OverUnity Lead Acid Battery Switching Circuit - Self Battery Charging

[BediniBattery]

FREE ENERGY TUTORIAL - WRITTEN BY Snail_007500 from universallyaware.ning.com (5th March 2012)


OverUnity Lead Acid Battery Circuit - Achieves Infinite COP & Self Battery Recharging


FREE ENERGY FROM THE VACCUM - DON'T KILL THE SOURCE
CLOSED LOOP CIRCUITS PREVENT OVERUNITY
YOU KILL THE SOURCE IF YOU KEEP THE CIRCUIT PERMANENTLY CLOSED
KEEPING A LOAD CONTINUOUSLY CONNECTED TO A BATTERY WILL KILL THE SOURCE
A BATTERY CANNOT RECHARGE ITSELF IF THE CIRCUIT IS KEPT CLOSED FOR LONG PERIODS
A BATTERY WILL ALWAYS RECHARGE ITSELF IF GIVEN THE OPPORTUNITY TO DO SO
THERE IS NO NEED TO RECHARGE A BATTERY IF YOU USE IT CORRECTLY
OVERUNITY IS INCREDIBLY EASY IF YOU ALLOW THE BATTERY TO RECHARGE ITSELF


The Purpose of the Switching Circuit
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01.) To allow energy from the vaccum to enter the circuit & power the load.
02.) To achieve a very high degree of overunity by opening & closing the circuit continuously.
03.) To encourage self battery recharging by carefully matching the load to the batteries amp capacity.
04.) To identify when the best time to charge the battery is & how it should be achieved.
05.) To switch the battery in & out of the circuit in a controlled way & at a specific frequency. (Less Than 15 Hz)
06.) To prevent the battery from being permanently connected to the load.
07.) To prevent the source dipole from being killed.
08.) To maximise the efficiency of all overunity motors & circuits.
09.) To create a super battery which lasts 10 times longer & doesn't discharge itself.
10.) To provide a better way to power circuits when using batteries.

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Overunity can only be achieved if you carefully match the battery capacity to the load it will power

If you attempt to draw excessive amounts of current from a battery, you can forget about overunity.

If you place too big a load on a battery, you will begin to kill to source.

No amount of feedback pulses from a motor / generator will change the situation.

If you place too large a load on the battery, you will be preventing the battery from recharging itself.

It is better to draw a small current for a long time & allow the battery to recharge itself when it is taken off the load.

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I encourage everyone to do your own experiments, to determine what loads can be powered by a specific battery capacity.

The only way to know how fast a particular battery can recharge itself is to put it under load, vary the switching frequencies, on / off times, & then plot the results.
If you start at 20% of the Batteries Amp Capacity for these experiments - you can either increase or decrease the load.

The bigger the load, the greater the chance of the battery discharging.
Ideally you will need to do several long term tests to determine where the peak of overunity occurs & when it starts to drop.

The rated capacity of a battery is only for a closed circuit. If you are using a circuit which allows energy from the vaccum to power your circuit,
you are likely achieve excessive amounts of overunity. The amount of overunity you achieve depends on the load you will be powering.

In general if you draw less than 20% as an average, you should have a lot of success with self battery recharging.
When you get down to 10% you may be able to achieve infinite COP.


Charging Your Batteries With a Large 100 Amp / Hour Battery
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When you charge a battery it must be done using a pulse charger, similar to a bedini circuit.

Charging should be done after the battery has been allowed to self charge itself.

You should only need to give the battery a top up, not a lengthy charge.

You don't need to build a bedini motor to do this.

You can make one of these pulse chargers using a 555 astable circuit with an adjustable pulse width, a (n type) mosfet & an iron dust or ferrite toroid.

If using an iron dust toroid T50-2, the frequency should be 30Khz & the number of turns = 45, using 0.6mm enammelled copper wire.

If using a ferrite toroid, the frequency should be about 5Khz & the number of turns = 8, using 1mm enammelled copper wire.

A single schottky diode can direct the back EMF spike to charge your battery, or you can use a secondary coil & a bridge rectifier.

A circuit drawing 0.5 Amps at 12 Volts will charge a battery slowly, so increasing the power used to 2 amps or more is something you should be looking at if you want a fast charger.

You should get hold of another battery to do your charging. (100 Amp Capacity is Ideal) as this will only use 2% of the capacity.

When you have got your 100 amp battery, place the switching circuit before the pulse charger & begin extracting free energy from the vaccum & charge
your smaller batteries for free. The 100 amp battery will quite happily recharge itself after 1 hour of being taken off load, because you made sure
it was being used in overunity mode & you didn't keep the circuit closed, unlike every other circuit out there.

A battery is charged when its voltage reaches 15 volts.

Its normal voltage is between 12.7 & 13.5 Volts depending on the battery.

Now that you know the secret of obtaining free energy from Lead Acid Batteries, you can tell all of your mates.

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My Original Article 13 Page Article Can Be Downloaded Here :

- http://www.mediafire.com/?qpudp49yqbsq4qd -

- My Facebook Group - https://www.facebook.com/groups/267745266621292/

The information that I am discussing here is already public knowledge, see the links below.

- http://www.cheniere.org/books/part4/s40.htm -
- http://www.cheniere.org/misc/battery%20poppers.htm -
- http://www.icehouse.net/john1/foreward.html -
- http://www.icehouse.net/john1/tesla.html -
- http://www.irf.com/product-info/datasheets/data/irf5305.pdf -

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Here is a quote from Tom Beadens Website

In this scheme, we drive an ordinary d.c. series motor by a two wire system from an ordinary battery.
The motor produces shaft horsepower, at -- say -- some 30 or 40 percent efficiency, compared to the power drained from the battery.
This much of the circuit is perfectly ordinary.

The trick here is to get the battery to recharge itself, without furnishing normal power to it, or expending work from the external circuit
in the process. To do this, recall that a charged particle in a "hooking" del-phi river moves itself.  This is true for an ion, as well as for an
electron. We need only make the del-phi in correct fashion and synchronize it;  specifically, we must not release the hose nozzles we utilize to
produce our del-phi river or waves. The inventors who have discovered this have used numberous variations, but here we show a common one.

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[ltseung888]

Thank you for your information.

I was planning to do a similar circuit in the next few weeks.  Now the task will be much easier.

God Bless.

[Mira]

How did you test this device?

[BediniBattery]

FREE ENERGY TUTORIAL - WRITTEN BY Snail_007500 from universallyaware.ning.com (5th March 2012)
OverUnity Lead Acid Battery Circuit - Achieves Infinite COP & Self Battery Recharging

This is the drive circuit for testing either a P-Type Mosfet or a Normally Open Relay.

The start button / switch is used to charge the super capacitor via a low value resistor & provide power to the 555 circuit.
The 555 needs at least 3 volts before it will begin to self oscillate. Once the 555 circuit starts to oscillate, the power switching will take over & will continue to charge
the supercap until it is fully charged. The relay placed across the low value resistor is used as a current regulator or short circuit protection circuit. Its cheap & effective.
You may also want to add a low value resistor to the output of the supercap since they can be quite dangerous if accidently shorted out.

The relay is a bit noisy, so the P-Type Mosfet really is essentially.
There is a pulse width adjustment using the two diodes in the 555 astable circuit & a variable resistor.
You can play around with the timing here.
The capacitor is approx 10 micro farads, this is what determines the basic frequency, the other two resistor set the on / off time or pulse width.

The circuit will operate up to 48 volts provided the 555 has a regulated 12 volt supply, so this could power a 48 volt mains inverter.
The N - Type mosfet part of the circuit is used to drive a big relay if you want to use one.
You can test the performance of various loads with a relay if you don't have a P-Type Mosfet at hand.

The switching part of the circuit can be constructed using a N-Type Mosfet but it makes life much harder, so just get the right parts if you are going to try this. Also I could not find a direct pinout for the P-Type mosfet IRF5305. The data sheets forgot to tell us what the pins were.

There is a missing wire on the pulse charger diagram, pin 8 on the 555 is +12 Volts, its not a mistake, I just haven't put it in.

If you intend to build these circuits, make sure that you use the exact component values that are shown.

There is a lot of oscillation with the pulse generator when you look at it on the oscilloscope. It does not affect the driving mosfet, but tends
to affect the mains powersupply. Use a 12 volt battery to power this circuit, ideally with the overunity switcher placed before it.
You can also use a secondary coil on the pulse generator to isolate the two batteries.
A 1 to 1 ratio is good & then feed it into a full wave schottky rectifier to charge the battery.
A few drops of superglue on the coil keep it from coming apart.

The iron dust toroid T50-2 works well at that frequency 33khz,  I can't recommend ferrite for this circuit.
Again use the exact component not one twice the size.

- http://powermagnetics.co.uk/pace-components/micrometals-iron-powder-cores/rf-applications/t50-2-micrometals-iron-powder-toroid -

I use schottky diodes for the flyback circuits, signal diodes for the 555 timer circuit.

The N-Type Mosfet is a HUF75337G3 - http://www.datasheetcatalog.org/datasheets/120/170920_DS.pdf -
The P-Type Mosfet is a IRF5305 - http://www.redrok.com/MOSFET_IRF5305_-55V_-31A_6mO_Vth-4.0_TO-220.pdf -

At the present time I have tested the above circuits for functionality, I still need to design & make a small PCB so I can really test it out.
If the circuit provides a good deal of overunity, it should be possible to charge very large batteries using a small one, thats the goal.

This is my facebook album with all the images-

https://www.facebook.com/media/set/?set=a.271859256223535.63319.100001983889140&type=1

[TheOne]

Thank you for the circuit


I have a question about the capacitor. What is the voltage required for the capacitor?


I have some capacitor of about 10V at 100000 UF, this is to big? can I put 2 in serie to make a 20V?


Thank you!