Hi Aaron,
Here is a schematic of My version of the Pat#6,545,444
the Capacitor discharger circuit is well described in the Complete Intermediate Handbook (SG) but I think there some thing more to it..like the Back pop to front battery needs a switch that is in 180 degree phase shift to the Capacitor discharger switch. Secondly the Capacitor Charging is done in the generator mode and the Pat#6545444 does not disclose the diode there..what say??

Rgds,
Faraday88.

Hi Aaron,
I understood what you thought about my previous question to you...no that's not what i meant..yes what you have posted here is perfect in its sense. what i really meant is the
1984 machine (Single battery) uses a Torque motor, while the 2000 SG motor is a speed motor, in the 1984 machine the commutator is the only switching involved(apparently at least), while in the 2000 SG there are two modes of switching present 1) The Transistor that Magnetoelectrically generates the Spike 2) The Capacitor dump circuit with the Inverted potential switch. In your earlier schematic if you include the external genny coil and make it a part of the Magnetic circuit of the SSG would that not make it JB's pat #6,545,444 ? but having done so things change, now you would charge a back battery with the recovery coil (genny) and dump the Capacitor charged by the spike into the front battery using the Inverted potential switch.
Rgds,
Faraday88.

Hi All,

This information below is extracted from this link that I posted earlier; http://energyscienceforum.com/files/..._Bedini_SG.pdf
I am getting people to think about how or what charges the primary battery, "the initial attraction pulse"... John does indeed specify this in the quotes I summarized below.

Dave Wing




John Bedini early forum post excerpts from 2004 to 2008.

The first thing that appears is a radiant reactive pulse leading the switched on signal from the transistor switch (no damped waves) at witch time the radiant component and reactive component go away, the current destroys the radiant, go read Tesla again, it was stated very clear that the power house switch operators were killed by the radiant reactive pulse before the current enters the system.

Their is a lot more going on in the front end of the motor or oscillators then can be measured, there is power returning to the primary section so the meter is in error.

...then I took an open loop Cole motor, gave it a spin with my hand and it charged its capacitor and continued to run itself, you can’t do this unless you are able to turn this law on and off.

This statement is correct: mnlakes1 wrote: As the magnet approaches the core a negative sine voltage is created at the base, when at TDC, the sine is at zero crossover, as the magnet leaves the core a positive sine voltage is created at the base, therefore at 23 degrees into this positive sine is when the base triggers the emittercollector to turn on.

The abrupt discharge stress the surrounding magnetic fields, which becomes non-liner causing an imbalance between the two energies, one normal EM the other Scalar, it’s just a differential equation.

Here is what I see when the magnet approaches the coil with iron in it. As the magnet is sucked in the pulse is in the downward direction, when the magnet leaves the coil it reverses the direction of the pulse to upward, Brett and I were watching this all day, so I would say if you catch this just right the magnet would be pushed away.
The first form of energy is what we all know as conventional, taught to us from all leading books in the field...

The current is developed by the battery inside in the charge process from the signal supplied by the spike, the second current is developed by the discharge process, these two currents are very different, not understood by main stream science.

I have told you time and time again where this machine runs. induction first, trigger second, collapse third. Where does the energy come from the SPIKE not the back EMF, back EMF is always much less then the source.

By taking the the Bloch wall where the two domains come together and pumping that we open a window for Zero Point energy, very small in this machine but workable for this group.

Hi Dave,
''The current is developed by the battery inside in the charge process from the signal supplied by the spike, the second current is developed by the discharge process, these two currents are very different, not understood by main stream science'' -John Bedini
Just to empahsis a bit more on what this means: there are two Scalar entities, one that is ''Outside-in' and the other 'Inside-out', these two Scalar entities couple between the external and Internal Magnetic Circuit between the Rotor and stator elements along the BATTERY AS THE CENTRAL NODE... most have asked(FAQ)why do we need the rotor at all if one can go the Solid state mode..??
@Aaron
I have told you time and time again where this machine runs. induction first, trigger second, collapse third. Where does the energy come from the SPIKE not the back EMF, back EMF is always much less then the source -John Bedini
This is what i mean by Magnetoelectric Triggering that is the case with SG and not the 1984 Single Battery Energiser. a Matter discussed with you in a previous post
Rgds,
Faraday88.

Dave,

You quote, "the initial attraction pulse" but you don't actually show that quote in your quote from John explaining the operation of the motor.

What is the context of what John is saying about his initial attraction pulse?

The current developed in the battery that doesn't come from the spike is not mysterious and I think it is useful to get away from the "signal" vocabulary to see it in simple terms because it isn't a signal, you could look at it that way, but to be accurate, it is a dielectric or electrostatic potential that polarizes the battery chemistry - that's it.

It is nothing more than electrostatic or more properly dielectric charging.

When you apply a dielectric field to the terminals of a battery, you're feeding compressed time into the battery, which is potential and this polarizes it. That potential potentiates internally developed current. The battery charges so when it is charged up and you apply a load, what do you get out of it? Time potential delivering work over real time.

When you electrostatically hit a dipole, it's just polarizing it so that the electrons in the battery know which way to go.

So even if you don't supply the current, anything negatively charged will be attracted to where the positive terminal is.

How do you split water without energy? There is absolutely no difference in how the spikes charge a battery.

If you apply an electrostatic potential at two plates of a water cell without supplying current - if the potential is high enough (voltage potential), it will electrostatically rip the water molecules apart. It will play tug-a-war on the dipolar water molecule. With enough voltage potential, the entire water bath become polarized and the bonding electrons will eventually rip from their covalent bonds and will be attracted to the positive terminal. That is the current that is created internally that was not supplied by the electrostatic source. The oxygen and hydrogen and freed up and this is the basic splitting of the water molecule without supplying current through the water.

There is virtually no difference in this and the battery charging process by charging a battery with a spike.

https://www.google.com/patents/US4427512

The only difference from what Tay Hee Han was doing is that John is using the transient spike from inductor or cap discharge with preferrably a fast enough cap contact to charging batt the batt gets slapped with potential without much current starting to flow (at least with caps that is the goal), but only the spike really did that for the most part - but same thing as Tay Hee Han.

I already understood what you're taking about with the triggering - your previous post discusses a generator coil as well, but I already said that the gen coil was not part of what I was trying to explain and is irrelevant, it was just the commutator and that was it - take my drawing, erase everything but the commutator and it will be easier to understand.

I really have no idea how John wired up the demo of that particular ZFM... And I am not talking about the half or full bipolar switch, but a generating circuit. But one thing I do know is that you can decrease the primary applied or supply current by sending the induced or generating current back to the applied or primary section to lessen primary amp draw, with minimal speed loss. Is he doing that? He could be.

Dave Wing

Hi Dave,

I want to address these one by one and of course they're only my opinion:

1. "The first thing that appears is a radiant reactive pulse leading the switched on signal from the transistor switch (no damped waves) at witch time the adiant component and reactive component go away, the current destroys the radiant, go read Tesla again, it was stated very clear that the power house switch operators were killed by the radiant reactive pulse before the current enters the system."

Even if there is the "radiant" flow during the switch on that happens before current can flow does not mean it is being used in the SG or any other Bedini circuit. I can get a LED flashlight from anywhere, hit the turn on switch knowing that the EMF flows before the current can catch up for a quick moment, but it doesn't mean that there is any advantage to know that it is happening when it isn't being used.

2. "Their is a lot more going on in the front end of the motor or oscillators then can be measured, there is power returning to the primary section so the meter is in error."

There is a return to the input battery, but it doesn't have anything to do with the radiant flow that starts during the switch on before current can flow. What goes back to the input battery is nothing more than the part of the transient spike that happens when the transistor turns off that isn't able to make it through the diode to the output battery. If the diode is too slow to let all that spike go to the output battery, some will kick back to the input battery. If you have a 1N4007 for example for that diode, but replace it with the UF4007, the high speed equivalent, you will see that there is virtually no more kickback going to the input battery and almost all of it goes to the output battery thereby reducing the input battery run time and reducing the output battery charge time (since it is getting more than it is used to). When I learned that, I chalked it up as John using a slower diode intentionally, but in the overall context, I don't believe John actually realized it was because the diodes he was using were too slow. I witnessed the comparison tests at Graham Gunderson's shop and this was clearly the case when we measured it all. This understanding was incorporated into Peter's presentation with the battery swapping build he showed and he even discussed the diode situation. The slow 1N4007 diode is the #1 reason for kickback going to the front battery keeping it charged up. There are many ways to show this - the simplest is that if anyone has enough windings on the coil, put the scope across the input battery, you will see little bumps above the battery voltage, that is where it comes from - put a faster diode, those bumps disappear meaning there is no longer or at minimum a lot less feedback returning to the input battery.

3. "then I took an open loop Cole motor, gave it a spin with my hand and it charged its capacitor and continued to run itself, you can’t do this unless you are able to turn this law on and off."

Yes and I've seen this, but if you overspeed any motor by force compared to its input energy, you will turn it into a generator to generate the difference.

4. "This statement is correct: mnlakes1 wrote: As the magnet approaches the core a negative sine voltage is created at the base, when at TDC, the sine is at zero crossover, as the magnet leaves the core a positive sine voltage is created at the base, therefore at 23 degrees into this positive sine is when the base triggers the emittercollector to turn on."

The degree that it fires is relevant to rotor diameter, etc... if the rotor is 10 feet in diameter, it can fire at 23 degrees - that only applies to a certain diameter rotor. Obviously, the induced voltage is negative when the magnet sweeps over the core.

5. "The abrupt discharge stress the surrounding magnetic fields, which becomes non-liner causing an imbalance between the two energies, one normal EM the other Scalar, it’s just a differential equation."

This statement about the discharge is as the coil is charging and about to switch on and not when the coil turns off. So do you mean when the coil turns off?

6. "Here is what I see when the magnet approaches the coil with iron in it. As the magnet is sucked in the pulse is in the downward direction, when the magnet leaves the coil it reverses the direction of the pulse to upward, Brett and I were watching this all day, so I would say if you catch this just right the magnet would be pushed away. The first form of energy is what we all know as conventional, taught to us from all leading books in the field..."

The magnet is attracted to the core no matter what since it is magnetic. Peter covered this thoroughly in the Beginning book I believe. That doesn't mean it is running in attraction mode - it will do that in repulsion mode before the coil is switched on - I think that is an important distinction that needs to be said. Of course the "pulse" is in the downward direction - it is very conventional electromagnetic induction where the magnet is inducing current to flow in the coil's windings. When the magnet leaves the coil, the trigger voltage flips to turn the transistor on, coil charges and of course the coil will charge with a magnetic field in the upward direction pushing the magnet away - if it is running in repulsion model.

7. "The current is developed by the battery inside in the charge process from the signal supplied by the spike, the second current is developed by the discharge process, these two currents are very different, not understood by main stream science."

This sounds like mixed language to me. The current developed by the discharge process is what I posted to Faraday - hit the battery with a dielectric potential (the spike) and it will polarize the chemistry so that the negative charged elements will know which way to go and visa versa. That is what is not understood or at least admitted by conventional science, but it is kinda of ridiculous on the conventional academic part because Townsend's Avalance is understood to be a negative resistor where the HV potential gets the electrons to avalanche so there are more electrons moving than what was supplied by the source dipole. But to say the "current is developed by the battery inside in the charge process from the signal supplied by the spike" sounds to me like the exact same non-conventionally developed current as what develops in the charge battery supplied by the spike.

8. "I have told you time and time again where this machine runs. induction first, trigger second, collapse third. Where does the energy come from the SPIKE not the back EMF, back EMF is always much less then the source."

John only started to talk about the spike not being the same as back emf way later on - like I stated earlier in the thread, I would be surprised if it was from Peter's influence.

9. "By taking the the Bloch wall where the two domains come together and pumping that we open a window for Zero Point energy, very small in this machine but workable for this group."

The Bloch Wall gets pumped with any push or pull no matter what - it can't not as far as I can tell. When the coil's field collapses, it sucks in some of that potential from the permanent magnets and that loss in the permanent magnet is restored freely to keep it in equilibrium.

The context that John shared this all in is with the repulsion mode. I've been hesitant to elaborate on his experiments with extracting the "Phi Dot" current and making transistors run cold, making the SG run longer, etc... but I'll probably share that soon.

I cleaned it up a bit more so we can get to the point...

John has a video on the small window motor shown prior, first he spins the motor by hand it charges the capacitor then he runs the machine for a long while off the capacitor. What is charging the capacitor? It is the energy "As the magnet is sucked in the pulse is in the downward direction" " negative sine voltage is created" this "is power returning to the to the primary section" this charges the primary powering capacitor or primary battery." This is the "...first form of energy is what we all know as conventional, taught to us from all leading books in the field..." How many energies does John say you can harvest from the SG? I know he says at least three are available.

The above is why John says the machine goes in and out of lense law when it generates the law applies and when it powers its self via the pulse it is out of the confines of the law and especially so when pulsed at the zero point or Bloch wall.

That is what I am talking about. I hope it is clear. This is the same induced current that powers the trigger circuit. Aaron you said that when you were using your spark plasma ignition to run a SG the rotor was able to turn something like 25 revolutions between pulses at rpm. So there is quite a bit of angular momentum stored in the rotor magnetics and this can then be easily converted to electrical current and sent straight to the primary section between power pulses. This of course is separate and distinct from the positive sine wave spike and coil collapse.

When one pulses the zero point of the magnet, you get rotation or angular momentum imparted to the rotor, by doing this you then are able to have access to the two opposite voltages being generated on each side of the zero point and you can harness either one separately or both at the same time if desired and power the motor. It should be noted that a North Pole magnet can generate a sine wave.

Dave Wing

Hi Aaron,
Very well..i'm in line with your opinion on all what you have stated...after all Scientific describtion are relative understandings!! Yes, absolutely JB using the spike for Battery is same as Other patents using the spike for splitting Water molecule..however this comparision if you ask me would be closer to the Stan meyer patent or the Xogen patent. if you remember Stan's patent saying that the H20 molecule can be fractured stricktly on Mechanical oscillation basis which differes from Faraday's electrochemical mode of causing the splitt and hence it is proportional to the Voltage for a given current.
Sure enough! i know the commutator you are refering to is classical to that 1984 Machine there is no discrepancy over that!! cool pal I interguied on these essence 1) the Magnetic Structure of the monopole 2) Trifilar Coil configuration 3) Switching mechanism. pertaining to JB's Pat 6,545,444
I'm keen to see the Front battery go over its Staring Voltage...have you personally seen JB acheive this?
Best Regards,
Faraday88.

no induced current feedback to the input

Hi Dave,

There is nothing unusual in how John wired up his ZFM circuit in this video https://www.youtube.com/watch?v=3kpD...ature=youtu.be What seems unusual is the position of the stator coil with respect to the rotor disk that has the magnets like poles facing out radially towards the coil, i.e. the magnets rotate tangentially to the coil.
And the coil is switched on or off by a half bipolar switch (John says bipolar switch but the scope waveform does not show he used a full bipolar switch but half of it: no input voltage polarity change happens across the coil, the waveform does not show such). The (half) bipolar switch was controlled by a Hall sensor and the sensor by a timing wheel, these latter two were positioned at the right hand side of the setup.

On the generating circuit you are talking about, here is my 2 cents: there is no intentional generating circuit... What is generated by the single coil is normal induction from the rotating magnets as I explained in my above post you quoted.

You are correct that "you can decrease the primary applied or supply current by sending the induced or generating current back to the applied or primary section to lessen primary amp draw, with minimum speed loss."

But this method was not applied in John's ZFM setups, at least not in the ones he publicly demonstrated. He showed 3 videos on the ZFM with 3 different circuits and none of them used any "sending the induced or generating current back to the applied or primary section to lessen the primary draw".
How do I know this? In the other two videos on his ZFM he showed the circuits and no any such "sending back" was shown by him. In this single coil ZFM he did not show schematic but he described the circuit with his words. And the input current went down from 200 mA to say 20-30 mA when he inserted the iron pipe core into the coil because the core increased the AC impedance of the coil.

So no, he was not doing what you mention as a method on decreasing input supply current, at least not in the shown 3 ZFM setups.
Here are the other two videos on his ZFM setups I mean: https://www.youtube.com/watch?v=XQzcYZk9MWA and https://www.youtube.com/watch?v=4TICXxP1jI4

My aim with my post #163 (or with this one) to you has been to clarify with a 100% certainty why the input current decreased when John inserted the core. And to clarify also that in the shown 3 ZFM setups no induced current feedback was applied back to the input side.

Gyula

Hi Gyula,

At the 2:20 mark of the video below John says: "And now we just accelerate because there can be no BEMF here and the motor speeds up... And now we are going to add the controlling factor." What is the controlling factor controlling? Could it be BEMF, because John says when you remove the iron "we just accelerate because there is no BEMF" which implies there was with the iron inserted.

John also used eight neo magnets on that particular machine with a hall triggering on three magnets... He says he only had enough magnets to trigger three times per rotation... Is that true or was he showing something or what could be done between power pulses? He also says he used 2000 turns of number 23 yet we see green and copper color magnet wire in the spool. So there appears to be at least two wires on that spool.

Below are the posts revolving around that ZFM, you can plainly see the schematic he told everyone to use below. You can see the FWBR in the image.

Like you posted here is the video link: http://youtu.be/3kpDMMcNQxc

Gyula if you have a demo of what you are saying I would like to see it.

I am still learning like everyone else and it can be hard for me to see what others are trying to say because I have my own understanding and way that I look at things and this can confuse me or I can miss what others are really saying very easily. Sorry if that is the case.


Dave Wing

Hi Dave,

Well, the controlling factor is the core: when it is in the coil the L inductance increases and input current goes down, when it is out of the coil the inductance goes down to its earlier air cored coil value and input current goes up to its value (200 mA as per the analog meter).

I suggest going through the sequencies together:

1) When he inserted the core first, he said:"the motor speeds up and holds steady", at video time 1:38. And the input current went down due to inserting the core as he showed it at 1:53.

2) Then he removes the core at around 2:06 and says (and shows) the current went back up and the wave came back to the normal wave.

3) Now we arrived at the 2:20 time mark where he said what you quoted: "now we just accelerate because there can be no back emf here so now we are going to add the controlling factor and basically start to run the motor for free" this latter is at 2:30
THIS IS what I hear in this part of the video at 2:20 mark but you included to this part some text John did not say here: 'the motor speeds up'.
No problem for me, just he did not say it here at this 2:20 time mark, he said earlier when he inserted the core.
I do not agree with John here: he still had input current when the core was inserted, whatever low value current it was (some mA). Unfortunately he did not load the rotor shaft mechanically to show how the input current would have changed then.

Now let's turn to the back emf. See my picture from the video at my #163 post here http://www.energyscienceforum.com/sh...ll=1#post25982
I indicated the induced back emf between points A and B and drew a yellow line across the peak value of the induced voltage (the back emf) in the scope shot.

John mentioned this induced waveform in his forum post to John K: "the voltage across the coil is about 3.2 volts, not much", see it in your second image.jpg

This shows John was aware of the back emf but I think he ignored it because it was much smaller than the input voltage (the battery voltage) switched across the coil. Still he called this setup a no back emf one. I would call it a low back emf setup.

Regarding the coil: indeed there must have been two coils on the spool but probably he used either one of the coils or he connected them in series and used both. In his forum post to Mark (your first image.jpg on the left) he wrote it was a standard mono-pole coil on a solder roll.

Regarding the switching circuit: yes the schematic shows the full bipolar circuit with 4 power transistors (pnp-npn pairs) and with 2 input pnp transistors to receive the control pulses from a reed switch or from a Hall sensor. If you check the video at the very beginning for instance 00:04 you can see only two heat sinks with one-one power transistor on them, this means he used only half part of the schematic i.e. one pair pnp-npn and one input pnp transistor (this latter can also be seen in a 'dead bug' position). Yes the diode bridge is shown in the schematic but I am sure he did not use it in this setup.

You asked on the trigger magnets etc and on this: "what could be done between power pulses?" Well, I do not think John in this setup did anything between the power pulses, the waveforms do not show any such shape.

No I do not have a demo on this circuit, sorry. When Naudin showed the coil tests on his Mini Romag replication pages years ago (link was in my reply #163) I also tested such coil-magnet positions and checked the waveforms with a scope so this part was clear for me. This was just my problem with John's no back emf claim on this single coil ZFM setup, why he said the no back emf feature when back emf was induced in the single coil whenever the magnets passed by the coil? He wrote the 3.2 Volt back emf on the forum as you kindly showed his post.
If you have questions or disagree I will try to answer.

Gyula

Uf4007 diode

Hi Aaron,
Just for discussion sake :''There is a return to the input battery, but it doesn't have anything to do with the radiant flow that starts during the switch on before current can flow. What goes back to the input battery is nothing more than the part of the transient spike that happens when the transistor turns off that isn't able to make it through the diode to the output battery. If the diode is too slow to let all that spike go to the output battery, some will kick back to the input battery. If you have a 1N4007 for example for that diode, but replace it with the UF4007, the high speed equivalent, you will see that there is virtually no more kickback going to the input battery and almost all of it goes to the output battery thereby reducing the input battery run time and reducing the output battery charge time (since it is getting more than it is used to). When I learned that, I chalked it up as John using a slower diode intentionally, but in the overall context, I don't believe John actually realized it was because the diodes he was using were too slow. I witnessed the comparison tests at Graham Gunderson's shop and this was clearly the case when we measured it all. This understanding was incorporated into Peter's presentation with the battery swapping build he showed and he even discussed the diode situation. The slow 1N4007 diode is the #1 reason for kickback going to the front battery keeping it charged up. There are many ways to show this - the simplest is that if anyone has enough windings on the coil, put the scope across the input battery, you will see little bumps above the battery voltage, that is where it comes from - put a faster diode, those bumps disappear meaning there is no longer or at minimum a lot less feedback returning to the input battery''

In your own explanation i remember in one of your post, stated that the Battery has the Inductor as the extension of the dipole arm,(say along the positive terminal) and this makes absolute sense to the context of evoking the Spike along the length of the dipole arm that includes the Inductor. the Spike evoked does phenomenal change in the way the Battery chemistry responds. In my persuit to understand the difference in the 'type' of the Energies that does the charging process in the bedini technology way back in 2005-2008 time frame i did extensive studyof Peter Lindemann's explanation for the production of Radiant Energy that included the Fractionation methods which can be either Inductive or Capacitive method.
Of late, i realized that we are primarly dealing with the Inductive Fractionation as far as the Bedini process is concerned. the Capacitor dump circuit is indirectly involved. this gets us back to the effect of the Spike on the primary (front ) battery.however,i'm still studying on the swapability of the Batteries (front to back) as far as the Pat# 6,545,444 is concerned. I wonder how a faster switching Diode(UF4007) can clamp the effect of the spike from the battery it is evoked from?? on the contrary, i feel the effect on the battery gets bettered!!while the same counter effect in the Receive Battery like wise gets bettered..
Rgds,
Faraday88.

"It is fair to say that the amplitude of the induced voltage by the rotor magnets is small compared to the input 12.5V battery voltage: about 2 V peak without the inserted core and about 4.5 V peak with the core. For me this means this single stator coil setup in this video must be a motor with low Lenz effect (especially without the core) and has a certain value induced emf (i.e. back or counter emf, who prefers what term) in it."

You're absolutely right about this.

This is very similar to Paul Babcock's motor. The magnets on the rotor have the same basic relationship with the coil where it rides over the sides of the coils instead of interacting at the ends.

When John Bedini and I were talking about Paul's motor once, he said the ZFM had some of the same principles. However, I believe John thought the ZFM might be Lenzless - at least it has the potential to be, but for sure has reduced Lenz Law.

On Paul's motor, when it's running, the coils are switched on and the magnetic field from the coil is large enough to interact with the permanent magnets to push or pull them. The permanent magnets however are strong, but not strong enough to have a significant field that cuts the windings to induce anything into the coils. It has a small insignificant amount - yes, it has a tiny bit, but most of Lenz's law is negated so the power coils have a large advantage and an advantage of recovery as well. The ratio if way offset so instead of having an equal or close to equal relationship between the forward emf and back emf, you might have 9 parts forward and 1 parts back - that's the concept anyway, not a mathematical analysis and it is possible to to have 10 parts forward and 0 back emf.

In the ZFM, the same principle is being exploited but if you really want to get Lenz's law out of it, you simply increase the gap until the coil's charge can push or pull the magnet, but the magnet field is not strong enough to cut the windings. If you get that relationship correct, then you have a no back emf ZFM, but nobody has done that yet. But that is the idea anyway. Can do it with the same gap and weaker magnets until weak enough that they get pushed and pulled by the coils but their field doesn't cut the windings. The possibility is there for sure - its right in front of us. Does the sacrificed torque outweight the efficiency and recovery? I don't know but obviously this all has to be tested.