charging battery your transistors will blow almost instantly if there is no load. I have blown tons of them by disconecting my charging battery instead of my primary, sometimes 8 at a time!

Sucahyo

If you take the original Bedini SSG circuit using the 3055 transistors with an input of 24 volts and output going to a battery operating normally and you disconect the charging battery your transistors will blow almost instantly if there is no load. I have blown tons of them by disconecting my charging battery instead of my primary, sometimes 8 at a time!

Try using higher voltage transistors....keep the supply voltage low roughly 12ish or so...then you should be able to switch between load types without blowing your transistors......I can.....what I have found that works and works really really well is when you modify the trigger circuit, contrary to popular belief the trigger circuit has an extremely large influence on the "quality" of the kickback produced by the power strand....I'm not ready to disclose how I modified my trigger circuit, but I do recommend that anyone with a tad bit of interest in this circuit try modifying this part of the circuit....tip....modify in this case means adding something that wasn't there before....it could be as simple as adding a single diode in the proper place....

You can try inserting a diode between the collector and emitter of each transistor. Look at Bedini's patent: google patents 11592633 fig 2 & 5.
He says that the diodes protect the transistor by routing any high negative voltage transients to ground
I found that on my 9 filar coil when the battery became disconnected that it blew only one of that diodes and it effectively short the circuit so no further damage happend.
You could also connect TVS diodes (1.5KE18A) over the collector emitter. They are normally used to protect mosfets.
They are SUPER FAST devices, working in the sub-nanosecond (pico) range!

Then you're learning well as a result of your own
curiosity and experimentation!

The lead acid battery is an amazing device which
is capable of a very long life if treated with care.

Sulfation of the plates is a normal consequence of
battery discharge. When the battery is re-charged
most of the sulfation is restored to active plate
material however a small remnant of the sulfate
may remain in "pockets" of the plates.

To overcome this residual sulfation it was customary
to perform an "equalizing charge" periodically. This is
an Overvoltage Charge Cycle which will revert the
sulfation which is still fresh (amorphous) back into active
plate material and the "gassing" which occurs will "stir"
the electrolyte well in order to prevent "stratification."

In time this initially amorphous sulfate will change to
its stable crystalline form which cannot be "desulfated"
by normal charging voltages or even an equalizing
charge. As a result the battery will gradually lose its
capacity due to the increasing of the pockets of sulfation
which assume crystalline form.

The Desulfator Circuit applies to the battery being treated
very short (nanoSecond) pulses of very intense current at
a voltage which can rise to over 50 Volts on a 12 Volt battery.
This "radiant spike" of energy is capable of "desulfating" even
the crystallized stable form of sulfate and rejuvenating the
plates of the battery.

The individual spikes have a very high instantaneous power but
the average power is very low. Consequently, the battery
being treated will (should) not get hot to the touch.

Most desulfators operate at a relatively low frequency of from
1 to 5 KHz. At that range of frequencies the pulses are very
effective at desulfating and rejuvenating but will not have
sufficient power to "recharge" the battery.

Therefore, you will want to charge your battery in the "normal"
way and use the desulfator, either continuously or intermittently,
to keep the battery free of sulfation. The amount of power
needed for desulfation is low; generally less than 5 watts at the
very most. About 1 Watt is typical for even a large lead acid
battery.

The Inductor is the "workhorse" of the desulfator. It must have
a very low DC resistance (less than 0.2 Ohms - smaller is better)
and an inductance of from 100 to 500 microHenries. The inductor
can be hand made by winding heavy wire onto virtually any
magnetic core material (ferrite/powdered iron toroids, ferrite
rod, silicon steel "I" laminate bundle from an old transformer,
etc.) or it can be purchased. Any inductor with a current rating
of at least 2 Amperes will suffice.

I've attached diagrams for circuits which can be used to
"tune" the pulse width for maximum radiant spike output
from any inductor that you may desire to try.

Once the variable resistors have been "tweaked" for the
operation you desire then the values may be read with an
Ohmmeter and fixed resistors used in the final version of the
circuit. Different Inductors will require different resistance
values to get the "just right" pulse width for the best radiant
spike output with the least amount of input current.

When testing one of these circuits always have some sort of
"load" attached to the Inductor output to prevent damaging
the MosFet. A light bulb makes a good load and also will provide
a visual indication of Radiant Pulse strength. I often use a
12 Volt/ 300 mA automobile incandescent lamp.

In those cases there is a "reflected" energy building
up within the circuit which causes an abnormally high
power consumption and high power dissipation in the
amplifying/switching device.

Once the normal load is connected the energy which
would be "reflected" back into the circuit to cause
problems is now safely "dissipated" by the load.

When current increases as a consequence of losing the load; that is an anomaly which indicates that something is wrong.

Sucahyo

If you take the original Bedini SSG circuit using the 3055 transistors with an input of 24 volts and output going to a battery operating normally and you disconect the charging battery your transistors will blow almost instantly if there is no load. I have blown tons of them by disconecting my charging battery instead of my primary, sometimes 8 at a time!

what I have found that works and works really really well is when you modify the trigger circuit, contrary to popular belief the trigger circuit has an extremely large influence on the "quality" of the kickback produced by the power strand.

You still think that what I get is current increase without load and not current reduce with load huh?

Do you have proof?


I have circuit in front of me that can output 500mA to 12V battery and I can attach and detach any load at will.

This is what I done yesterday. Charging a single alkaline battery, then while the circuit still running, replace it with 12V, and then replace it with mid sized zinc carbon 1.5V. Still running well after months.

Does anyone here test their devices output with the 1 ohm resister test? (like Bedini's SSG test) What does that test prove anyway?

There is no reason to disbelieve what you are
telling us all about your circuit.

I can only relate what I've personally experienced with my own circuits and with Radio Transmitter devices.

A test to prevent over current.

Do your circuit reduce current consumption with load? And is that a radiant circuit? And you never dare to run it without load?

What is your circuit?

Because you kept talking as if you explaining radiant circuit and I really don't get it because a circuit that reduce consumption with load is very rare. You talk as if it common at first. Then explain as if you already have it but yet never give hint of limitation needed to achieve that operation, unlike people who already attain it for real.

You talk like that kind of circuit is easy to find. Can you even name who done it? I never read John Bedini or Peter Lindemann do / need that, so point someone else.

Do posting your circuit really that much of a trouble? why you post so many wrong conclusion? Do you base your conclusion on your own circuit? Then don't talk as if you know how my circuit work if you never build stingo. Why don't you just build it and then explain it from your own observation?

Where do you live anyway? I don't think you would need to skip few lunch just to buy radiant circuit components on US.

If anyone know any other circuit that always consume less with load, I would be very grateful if you can post it or even just give hint of alternate circuit existance. I don't mind seeing video of a black box or incomplete diagram.