Great work R12003, do you have all 3 coils working on that last video? And if so ,are they all wired with the start of each coil together and ends together? Just curios.
@ minoly, I have never done anything but put water in it. It has been sitting on the shelf in the closet for 5 or 6 months, I put about a cup of water in it about 5 minutes before I took the picture. Good luck at the shop


Brian

Bedini GT3

Brent,
I'm talking about making a solid state relay for the switching.
The Fet would get around the problems with the SCR.Mathew Jones shows the circuit a few pages back, but that solid state relay is costly so we could make that with the opto and the regulator for the gate voltage and the resistor to pull the gate off. The way around his circuit for timing is a SIDAC at 40 to 60 volts to fire the opto when the capacitor reaches the correct voltage. that is the switch I'm working on. NTE makes that part NTE6415. The higher the voltage the better, then the battery will charge fast that is what we want. Capacitor dump circuits must be double in voltage or very close to it.

John B

6 pole monopole on Iron Pyrite/Magnesium/Calsium Chloride and Bromine

Just some test results using Calsium Chloride and Bromine with Iron Pyrite/Magnesium as a battery on the little 6 pole ( and yes the paper towel too...) yes the Bromine is corrosive but as you can see can be used in a pinch to make it run and charge batteries. I did not use the 2 together. testing was with each. The bromine is a time release type I use for my hot tub. It breaks down very quick in light... but desolves very slowly... You can see the benifit of that ( keep it dark). This configuration should run for a while with only needing to add water once in awhile over time... anyhow back to work on the next expermint ( mint... maybe we can make these run on mint( Ha Ha). See videos if you want... Thanks John Bedini, Lasersaber, Lidmotor Etc...



YouTube - 6 pole monopole on iron pyrite/magnesium and calcium chloride as battery
YouTube - 6 pole monopole on iron pyrite/magnesium and BROMINE

I have been rather reserved with my posting on what is going on with my replication, but I feel that a relevant point has come up to force me out of my shell.

I assumed that all of the windings were paralleled in the literal sense of the word. After John Bedini posted(http://www.energeticforum.com/renewa...tml#post127253) that the windings were run off of different transistors but still paralleled, I hooked up my second half bedini/cole bipolar circuit that I had constructed on a prototype board.

I had my setup running off of one half bipolar circuit and it was charging my 7800 uF capacitor bank rather weakly with 19v @ 700mA (I am running off of my variac from 120VAC with a bridge rectifier and a smoothing cap). The cap dump was about every second @ 20v to a 12v battery.

When I was in the midst of switching my setup to multiple switches, I tried something different. I just used my center coil (4 wires @ 2 x 16 AWG and 2 x 23 AWG) with both of the 16 AWG paralleled to one bipolar circuit without any slave coils, and to my surprise, the LED on the cap dump circuit (using PG 43 out of FEG book) started blinking even faster. The meter and the scope showed that there was more energy transfer taking place towards the cap.

It seems that the radiant energy doesn't like being added in full parallel and that it must be taken off of multiple different switches just like JB has been telling us.

Now that I have the two slave coils running in parallel in the to one half bipolar switch and the two power wires on the main coil in parallel to one half bipolar switch, the charging is off of the scale comparatively.

I am getting to the point where I have to physically slow the rotor down to allow the cap dump circuit to work properly without going into latch mode (I think this might also be JB's problem with the circuit in FEG).

I will more than likely be adding generator coils to slow the rotor down while feeding the excess energy to the charging or primary batteries. Also, tomorrow I think I'll be making two more half bipolar circuits so that each power coil has its own switch.

So the whole idea of this post is to get more people using individual circuits for each power strand to see better charging, cooler transistors, and whatever other goodies surface.

Attached are some photos of my setup.

Hope to be of assistance,

Dave

P.S. I am not using my timing wheel as you see in the photos. I have been using a PIC16F690 Chip to trigger the hall and run pulse signal back through an optocoupler. I have an analog voltage function that is able to control my pulse duration depending on where I set the potentiometer.

Even when I scale down to the same input as before (19v @ 700mA) when I adjust my PIC pot, better charging takes place. I'm using the two slave coils off of one switch and the two center coil power strands off of one switch, I still cannot get the SCR to unlatch for a pulsed cap dump. There is enough "electron current" to keep any capacitor pulsing from happening.

More switches means better charging. Don't hold back.

Dave

I woke up and couldn't sleep wondering about some of this. My thoughts have been about PN junctions especially in LED's relating to radiant. Some of my testing has been interesting and I'll post more on that elsewhere. but I was following the SSR cap pulser circuits and John's efforts in this part of the circuit. I found this SSR
KD20C40AX: KYOTO ELECTRIC: Electromechanical

But when I ran across this quote it answered some of the things that were troubling me about the cap pulser as a battery charger for the very reasons described here by John B. the SG always was superior in my testing. I am just wondering if anyone else has considered placing a monopole master/slave on the output of the 3GT to charge the batteries?
Or Tesla switch/solar tracker? then with Bit's swapper, this thing would run a very very long time wouldn't it?



Les

Hi Dave,

Yes, you are correct, energy differences should be considered in calculating the remaining energy in the capacitor. Thanks for pointing to my mistake.

Applying the formula for the energy differences I highlighted your math: the energy in the cap when it has got the 36V is (.5*.016*36^2)=10.4J and you somehow mixed it up with the difference, 3.7J?

So (.5*.016*42^2) - (.5*.016*36^2) = 14.1J - 10.4J = 3.7J this is the energy taken out from the capacitor and the remaining 36V in the capacitor represents 10.4J. Is this ok now?

Thanks, Gyula

Thanks, Yes and yes they are. Now I am just learning and watching how
this is all working as one.

I may have to adjust the timing a little still, and a new timing wheel.
There is a small deflection in it, causing it to roll away from the hall on
one of the magnets. I can only see or hear it when I allow the wheel
to spin very slowly.

Mark P.

Yes, does anyone know if there are gains achieved with this type or other types of multiple SSG's in series like this ? It does appear that there might
be.

FRC

Can that Joule figure be accounted for in terms of a current pulse? Meaning what is the .338J of energy equivalent to in terms of the pulse of current being delivered into the battery? The volt difference is 6.5volts...

I suppose this is why its good to keep the discharge path at as low of a resistance as possible, preferably sub-1ohm to make the actual cohered current pulse larger than it would otherwise be with a higher resistance discharge path? 6.5volts pulsed over .1ohms "should" deliver more current than the same 6.5volts pulsed over 10ohms, right?

Of course the battery looks like a high impedance load to current impulses.

Trying to make sense of it still...

Gene

Thanks for catching my mistake. I think that I calculated that more than once and still posted flawed math.

I think we're okay now with the energy dumps into the batteries.

Dave

Bedini GT3

I guess I should direct this at all of you calculating Joules, you must take into account the instionious peak amps it's what the meters do not catch. When you hit the battery with that the Ions are forced to move, the battery will boil very quick (Cold Boil). I have seen the peak amps reach 600 amps. The battery when discharged still has a very low impedance as the charge rises the impedance lowers to around .00023 Ohms, this is just a ballpark figure (Battery Bible). So re-calculate with the correct impedance. Kickoffs law explains the rest where everything is in the charging system.

With a sulphated battery the impedance is extremely high and no power is developed in the system just potential. ( SCR will not work here, it will lock on). The battery under this condition takes a long time to become useable as the sulphation dissolves from the plates. This takes constant use of charging and discharging. Pulse Charging even at a low rate allows the chemical in the battery to absorb the charge, it does this with time and a rest period in-between pulses, "Time Charge". Again I will say that the machine must be tuned to produce double the battery voltage or very close to it, do this with the duty cycle. Some of you have big magnets on the machine timing wheel. My wheel is 16 feet high and has 1 inch magnets, the smaller machines only needs 3/8 magnets this allows the correct space for the circuit to shut off correctly.

Gel cell batteries have a much higher impedance built into them if you boil these they just dry out and become useless ( old ones). But don't believe me read the Battery Bible it will explain what is going on. People have posted that under SG groups. Most chargers are only 3 volts over the battery, but then look at what the transformer in the charger must put out at 10 or 15 amperes to do this. It's all about impedance and voltage.
Hope This Helps.
John B

Thanks John B. That makes sense then that the instantaneous amps at "switch on" of the discharge pulse wouldn't register on the meter just cuz the meters are to slow.

Does the instantaneous amps still figure into the resistance on the discharge path to the charging battery? What I mean is, does the discharge path to the battery need to be like .001 ohms or lower so that this instantaneous amp figure can be as big as possible?

Whats the typical resistance inside a biased "ON" BJT MJL21194? I suppose as with diodes, you can just parallel more transistors, presuming they beta match, to bring down the overall resistance in the discharge path. (can you do the same thing with an SCR? )

Thanks again man,
Gene

Hi Gene,

The Joule figure means Wattsecond, so 1J energy means 1Watt power under 1 second, OR ANY combination of two numbers that give 1J when multiplied together. So taking out 1J energy from a capacitor (that stores 1J) under 0.1 second means that you can take out 10W (10W*0.1s=1Ws=1J).
And you can take out this with a switch that is controlled with a given duty cycle, what count is how long one ON time of the switch lasts and how many ON times you let occur within the given total time.
Of course, the amplitude of the current you take out with the controlled switch depends on the total impedance the closed circuit lets develop, including the summed DC resistances of the switch and the capacitor's series resistance and any AC impedance also in series like the combined DC - AC impedance part of the battery, wires etc.

So your first question below is answered partly above and partly by John B in the meantime. I cannot add much to it.

Your second question below is answered by you: it is correct the 6.5V is able to drive higher current through 0.1 Ohm than through 10 Ohm (not neccessarily in a linear fashion because it depends also on the 6.5V source inner impedance or any other series nonlinearity).

Your recent question: "Whats the typical resistance inside a biased "ON" BJT MJL21194?" depends on the transistor's saturation resistance which comes from the instantaneous saturation voltage (across collector-emitter) devided by the instantaneous collector current. Study Figure 10 in Page 4 for the Vce(sat) voltage how it changes in the function of the collector current (under condition of Ic/Ib=10) and make the divisions. It is non-linear, so one more reason to select transistors for Beta (hFE) when paralleling them.
Here is the data sheet I refer to: http://www.datasheetcatalog.org/data...a/MJL21193.pdf

rgds, Gyula

Ok Dave, finally Vissie got the answer this is what counts.

Gyula