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So we basically covered there are two ways that this machine can operate.
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One of them is just a straight diode which takes a long time to charge, but it's a charge that's dense.
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That's the radiant charge.
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The capacitive charge is more like a current charge in pulses, and so it stair steps the battery up.
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Alright, so the question comes up, how can I get more out of the machine?
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And there's one or two ways to do this.
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You know, you've got this amount in this branch, and it's being triggered by this.
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So this is the actual circuit, so this is not a slave.
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Alright, so to turn this around so that now there's another transistor and another transistor,
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Frank brought up a good question at lunch, that if you run too many transistors out there, you won't be able to drive them.
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You have no driver to drive them except for what's coming out of this circuit here, which is the trigger.
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I'm running seven devices on this machine, and that's about the maximum that you can drive with this machine and turn them on and off.
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So the question is, if you can only use seven devices, right?
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So I'm just going to do it with these three coils, because I just ran out of room.
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And all these are going to the same hot spot.
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Then you have three coils firing, which means that you no longer have this, but you start to get where you see that it's more and more and more and more and more.
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So if you have three of these running and then you got 21 magnets going around the wheel, you can see you're collecting a lot.
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About two times more, three times more.
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But you must, on each one of these circuits, and this is nothing more than what's done in amplifiers,
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you must balance these. They got to be matched.
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One can't draw more current than the other, so you have to very closely match them.
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And each one.
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Then has a base resistor.
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You want to be as close as possible on this coil.
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That's your load.
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Then you want to make sure that each base.
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Is receiving the exact same voltage.
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And I want to see point one over here and point seven over here and point 10 over here.
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If it's going to be point 10, then they're all point 10.
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And that's and I don't want to see.
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225 volts here in the spike and 255 on this one and 400 on this one.
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Then it tells me that you've done something wrong.
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You haven't measured out each one exactly.
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You just took it for granted that you could twist them wire together and just roll it on the roll.
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You can't do that.
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So we're going to build a machine, and the machine must be exact.
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If it's not exact, it's not going to operate properly.
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And you're going to get results.
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And if you go on YouTube, you can watch everybody with machines.
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And it's their opinion of the machine.
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It's not mine.
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Everybody's an expert except for the guy that made the machine.
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All right.
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So the other thing, the other question that was brought up, I want to address it right now is neo magnets.
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Why?
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Why does John not want any neo magnets?
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Why?
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Because first of all, the magnets wrong for the machine.
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Hard to adjust.
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Saturates the iron.
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Takes more power to release it and to make it go.
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And you can see this is an example of all the machines that are built out there.
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To get this coil to release, instead of the appropriate resistance on the base of 470 ohms, you're going to find 10.
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There's two things to look for 10 ohms because they can't drive the current through the coil to get rid of the neo magnet.
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Neo magnet will not leave.
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Now, when you do this, you are exceeding.
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And I want you to understand this.
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You're exceeding the SOA curve of the transistor.
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What is that?
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Right?
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Yeah, right.
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Safe operating area of the device.
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So how am I looking at the safe operating area of the device?
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Here's the current.
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See the current.
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So it's just five amps.
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Here's the voltage.
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Well, how much voltage have you guys seen?
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Coming off the machine.
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The MJL 21194 is not rated for that.
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Not rated for that.
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So what happens for a brief moment in time is the voltage is out here at 400 volts.
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How much can I have?
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One tenth of an amp.
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You must understand this first.
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That you want to keep the machine at a safe voltage.
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First of all, it is not required to have on the machine 450 volts.
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It's only required to double the battery voltage.
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And that's it.
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Now, at that safe operating level, at 24 volts, how much current can I have?
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Right.
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16 amps per device.
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Why, Frank?
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Because you found out, didn't you?
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The first time hooked up.
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Explosion.
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Vaporized.
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Also, very important, do not disconnect the machine from the load if you're operating in this mode.
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Which is the normal SG mode.
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Because there's no load.
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So this is going to go real high.
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And this is going to fall on its face down here.
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Very simple.
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If you don't know it, go look it up.
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But don't blame John, because John is not there to say, oh, did you look at the curves for this device?
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Did you look at the curves for this?
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Because I'm going to be a sticker when it comes to this.
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This is done in all audio.
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Very important that an audio amplifier cut one amp at DC.
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Why do you think that is?
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Second emitter breakdown when the speaker collapses.
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And you vaporize the transistors if you don't do that.
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So anyway, we know now two modes of operation, correct?
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We know the comparator, the capacitor charge, and discharge.
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And we know the radiant portion of it.
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However, the SG is very tricky.
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Because if you do this properly, you can force the battery to charge, not deplete the primary.
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And when I mean force the battery to charge, I mean current.
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If you take the SG and you take this and you run it to the secondary battery like this, what do you have?
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You have a generator.
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You have a real generator.
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And this is not going to drag.
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See, you just tricked the whole system.
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What's the problem here, guys?
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What did John originally want to do?
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Without depleting the front battery, right?
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Well, you can see that if you know what the diode is.
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It's plus, it's minus.
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So now we're using this as a generator.
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Now the other important thing is, is if you get any heat at this transistor, the efficiency of the transistor is going to go downward.
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And it's going to go downward like this.
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As the device gets hotter, it's less and less and less and less.
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So theoretically and in all practicality, you would want this device running at room temperature where you could touch it.
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And you're the most efficient.
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Now, who really cares about C.O.P. if the back battery got charged long before the front one depleted?
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What?
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It is working at its maximum.
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It's working exactly as I designed the machine.
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So you're not using the capacitor discharge anymore on the battery?
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No, I just said it was a generator.
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That this machine is capable of being three machines.
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The first machine is a radiant charger, which is going to take you a long time.
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And you better calculate everything out and everything must be balanced for you not to deplete the primary battery.
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You should be able to get out of the primary battery, two other batteries over there charged before this is at its 12 volt limit or 11 volt limit.
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And it'll run down to 10.5.
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Not good for it, but it will keep charging even at 10.5.
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Why? Because it uses the inductor.
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So, we understand the basic operations of the machine and what the invention is.
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The invention is motor generator.
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Now, if you think I'm kidding around, all the new Honda generators operate exactly on that principle.
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But they're using gas to turn them.
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Well, I'm not using any gas here.
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I'm using this chemical in the battery.
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The invention in the patents is exactly what?
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The motor generator.
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And in the patent, how is it depicted?
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First of all, there are some very simple words in the patent.
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Those skilled in the art.
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Great term.
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Those skilled in the art.
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Okay.
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So, right.
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You use them all the time.
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Those skilled in the art may participate in this program of trying to copy something.
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You may participate and try to copy it.
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So, therefore, when it doesn't work, when you copy it, you're not very skilled in the art.
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You made a big mistake.
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You shouldn't be making it.
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Anyway, let's get on with this.
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I want to go over this one more time.
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I don't want to see any neomagnets.
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I never said that I wanted to use neomagnets in the patent.
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I never said that at all.
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I said ferrite.
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And I said ferrite for the simple reason that I do not want to completely saturate this when the magnet's sitting on top of it.
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The major problem in the machine was also brought to my attention is the iron.
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The delay in the iron.
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How fast can it go?
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And at what frequency level before you get this?
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Lost.
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Look, guys, this is simple physics.
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A combustion engine works the same way.
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It goes to a certain point, and then it loses.
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No longer do you have any more energy.
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It's simple physics.
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You can't break the laws of physics here.
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There's no way to break that law.
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There are, but I don't know them.
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And don't care to know them.
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I only care that you understand what this machine is and how you operate with the machine.
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Because there's far too many people that buy machines at people that produce kits.
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Right?
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And they don't get the results.
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Why don't they get the results?
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They're not skilled in the art.
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They assume.
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Here's exactly the way they assume.
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First assumption.
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We need that transistor.
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Oh, we need this transistor.
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However, they're forgetting to look at the SOA chart.
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Why did John choose that transistor?
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Because I looked at that chart.
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The next assumption is, oh, this shouldn't be 470 ohms.
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I like 1.2k or 1.1k better.
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And I don't like the diode he used.
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So now I'm going to put this one here that nobody's ever heard of.
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Each one of these parts has its own curves.
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So now are we on the same page with the machine?
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Don't assume.
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Look up things.
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Don't put a post up there and say, can we use 355 feet of wire?
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Don't even bother asking me the question because I'm never going to answer it.
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I'm just going to ignore it.
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I'll answer it.
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I'll say no.
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Well, these guys, well, because they run the forum.
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We see these things all day long.
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But does anyone really understand how the machine operates?
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No.
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What you do now, you know what its three modes of operation are.
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If you want a slow, dense charge, make sure the primary system can handle what it needs to handle.
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Because this guy right here in the front, that's not efficient.
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What's efficient is what happens in the battery and what happens to the chemical.
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Now, you want an explanation about why that happens?
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Why do batteries restore themselves?
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Batteries are funny creatures.
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And for somebody to really understand a battery, go buy this book.
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And build the battery in it.
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And once you build the battery, then you will understand exactly what's going on in that battery.
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Because you'll be able to watch it through the plastic or the glass.
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So you can't see what's going on in this battery right now.
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You can only assume.
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But when a battery that's badly sulfated has very little passages for the electrolyte to go through,
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so therefore you have no capacity in the battery.
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So what I have here is I have a window.
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And I'm looking through that window.
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Right now the window is pretty clear, right?
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But what happens when the window starts to get fogged up?
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It's hard to see through the window.
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Until the window cleaner comes.
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And he takes away all this stuff.
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And now you have a view on that one and you have a view on the view.
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Pretty soon you're looking through the window again.
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So the idea is to generate a pulse that chips away at this like a little hammer.
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And when you chip this away, more electrolyte gets to the plates.
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And guess what?
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All of a sudden you're saying to yourself, I rejuvenated the battery.
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And you did.
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And as long as you keep the battery maintained, you may have service life out of the battery.
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Don't put a battery on the machine that's got shorted plates because you're never going to rejuvenate it.
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You're never going to get anything back.
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There's a little space underneath the plates.
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They're like little troughs.
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And it's a time for you.
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It tells the manufacturer how much time before that guy has to buy another battery.
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Now people have tricked it and put them on shaker tables and put water in them.
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And shook them and got the lead that's in the bottom out.
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But that doesn't say anything about the loss on the plate.
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It just says that you stop the short.
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If you don't have any red lead on the plates left, you don't have a battery.
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And you're never going to have one.
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Right, so now that we understand each other about the three modes of operation on the machine.
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So let's watch those modes here.
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Okay, first thing to do is look at the battery and pull some current out of the battery.
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You've all been taking pictures of this, basically what this is.
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And I'm going to do some recapping after I run it for you and show you because I'm going to run out of time and the next guy's going to be here.
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So this coil is wound counterclockwise.
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Alright, which makes the motor in attraction.
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So when these turn on, this is being attracted in.
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But like everybody knows in an attraction motor.
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That you only have half the pull.
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That you can utilize with a magnet.
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So you can only use half.
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So the magnet comes in, attracts in halfway and then it becomes neutral.
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And so the flywheel effect is going to carry it back around.
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And then at the next pulse, when the magnet goes by, it turns on in the field and then it attracts in and it catches the second magnet.
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So the first magnet is totally useless on the machine.
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There's 21 of them on the wheel.
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So the first thing to do is if we're going to call this our secondary battery, then we're going to take the power from the secondary battery.
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And we're going to watch what the primary battery does.
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OK, see they're saying 13.2 volts, six cells.
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OK, so OK, we'll go with it.
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One amp, one test amp.
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We're going to start it and see where it is.
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All right.
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So here we go.
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And we'll run this really quick so that you can see how it charges.
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Then how it comes back up and puts it back in.
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And then we'll take it back out again in these three modes.
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So the first little test will be the normal SG mode, radiant.
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So it's at one amp. It's pulling it down.
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It's at 12.35.
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However, storage batteries are funny.
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Sometimes they have to be loaded before the game.
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It would take us hours to do this.
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I'm going to make short little tests so you can see exactly what the curves do.
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And then you can you can actually bring them out or do the test yourself.
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Now, as you're starting to find somewhere.
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That it wants to stay.
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OK, so we'll take it to here.
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It will stop the test.
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And I'm not going to save it because it's going to be on camera.
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So it's it's there.
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OK, so this thing.
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So now we're going to go back again, go back to the same battery.
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And this time we're going to watch the charge.
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There we are. We're drawing a curve in the red.
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OK, this is this charge.
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I hope I don't have to go unplug that and plug it back in each time.
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So that's this charge.
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And the motors and attraction.
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So normally everybody says the transistors are heating by now.
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With the machines that they're building, right?
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Well, I can guarantee you that these are not eating.
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And either is the coil.
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So if you don't believe me, walk up here and touch the transistor.
29:57.000 --> 30:02.000
So you can see how the radiant charges it.
30:02.000 --> 30:05.000
We're going to watch it there.
30:05.000 --> 30:09.000
Nowhere near charged, right?
30:09.000 --> 30:13.000
So to see this, all you have to do is to calculate out what the machine's doing.
30:13.000 --> 30:18.000
All you have to do is a short little test.
30:18.000 --> 30:21.000
Draw the battery down at one amp hour.
30:21.000 --> 30:25.000
Get all the charge that was there out of it.
30:25.000 --> 30:28.000
Let it sit for a minute or so like we did.
30:28.000 --> 30:36.000
And then you can see here that we took, even in this short period of time,
30:36.000 --> 30:41.000
we took quite a bit out of the battery.
30:41.000 --> 30:43.000
Because now it's time, isn't it?
30:43.000 --> 30:48.000
It's time to charge.
30:48.000 --> 30:51.000
It's not very fast, is it?
30:51.000 --> 31:01.000
Approximately at 14.80, the battery is boiling, starting to boil.
31:01.000 --> 31:06.000
That's when the battery is going to start to gas.
31:06.000 --> 31:15.000
And at that point, from that point on, you can only put so much more in the chemical.
31:15.000 --> 31:22.000
And then you're going to gas off the battery, you're going to lose electrolyte.
31:22.000 --> 31:24.000
Right?
31:24.000 --> 31:29.000
So this is the way an SG machine should absolutely charge.
31:29.000 --> 31:35.000
Now when I give it up to 15 volts, when it goes over the thing,
31:35.000 --> 31:41.000
take the amp hour out of it again for that amount of time.
31:41.000 --> 31:48.000
And then I'll put it into generator mode and show you what the difference is.
31:48.000 --> 31:58.000
This one is what you call desultation.
31:58.000 --> 32:01.000
So it's starting to curve over, right?
32:01.000 --> 32:04.000
Which means that if you look in the battery, it's boiling.
32:04.000 --> 32:09.000
But it's micro boiling with no heat because there's no real current there.
32:09.000 --> 32:17.000
So actually, if you look at it, the curve is just a little bit above 15, right?
32:17.000 --> 32:26.000
Okay, so this battery is sitting at 12.23 under load.
32:26.000 --> 32:28.000
Well, it was.
32:28.000 --> 32:31.000
Nobody ever touches these batteries at the shop.
32:31.000 --> 32:33.000
They just sit there.
32:33.000 --> 32:41.000
So I just grabbed them and said, have at it, John.
32:41.000 --> 32:43.000
But you can see basically what the curve is.
32:43.000 --> 32:46.000
It can only flatten off now, maybe raise a little bit more,
32:46.000 --> 32:49.000
and eat up the electrolyte in the battery.
32:49.000 --> 32:57.000
So if we stop, we've got a good idea of what that is, right?
32:57.000 --> 32:59.000
Or does everybody want to make it go longer?
32:59.000 --> 33:05.000
It's up to you guys.
33:05.000 --> 33:10.000
Okay, so let's go back and do the same thing again.
33:10.000 --> 33:14.000
If I can make this thing work.
33:14.000 --> 33:19.000
Okay, so here, here the battery is at rest now.
33:19.000 --> 33:22.000
And we see where it rests.
33:22.000 --> 33:25.000
See, normally lead-acid batteries don't rest there.
33:25.000 --> 33:28.000
They rest at 6.2.
33:28.000 --> 33:38.000
So this charge takes a longer time and is more dense.
33:38.000 --> 33:45.000
Because it's taking a longer time, so it's doing it very slowly.
33:45.000 --> 33:49.000
Okay.
33:49.000 --> 33:51.000
Does everybody see that now?
33:51.000 --> 33:52.000
Yes.
33:52.000 --> 33:55.000
Okay.
33:55.000 --> 34:02.000
So let's...
34:02.000 --> 34:11.000
Okay.
34:11.000 --> 34:16.000
No, it's going.
34:16.000 --> 34:19.000
I've never ran it on this computer.
34:19.000 --> 34:27.000
I run it on an old XP computer, which doesn't give me the same trouble as this.
34:27.000 --> 34:35.000
This is the new one, the 7.
34:35.000 --> 34:44.000
Okay, now, do any of you have a good memory?
34:44.000 --> 34:48.000
Okay, notice what it's doing.
34:48.000 --> 34:53.000
It's got a different curve on the discharge.
34:53.000 --> 34:57.000
One ampere.
34:57.000 --> 34:58.000
Absolutely right.
34:58.000 --> 35:03.000
It was a more dense charge.
35:03.000 --> 35:06.000
It's got a different slope, doesn't it?
35:06.000 --> 35:09.000
It'll all be on the camera.
35:09.000 --> 35:14.000
So I don't have to worry about it here.
35:14.000 --> 35:23.000
So actually, I'm able to take it out longer in time this time before I reach the same level.
35:23.000 --> 35:27.000
Did I gain any energy?
35:27.000 --> 35:29.000
Yes or no?
35:29.000 --> 35:30.000
Yes.
35:30.000 --> 35:31.000
Okay.
35:31.000 --> 35:36.000
So I've taken it out longer now at the one amp.
35:36.000 --> 35:39.000
And now what I'm going to do is just stop the test.
35:39.000 --> 35:42.000
I guess go up here and learn how to use this thing.
35:42.000 --> 35:44.000
Stop test.
35:44.000 --> 35:48.000
And then what I want to do is I want to go to a new test, right?
35:48.000 --> 35:53.000
New graph.
35:53.000 --> 35:54.000
Well, look at that.
35:54.000 --> 35:59.000
You just need to learn how to use it.
35:59.000 --> 36:00.000
Yeah.
36:00.000 --> 36:06.000
Well, I'm not computer savvy.
36:06.000 --> 36:11.000
In fact, I hate the computer.
36:11.000 --> 36:12.000
Okay.
36:12.000 --> 36:19.000
So now remember I gave you this mode.
36:19.000 --> 36:26.000
I said that the SG was capable of being a generator.
36:26.000 --> 36:28.000
Forced mode.
36:28.000 --> 36:34.000
It's forced to charge because it's a generator.
36:34.000 --> 36:35.000
There is no pulse.
36:35.000 --> 36:37.000
There's no little spike.
36:37.000 --> 36:40.000
There's no capacitive discharge.
36:40.000 --> 36:44.000
It's just a straight generator.
36:44.000 --> 36:45.000
It's there.
36:45.000 --> 36:49.000
It's there.
36:49.000 --> 36:54.000
It's not going very fast.
36:54.000 --> 36:57.000
It's accelerating upward.
36:57.000 --> 37:01.000
It's doing exactly like a generator does.
37:01.000 --> 37:06.000
Just running it as a generator.
37:06.000 --> 37:09.000
Will the fan blades keep it going too fast?
37:09.000 --> 37:10.000
Well, they slow it down a little bit.
37:10.000 --> 37:15.000
I mean, it's blowing quite a bit of air over here because it's two fans.
37:15.000 --> 37:22.000
Does the load charge you with the battery in any way?
37:22.000 --> 37:23.000
It's just in a generator mode.
37:23.000 --> 37:28.000
It can't do anything but operate like a generator.
37:28.000 --> 37:29.000
Yeah.
37:29.000 --> 37:34.000
I did that, but it's not balanced like that with all the transistors.
37:34.000 --> 37:41.000
Well, if I want you to see something, it's drawing a lot of current.
37:41.000 --> 37:44.000
Drawing about three amps.
37:44.000 --> 37:51.000
Now, one at a time, come up here and touch the transistors.
37:51.000 --> 37:53.000
No, they're not hot.
37:53.000 --> 37:55.000
They are room temperature.
37:55.000 --> 37:59.000
So, John, at the beginning, you did it.
37:59.000 --> 38:03.000
In fact, at the beginning, when you wanted to make that thing run in a circle.
38:03.000 --> 38:04.000
That's exactly right.
38:04.000 --> 38:05.000
There it is.
38:05.000 --> 38:07.000
How long?
38:07.000 --> 38:09.000
There you go.
38:09.000 --> 38:11.000
Congratulations.
38:11.000 --> 38:15.000
Okay.
38:15.000 --> 38:24.000
Well, this is the principle of the Watson machine, except that it just is using mechanical switching.
38:24.000 --> 38:27.000
This is using electrical switching.
38:27.000 --> 38:28.000
Is that the primary battery?
38:28.000 --> 38:30.000
Watch the battery.
38:30.000 --> 38:32.000
Going up.
38:32.000 --> 38:37.000
Now, what's that curve compared to the other one?
38:37.000 --> 38:39.000
Quite a bit of difference.
38:39.000 --> 38:45.000
That's forcing the battery to charge as if it had a DC generator on it.
38:45.000 --> 38:52.000
And the DC generator can only put out so much with the RPM.
38:52.000 --> 38:57.000
But the point is, do you see what you call drag on here?
38:57.000 --> 39:06.000
That is a totally different charge.
39:06.000 --> 39:10.000
Will this desulfate or...
39:10.000 --> 39:17.000
Desulfation is when your battery is totally useless and you want to get the sulfation off.
39:17.000 --> 39:24.000
Just because this thing is running with the spikes and everything else doesn't mean any desulfation is taking place.
39:24.000 --> 39:30.000
That's some conception that started on the Internet that I never used the term.
39:30.000 --> 39:34.000
I don't worry about whether the battery is desulfating or not.
39:34.000 --> 39:41.000
As long as I'm putting the charge back into the battery, I'm not going to worry about sulfation.
39:41.000 --> 39:44.000
By this beat, the four minutes, the other one took seven.
39:44.000 --> 39:45.000
Right.
39:45.000 --> 39:48.000
You have two batteries.
39:48.000 --> 39:49.000
I'll change it.
39:49.000 --> 39:54.000
I'll change them if you want me to change them over.
39:54.000 --> 39:57.000
Here.
39:57.000 --> 40:02.000
Like a generator.
40:02.000 --> 40:07.000
This is nothing more than a generator.
40:07.000 --> 40:11.000
This side goes down, that side goes up.
40:11.000 --> 40:16.000
Up, down, up, down, up, down, up, down, up, down.
40:16.000 --> 40:46.000
Up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up, down, up
40:46.000 --> 40:55.000
See the chemical right now is, is, well it's having a fit.
40:55.000 --> 41:03.000
It's boiling away. It's eating the lead away. You don't need to be there.
41:03.000 --> 41:07.000
You just need to be up on that knee up there.
41:07.000 --> 41:19.000
So if you leave it there, you're actually going to damage your battery?
41:19.000 --> 41:28.000
Oh yeah. You bet. You're going to boil this away. There's no regulation. There's nothing to protect it.
41:28.000 --> 41:32.000
Do you have a device that can switch those batteries?
41:32.000 --> 41:37.000
People have built it. I don't do that. I'm not into that. You guys are into that.
41:37.000 --> 41:45.000
To me, I'm proving to you that, that I'm not going to deplete this front battery. In fact, it's going up.
41:45.000 --> 41:48.000
So I don't need to listen to that.
41:48.000 --> 41:50.000
The knee you're talking about is right at the first volt.
41:50.000 --> 41:55.000
The knee is right here. At 15 volts. See it?
41:55.000 --> 41:59.000
Now it can only gain, and it's gaining linearly.
41:59.000 --> 42:01.000
So you would have stopped this at 15 volts?
42:01.000 --> 42:07.000
I would stop this at 15, 3, 2 and say, hey, it's charged.
42:07.000 --> 42:12.000
Why do I want to burn up the sulfuric acid in the battery?
42:12.000 --> 42:18.000
Why don't I want to just boil the water away? You don't want to do that.
42:18.000 --> 42:23.000
Okay. So we'll stop it, right? Everybody's satisfied. It ran like a generator.
42:23.000 --> 42:25.000
Except for you.
42:25.000 --> 42:27.000
No, I'm satisfied.
42:27.000 --> 42:31.000
Not the yesterday that Ampere showed me.
42:31.000 --> 42:33.000
I don't go by amps.
42:33.000 --> 42:34.000
No, no, no.
42:34.000 --> 42:37.000
Well, I can put it on there if you want me to put it on there.
42:37.000 --> 42:38.000
I'm just curious.
42:38.000 --> 42:42.000
Actually, I was going to use the amp meter on the pulse charger.
42:42.000 --> 42:53.000
So you could see what's going to happen because we'd be able to change the pulse charger to do whatever we want to step it up just like the generator.
42:53.000 --> 42:58.000
So see, it can't go anymore. That's it. It's shot. It's done.
42:58.000 --> 43:03.000
You know, you put any more in that battery, you're doing the same thing that an alarm charger does.
43:03.000 --> 43:06.000
What's the voltage at the primary?
43:06.000 --> 43:09.000
1228 going up.
43:09.000 --> 43:14.000
No, why? Do you know why?
43:14.000 --> 43:16.000
What's going on with this circuit?
43:16.000 --> 43:18.000
Radiating.
43:18.000 --> 43:22.000
No, it's pushing backwards.
43:22.000 --> 43:27.000
Pushing backwards to the primary.
43:27.000 --> 43:29.000
From the main coil.
43:29.000 --> 43:30.000
From the main coil.
43:30.000 --> 43:34.000
The rest is being delivered to the secondary battery.
43:34.000 --> 43:39.000
So why am I worried about my primary going down?
43:39.000 --> 43:41.000
Does this only happen in the generator modes?
43:41.000 --> 43:43.000
No, this happens in a lot of different modes.
43:43.000 --> 43:46.000
It will happen with a capacitive discharge too.
43:46.000 --> 43:48.000
But not in the full charge.
43:48.000 --> 43:56.000
This under the radiant charge, right, not very much can go back because the pulses are very small little bits of current.
43:56.000 --> 44:00.000
This is a lot of current.
44:00.000 --> 44:05.000
See the diode in that far side there?
44:05.000 --> 44:08.000
That's exactly what it is.
44:08.000 --> 44:11.000
Yeah, it's hanging right here. See it?
44:11.000 --> 44:13.000
It's hanging right there.
44:13.000 --> 44:15.000
And you want to know something?
44:15.000 --> 44:18.000
It's warm.
44:18.000 --> 44:24.000
Well, to push the storage battery like that, there would have to be some current there.
44:24.000 --> 44:26.000
Okay, so 28.
44:26.000 --> 44:30.000
God, I can't get it to go down a minute.
44:30.000 --> 44:33.000
I don't understand what you people built.
44:33.000 --> 44:35.000
Figure out what that diode does.
44:35.000 --> 44:37.000
You people have a question or two.
44:37.000 --> 44:39.000
What does this diode do?
44:39.000 --> 44:43.000
If we short this diode out, we're back to the original radiant charger, right?
44:43.000 --> 44:45.000
Yes.
44:45.000 --> 44:48.000
In the original radiant charger, you get pulses going into the battery.
44:48.000 --> 44:52.000
You get a rise time here and then a fall.
44:52.000 --> 44:55.000
Rise and a fall.
44:55.000 --> 45:00.000
If this is grounded, the charges are going into the battery.
45:00.000 --> 45:07.000
And then when the pulse goes down, the capacitive push back, the ions go this way.
45:07.000 --> 45:09.000
They go this way, they jiggle back.
45:09.000 --> 45:10.000
Right.
45:10.000 --> 45:13.000
With this diode, they go forward.
45:13.000 --> 45:16.000
When the pulse goes down, it can't go nowhere.
45:16.000 --> 45:21.000
And so that's why that machine runs faster.
45:21.000 --> 45:26.000
Because it sees a higher impedance and more energy is being forced into the battery.
45:26.000 --> 45:29.000
Now, absolutely, Frank.
45:29.000 --> 45:31.000
You can see it.
45:31.000 --> 45:36.000
Thank you.
45:36.000 --> 45:39.000
Didn't take you very long.
45:39.000 --> 45:45.000
It's taken these people out here ten years.
45:45.000 --> 45:52.000
So is this what John wanted to build as a little kid?
45:52.000 --> 45:55.000
Do you know how few seven-year-old kids get what they want when we are...
45:55.000 --> 46:00.000
There's a few in here that had the same idea, that did exactly the same thing.
46:00.000 --> 46:03.000
But maybe they didn't have the means to do it.
46:03.000 --> 46:05.000
Me, I was kind of lucky.
46:05.000 --> 46:18.000
My dad handed us at six years old and seven years old the first top hat transistors that they got from Rocketdyne.
46:18.000 --> 46:19.000
All right.
46:19.000 --> 46:29.000
So, of course, the school thought, you know, these two guys don't have them ask any questions.
46:29.000 --> 46:34.000
Oh, look at that battery.
46:34.000 --> 46:40.000
Don't have them ask any questions because kids at this age don't need to know nothing.
46:40.000 --> 46:43.000
So we're happy.
46:43.000 --> 46:44.000
Right.
46:44.000 --> 46:46.000
Let's pull the amp power back out.
46:46.000 --> 46:48.000
I think I learned how to use this.
46:48.000 --> 46:55.000
Let's see where it goes down and settles, though.
46:55.000 --> 47:00.000
What do you think would happen?
47:00.000 --> 47:15.000
It would just go as far as the machine could push and the battery would be depleted to the level that the generator could push to.
47:15.000 --> 47:18.000
And then if you took the load off, it would rise back up.
47:18.000 --> 47:21.000
That's what the ideal generator does.
47:21.000 --> 47:26.000
You can harvest whatever.
47:26.000 --> 47:31.000
Actually, I'm not going to even call it that.
47:31.000 --> 47:39.000
I'm not interested in the amperage until I take it out of the battery.
47:39.000 --> 47:45.000
Well, first of all, why even care if the primary is going up?
47:45.000 --> 47:49.000
See, look, it's going down because it's not running.
47:49.000 --> 47:51.000
But you started at 12, too.
47:51.000 --> 47:54.000
Yeah.
47:54.000 --> 47:57.000
Okay.
47:57.000 --> 48:00.000
That is free.
48:00.000 --> 48:03.000
Okay, so let's let's take our one amp power back out.
48:03.000 --> 48:06.000
Right.
48:06.000 --> 48:09.000
And now that you guys showed me how to use a program, you know what?
48:09.000 --> 48:17.000
I'm going to spend a lot of time learning.
48:17.000 --> 48:21.000
So now what we want to do is discharge, right?
48:21.000 --> 48:24.000
We want to take our voltage.
48:24.000 --> 48:26.000
We want to take our one amp out.
48:26.000 --> 48:32.000
We want to cut off at 10, 5, 13 hours, one amp.
48:32.000 --> 48:37.000
Yeah, okay, sorry.
48:37.000 --> 48:42.000
Okay.
48:42.000 --> 48:47.000
Okay.
48:47.000 --> 48:49.000
Okay.
48:49.000 --> 48:51.000
Now look at our curve.
48:51.000 --> 49:01.000
Running in generator mode, supplying two batteries.
49:01.000 --> 49:04.000
Say that again.
49:04.000 --> 49:08.000
It's not as dense.
49:08.000 --> 49:20.000
There isn't a car battery that's out in the parking lot that's as dense as what the first charge was.
49:20.000 --> 49:21.000
It's good.
49:21.000 --> 49:25.000
I would use this.
49:25.000 --> 49:32.000
It's not dead.
49:32.000 --> 49:35.000
It didn't even make 13 volts yet.
49:35.000 --> 49:38.000
That's what it says.
49:38.000 --> 49:44.000
Or I'm blind.
49:44.000 --> 49:48.000
So, but see, it's real important to take this back out to where we had it.
49:48.000 --> 49:52.000
Remember?
49:52.000 --> 50:01.000
Because what happens with generators and what happens with pulse chargers and what happens with radiant chargers are
50:01.000 --> 50:05.000
they're different.
50:05.000 --> 50:14.000
Generators, if they're a real DC generator with brushes, can desulfate the battery, as you're talking about.
50:14.000 --> 50:23.000
If they're this type of generator, they're more like a power supply, a pulse power supply.
50:23.000 --> 50:27.000
And batteries degrade under that.
50:27.000 --> 50:37.000
What I'm saying to you guys is if you need to force a battery up to get it somewhere to get it charging with either pulse or radiant,
50:37.000 --> 50:43.000
that's how you do it.
50:43.000 --> 50:49.000
Actually, it held a lot more.
50:49.000 --> 50:52.000
Ten years ago, right?
50:52.000 --> 50:55.000
Would this load of charging your battery won't last as long?
50:55.000 --> 50:56.000
I would not.
50:56.000 --> 50:57.000
I would.
50:57.000 --> 51:01.000
I'd have to run this curve like for 200 cycles.
51:01.000 --> 51:03.000
No, I mean the physical battery wouldn't last.
51:03.000 --> 51:05.000
No, that's what I'm telling you.
51:05.000 --> 51:11.000
I'd have to run this curve and this machine that way for 200 cycles.
51:11.000 --> 51:16.000
I'm only showing you what I know.
51:16.000 --> 51:21.000
You can do what you want to do with it.
51:21.000 --> 51:28.000
This is like the third time because I wanted to show the modes of operation in the machine.
51:28.000 --> 51:31.000
So I knew about this a long time ago.
51:31.000 --> 51:44.000
And I didn't want to say anything about it because, look, I'm going to let it go out a little bit longer because it's better.
51:44.000 --> 51:56.000
So it's a pretty good mode of charging when you can push back to the front at the same time you're charging the Mac.
51:56.000 --> 51:58.000
Is it back down where it belongs?
51:58.000 --> 52:21.000
If you build the machine and it's all balanced and it's multiples and you can put amperage while you're taking amperage out.
52:21.000 --> 52:24.000
No, you want to take it to 15.
52:24.000 --> 52:28.000
You got to be above 15 to get the charge into the battery.
52:28.000 --> 52:29.000
That's yeah.
52:29.000 --> 52:32.000
Yeah, you want to boil it for a little bit, right?
52:32.000 --> 52:36.000
And that's that's dissolving the sulfate off the plate.
52:36.000 --> 52:55.000
OK, so the next thing is comparator.
52:55.000 --> 52:59.000
OK, so the comparator hooks up a little bit different.
52:59.000 --> 53:07.000
The machine.
53:07.000 --> 53:10.000
Is across the capacitors.
53:10.000 --> 53:12.000
You want to look?
53:12.000 --> 53:17.000
I'll hold it up.
53:17.000 --> 53:22.000
See, it's across the capacitors, this terminal and this terminal.
53:22.000 --> 53:26.000
And then this terminal over here.
53:26.000 --> 53:30.000
Is going to the negative terminal of the battery.
53:30.000 --> 53:34.000
So we did go put this wire.
53:34.000 --> 53:43.000
You want to.
53:43.000 --> 53:46.000
And then there's one other little thing.
53:46.000 --> 54:05.000
You need to run a positive wire from here to here.
54:05.000 --> 54:09.000
Did you see the little spark?
54:09.000 --> 54:11.000
When I first hooked it up.
54:11.000 --> 54:16.000
That's because the capacitors raised to the battery voltage.
54:16.000 --> 54:18.000
All right, so we can go ahead and go right.
54:18.000 --> 54:24.000
Just say start.
54:24.000 --> 54:30.000
Before you turn it on, would you give us the resting voltage of that battery?
54:30.000 --> 54:34.000
On the primary.
54:34.000 --> 54:49.000
12.63.
54:49.000 --> 54:54.000
All right, first of all.
54:54.000 --> 54:56.000
The comparator.
54:56.000 --> 54:59.000
Can you see it flash there?
54:59.000 --> 55:02.000
I don't have a camera, so I can't look at it, but.
55:02.000 --> 55:05.000
But you see the machine is at the same.
55:05.000 --> 55:09.000
It stays the same no matter what you do to it.
55:09.000 --> 55:15.000
Okay, so do you see the little wiggles? What it's doing there?
55:15.000 --> 55:18.000
Yeah, so.
55:18.000 --> 55:20.000
If I say to it.
55:20.000 --> 55:30.000
Charge a little faster.
55:30.000 --> 55:34.000
You can see the flash. It's bang, bang, bang, bang, bang, bang, bang.
55:34.000 --> 55:36.000
See it.
55:36.000 --> 55:45.000
And as it approaches the battery level, the comparator will want to go faster and it'll want to go faster and faster and faster and faster.
55:45.000 --> 55:48.000
Because it's looking at the battery voltage.
55:48.000 --> 55:52.000
Okay, but if I want to see stair steps.
55:52.000 --> 55:59.000
This is what I'm going to do.
55:59.000 --> 56:03.000
Oh, yeah.
56:03.000 --> 56:08.000
You'll slow the rate of discharge.
56:08.000 --> 56:13.000
So that you get actually, let me put the current meter in line with it.
56:13.000 --> 56:17.000
Okay, well.
56:17.000 --> 56:21.000
So the battery is going to fall now.
56:21.000 --> 56:24.000
And probably invalid test.
56:24.000 --> 56:32.000
But you'll get the general idea when you see the pulses occur.
56:32.000 --> 56:34.000
And we won't let it do that.
56:34.000 --> 56:40.000
We'll just put this in line.
56:40.000 --> 56:42.000
Okay.
56:42.000 --> 56:51.000
So can everybody see?
56:51.000 --> 56:56.000
It's one amp pulses.
56:56.000 --> 57:15.000
Okay, so let's take it up.
57:15.000 --> 57:18.000
See what it's doing.
57:18.000 --> 57:20.000
It goes up and goes back down.
57:20.000 --> 57:27.000
Of course, because there's this rest time.
57:27.000 --> 57:29.000
Well, we can make it go higher.
57:29.000 --> 57:32.000
But what's the machine doing?
57:32.000 --> 57:33.000
Right?
57:33.000 --> 57:38.000
Went down.
57:38.000 --> 57:41.000
It's going to wave around with this.
57:41.000 --> 57:53.000
If I make it go faster, it'll change a little bit more.
57:53.000 --> 57:55.000
Right.
57:55.000 --> 57:56.000
Right.
57:56.000 --> 57:57.000
It's not.
57:57.000 --> 57:59.000
It's not charging the primary.
57:59.000 --> 58:02.000
Right.
58:02.000 --> 58:08.000
But it's also doing these horrific pulses.
58:08.000 --> 58:16.000
Pulse discharges great for rejuvenating batteries.
58:16.000 --> 58:20.000
This also packs a very dense charge.
58:20.000 --> 58:22.000
Yeah, like a hammer.
58:22.000 --> 58:25.000
So let's slow it down to like two amp pulses.
58:25.000 --> 58:27.000
Actually speed it up.
58:27.000 --> 58:30.000
Actually, there's a five amp pulse.
58:30.000 --> 58:32.000
Okay.
58:32.000 --> 58:34.000
That's like, forget it.
58:34.000 --> 58:35.000
The meter isn't fast enough.
58:35.000 --> 58:38.000
So it's much more than that.
58:38.000 --> 58:40.000
And you can see it's just stepping it.
58:40.000 --> 58:43.000
See it.
58:43.000 --> 58:48.000
When the chart actually comes out, when it goes up, we'll just leave it there.
58:48.000 --> 59:01.000
This is changing.
59:01.000 --> 59:04.000
Well, yes, I can.
59:04.000 --> 59:09.000
I can make it go really fast.
59:09.000 --> 59:16.000
That's one mode that I haven't shown you.
59:16.000 --> 59:22.000
But if we put it in generator mode and make it generate to the capacitors,
59:22.000 --> 59:30.000
the charge is going to be enormous because it's got current behind it now.
59:30.000 --> 59:33.000
See, right now it's in radiant.
59:33.000 --> 59:35.000
Supplying the capacitors in radiant.
59:35.000 --> 59:45.000
And we're asking for five amp pulses at about one and a half seconds.
59:45.000 --> 59:49.000
Okay, so if we stop it, you want to put it in generator mode, right, Tom?
59:49.000 --> 59:50.000
Yeah.
59:50.000 --> 59:52.000
Okay.
59:52.000 --> 59:54.000
This is a fourth mode.
59:54.000 --> 01:00:00.000
Yeah, there's a fourth mode.
01:00:00.000 --> 01:00:06.000
Also, the time is going to increase on the comparator.
01:00:06.000 --> 01:00:08.000
So it's in generator mode now.
01:00:08.000 --> 01:00:12.000
And now what I'm going to do is I'm going to increase.
01:00:12.000 --> 01:00:14.000
I'm going to try to balance it out.
01:00:14.000 --> 01:00:35.000
You can probably hear it.
01:00:35.000 --> 01:01:02.000
So now it's about three pulses per second.
01:01:02.000 --> 01:01:03.000
It's going to go.
01:01:03.000 --> 01:01:10.000
It's isolated.
01:01:10.000 --> 01:01:18.000
That's what's going in the battery.
01:01:18.000 --> 01:01:20.000
Yeah.
01:01:20.000 --> 01:01:24.000
See here?
01:01:24.000 --> 01:01:28.000
Okay, now the comparator is stuck in generator mode.
01:01:28.000 --> 01:01:30.000
See it?
01:01:30.000 --> 01:01:50.000
It's going real fast.
01:01:50.000 --> 01:01:52.000
So these are all steps up.
01:01:52.000 --> 01:01:56.000
And then changing the mode there, you see we changed it, right?
01:01:56.000 --> 01:02:01.000
And we ran it until the comparator stopped or got too high.
01:02:01.000 --> 01:02:04.000
In other words, it was switching way too fast.
01:02:04.000 --> 01:02:05.000
All right.
01:02:05.000 --> 01:02:11.000
And there was almost an amp on the output of the machine directly.
01:02:11.000 --> 01:02:12.000
All right.
01:02:12.000 --> 01:02:22.000
Right now it's pulsing at about an amp and a quarter in just these little kicks.
01:02:22.000 --> 01:02:29.000
And now watch this curve because this curve is a little bit different at the end.
01:02:29.000 --> 01:02:31.000
Where it is?
01:02:31.000 --> 01:02:33.000
1230.
01:02:33.000 --> 01:02:38.000
We started out at 1230.
01:02:38.000 --> 01:02:40.000
But see the little steps?
01:02:40.000 --> 01:02:41.000
It's kind of hard to see.
01:02:41.000 --> 01:02:43.000
I can see them with my glasses.
01:02:43.000 --> 01:02:53.000
But there's little steps in there, see?
01:02:53.000 --> 01:02:55.000
Oh, yeah.
01:02:55.000 --> 01:02:57.000
The pulses are much faster than what the meter can go.
01:02:57.000 --> 01:03:04.000
I just put it there because it's like having a crutch.
01:03:04.000 --> 01:03:08.000
Everybody thinks in the world is current.
01:03:08.000 --> 01:03:10.000
What does current do?
01:03:10.000 --> 01:03:15.000
Does it have some more current?
01:03:15.000 --> 01:03:16.000
Please?
01:03:16.000 --> 01:03:17.000
It's not charging.
01:03:17.000 --> 01:03:19.000
There's no current.
01:03:19.000 --> 01:03:22.000
So now you know what the machine is.
01:03:22.000 --> 01:03:27.000
You should have no problem remembering this, right?
01:03:27.000 --> 01:03:38.000
If you have a problem remembering it, there's the two DVDs that were made before this that identically show you the same thing.
01:03:38.000 --> 01:03:48.000
I did it in advance because I knew you wouldn't remember this and you'd go back and it'd be all goofed up.
01:03:48.000 --> 01:03:51.000
So go look at the DVDs.
01:03:51.000 --> 01:03:54.000
At least go look.
01:03:54.000 --> 01:04:03.000
And try to remember this because in certain situations, this could be a lifesaver.
01:04:03.000 --> 01:04:09.000
On a useless machine that's been sitting in your bench that you said didn't charge the battery.
01:04:09.000 --> 01:04:13.000
How do you measure COP if that battery's not going down?
01:04:13.000 --> 01:04:15.000
Good question, isn't it?
01:04:15.000 --> 01:04:19.000
You can tell by this what the COP is.
01:04:19.000 --> 01:04:28.000
If you take all those curves, you can tell that the machine is about 1.2.
01:04:28.000 --> 01:04:31.000
Because you're not taking this into account right now.
01:04:31.000 --> 01:04:39.000
See, no matter what I do with this, now I'm adding another load to it, right?
01:04:39.000 --> 01:04:44.000
And you can see the power on this one's a little bit different because it's in attraction.
01:04:44.000 --> 01:04:50.000
So it's actually regaging.
01:04:50.000 --> 01:04:53.000
Remember what I said. I'm going to recap this.
01:04:53.000 --> 01:04:55.000
I don't want to see any neomagnets.
01:04:55.000 --> 01:05:01.000
Don't ask me anything about neomagnets because I don't want anything to do with them.
01:05:01.000 --> 01:05:04.000
They're no good for the machine.
01:05:04.000 --> 01:05:08.000
It's a buzzword, okay?
01:05:08.000 --> 01:05:15.000
Buy my new neomagnet. Look, it can pick up 1,500 pounds.
01:05:15.000 --> 01:05:23.000
Bull. If you're generating energy, then generate it with the ferrite aids.
01:05:23.000 --> 01:05:26.000
It's the same effect.
01:05:26.000 --> 01:05:29.000
Except one is going to cost you.
01:05:29.000 --> 01:05:33.000
And if it gets warm, it's going to cost you more because you're going to have to replace it.
01:05:33.000 --> 01:05:38.000
The cure temperature of these magnets can take a lot of heat.
01:05:38.000 --> 01:05:43.000
The cure temperature of the neomagnet is very low.
01:05:43.000 --> 01:05:47.000
So the difference on the end of this curve is that it's flattened.
01:05:47.000 --> 01:05:49.000
Right, right.
01:05:49.000 --> 01:05:58.000
Each one of these charges has its own little characteristic at the end.
01:05:58.000 --> 01:06:03.000
But the battery is boiling right now.
01:06:03.000 --> 01:06:09.000
But the generator, see, in the generator mode it wanted to push it up higher.
01:06:09.000 --> 01:06:13.000
It wanted to use the full inductance of the coil.
01:06:13.000 --> 01:06:17.000
And also in this mode, there is no heat.
01:06:17.000 --> 01:06:20.000
Somebody just come up and feel it so everybody knows.
01:06:20.000 --> 01:06:24.000
In fact, they're a little cooler.
01:06:24.000 --> 01:06:35.000
It's the fan that's cooling them, though.
01:06:35.000 --> 01:06:39.000
Could you replace the primary battery by a capacitor?
01:06:39.000 --> 01:06:41.000
No, you can't do that.
01:06:41.000 --> 01:06:44.000
Who told you that? You read that on the Internet.
01:06:44.000 --> 01:06:46.000
No, no, no, no. I'm just asking you.
01:06:46.000 --> 01:06:48.000
No, you wouldn't want to do that.
01:06:48.000 --> 01:06:52.000
But you could have one primary battery and feed the energy.
01:06:52.000 --> 01:06:57.000
Thank you.
01:06:57.000 --> 01:07:03.000
John, why seven wires with seven transistors and not just one bigger wire with one transistor?
01:07:03.000 --> 01:07:06.000
You can do it either way.
01:07:06.000 --> 01:07:09.000
I'm not limiting you. I'm telling you, you can't do it.
01:07:09.000 --> 01:07:13.000
Frank brought that question up and he's absolutely right.
01:07:13.000 --> 01:07:22.000
You can take a bunch of these coils all in one.
01:07:22.000 --> 01:07:31.000
It's just this device then.
01:07:31.000 --> 01:07:34.000
It's just this device.
01:07:34.000 --> 01:07:37.000
And you can isolate every one of these.
01:07:37.000 --> 01:07:41.000
You would only need one diode.
01:07:41.000 --> 01:07:53.000
And a diode back in generator mode.
01:07:53.000 --> 01:07:58.000
But remember the current here.
01:07:58.000 --> 01:08:08.000
See, people think that when you take coils and you start putting them like resistors,
01:08:08.000 --> 01:08:11.000
that this decreases and the current goes up.
01:08:11.000 --> 01:08:18.000
That's very untrue.
01:08:18.000 --> 01:08:20.000
Right, instantaneous voltage.
01:08:20.000 --> 01:08:23.000
And the current stays the same.
01:08:23.000 --> 01:08:26.000
So what are they telling you in school?
01:08:26.000 --> 01:08:28.000
It's just a bunch of crap.
01:08:28.000 --> 01:08:30.000
They don't want you to do it.
01:08:30.000 --> 01:08:32.000
They don't want you to find anything.
01:08:32.000 --> 01:08:36.000
They want you to do what they want you to do.
01:08:36.000 --> 01:08:39.000
Did he hear what he said? More coils actually?
01:08:39.000 --> 01:08:50.000
No, what he said was the coils, the voltage, the current is not going to increase.
01:08:50.000 --> 01:08:55.000
You're just going to have a thicker wire, aren't you?
01:08:55.000 --> 01:08:59.000
But you need to change this device proportionately.
01:08:59.000 --> 01:09:04.000
This would have to be a really high-power NPN transistor.
01:09:04.000 --> 01:09:08.000
Good luck, because most of them are only 16 amps.
01:09:08.000 --> 01:09:21.000
Unless you're going to buy a military transistor and ask for, well, the 5885 is 30 amps, but can't take the voltage.
01:09:21.000 --> 01:09:33.000
4502 and the MJ802 is 80 volts, but can't take the current.
01:09:33.000 --> 01:09:43.000
Right, so you could make this by paralleling transistors.
01:09:43.000 --> 01:09:45.000
Yeah, and put a heat sink on it.
01:09:45.000 --> 01:09:51.000
Well, you wouldn't need any if you're running an attraction, because it doesn't make any difference if you're running cold.
01:09:51.000 --> 01:09:57.000
It doesn't have to force it out past the pole so the device runs a lot cooler.
01:09:57.000 --> 01:10:01.000
So see where the curve is?
01:10:01.000 --> 01:10:04.000
Why don't you twist the wires together?
01:10:04.000 --> 01:10:08.000
To make sure the coupling is all the same.
01:10:08.000 --> 01:10:12.000
It's like a lip almost, but not quite.
01:10:12.000 --> 01:10:18.000
How far does what drop?
01:10:18.000 --> 01:10:24.000
Actually, it's not dropping, it's going up.
01:10:24.000 --> 01:10:29.000
Can you do a bank of battery?
01:10:29.000 --> 01:10:33.000
You can do anything you want to do.
01:10:33.000 --> 01:10:39.000
Those skilled in the arts.
01:10:39.000 --> 01:10:42.000
See, you're making a big mistake.
01:10:42.000 --> 01:10:50.000
You're making a big mistake when you think that you can keep putting things.
01:10:50.000 --> 01:10:58.000
You need to study the simplest form of the machine first to understand all these modes of operations,
01:10:58.000 --> 01:11:07.000
because John typing on YouTube or on some group somewhere is always a distraction.
01:11:07.000 --> 01:11:18.000
You type something back to somebody else and somebody else type something, now the question has changed and went over to cat's claws.
01:11:18.000 --> 01:11:32.000
Nobody's ever seen that has been in a group has ever been in focus and never stayed on one subject more than about five seconds.
01:11:32.000 --> 01:11:44.000
So somebody like me in the beginning of the year towards this conference refuses to talk on there.
01:11:44.000 --> 01:11:48.000
I don't care what they say.
01:11:48.000 --> 01:12:01.000
After this show, I'll only talk a little bit until the questions get ridiculous, because I already talked about it.
01:12:01.000 --> 01:12:03.000
Tom will tell you he runs it.
01:12:03.000 --> 01:12:06.000
He runs the energy science form.
01:12:06.000 --> 01:12:16.000
And the thing about forms are is if you have a form, why not use it?
01:12:16.000 --> 01:12:21.000
Actually, you're getting more here right now.
01:12:21.000 --> 01:12:25.000
You're getting more than you would ever get on the form.
01:12:25.000 --> 01:12:30.000
And it's on tape.
01:12:30.000 --> 01:12:35.000
And it's on a DVD set.
01:12:35.000 --> 01:12:40.000
And and your SG machine should run just like this.
01:12:40.000 --> 01:12:44.000
There's no secret here.
01:12:44.000 --> 01:12:47.000
470 ohms diodes.
01:12:47.000 --> 01:12:50.000
The resistor instead of the light bulb.
01:12:50.000 --> 01:12:54.000
Same transistor, same circuit.
01:12:54.000 --> 01:12:58.000
Same place, same time, same channel.
01:12:58.000 --> 01:13:03.000
How does this compare with the other forms?
01:13:03.000 --> 01:13:05.000
Heat.
01:13:05.000 --> 01:13:08.000
Heat.
01:13:08.000 --> 01:13:13.000
The machine becomes more efficient if these do not get hot.
01:13:13.000 --> 01:13:15.000
And these are not hot.
01:13:15.000 --> 01:13:17.000
And it's been running a while.
01:13:17.000 --> 01:13:20.000
What is hot is this.
01:13:20.000 --> 01:13:26.000
It's warm, but not hot.
01:13:26.000 --> 01:13:31.000
Yeah, the diode is taking all the current.
01:13:31.000 --> 01:13:34.000
What, this?
01:13:34.000 --> 01:13:37.000
It's pretty cool.
01:13:37.000 --> 01:13:40.000
This is a little warmer.
01:13:40.000 --> 01:13:42.000
These are cold.
01:13:42.000 --> 01:13:45.000
Oh, that's cold.
01:13:45.000 --> 01:13:49.000
It isn't the first time.
01:13:49.000 --> 01:13:52.000
Actually, I had one explode the magnets off.
01:13:52.000 --> 01:13:54.000
I got it going so fast.
01:13:54.000 --> 01:13:57.000
Just went right through the tape.
01:13:57.000 --> 01:14:00.000
What's the PIV of the diode?
01:14:00.000 --> 01:14:04.000
Oh, that 400 volts.
01:14:04.000 --> 01:14:06.000
Just some diode that was laying on a bench.
01:14:06.000 --> 01:14:07.000
No, excuse me.
01:14:07.000 --> 01:14:09.000
It's a 1200 volt diode.
01:14:09.000 --> 01:14:12.000
Now you regulate the speed of it.
01:14:12.000 --> 01:14:13.000
Regulate the speed of what?
01:14:13.000 --> 01:14:15.000
The wheel.
01:14:15.000 --> 01:14:18.000
By what you decide here.
01:14:18.000 --> 01:14:21.000
Yeah, the resistor is on it, regulate the speed.
01:14:21.000 --> 01:14:27.000
So does everybody understand what it is now?
01:14:27.000 --> 01:14:29.000
If you remove the two fans,
01:14:29.000 --> 01:14:33.000
you gain the two nano square L's you were taking off the fans?
01:14:33.000 --> 01:14:35.000
No, it'll just go faster.
01:14:35.000 --> 01:14:38.000
I'm using the two fans for a load.
01:14:38.000 --> 01:14:41.000
It's driving a load right now and doing the charging.
01:14:41.000 --> 01:14:45.000
See, the original, you can look at it this way.
01:14:45.000 --> 01:14:50.000
What toy have you ever had where you could play with it all day long
01:14:50.000 --> 01:14:55.000
and watch the battery go up that's driving it
01:14:55.000 --> 01:14:57.000
and recharge the other battery?
01:14:57.000 --> 01:15:01.000
You have never had that toy.
01:15:01.000 --> 01:15:03.000
And have mechanical energy.
01:15:03.000 --> 01:15:05.000
If you gear this down,
01:15:05.000 --> 01:15:11.000
this probably could be running a propeller in your boat very slowly.
01:15:11.000 --> 01:15:16.000
And why would you want to go fast anyway?
01:15:16.000 --> 01:15:17.000
You're on a vacation.
01:15:17.000 --> 01:15:20.000
Do you have to get there?
01:15:20.000 --> 01:15:23.000
What?
01:15:23.000 --> 01:15:27.000
How do you determine when you hit the sweet spot as far as?
01:15:27.000 --> 01:15:29.000
You don't even worry about it.
01:15:29.000 --> 01:15:35.000
You don't, Jack, you do not worry about it here with this right now.
01:15:35.000 --> 01:15:38.000
You don't need a sweet spot anymore.
01:15:38.000 --> 01:15:41.000
It's in attraction.
01:15:41.000 --> 01:15:44.000
It's not in repulsion.
01:15:47.000 --> 01:15:50.000
You don't worry about that curve.
01:15:50.000 --> 01:15:53.000
See, we wanted you to put it in the curve
01:15:53.000 --> 01:15:59.000
where the least amount of heat was on the transistor, on the groups.
01:15:59.000 --> 01:16:04.000
But everybody took that and said, blah, blah, blah, blah, blah.
01:16:04.000 --> 01:16:06.000
And then the next thing you know is there's gurus
01:16:06.000 --> 01:16:11.000
and they start their own forums and they lock you out.
01:16:11.000 --> 01:16:16.000
Imagine that they lock the inventor out.
01:16:16.000 --> 01:16:19.000
They boot you right out.
01:16:19.000 --> 01:16:22.000
They know more than you.
01:16:22.000 --> 01:16:29.000
That's why nothing's working.
01:16:29.000 --> 01:16:31.000
Does it matter which way the wheel's going?
01:16:31.000 --> 01:16:34.000
Doesn't make any difference which way that wheel goes.
01:16:34.000 --> 01:16:38.000
Does the power coil lose?
01:16:38.000 --> 01:16:41.000
Do you have a gain in the inductance or the overall?
01:16:41.000 --> 01:16:47.000
Well, first of all, the circuit says it all.
01:16:47.000 --> 01:16:49.000
What is the circuit?
01:16:49.000 --> 01:16:52.000
What are you pulling the energy from?
01:16:52.000 --> 01:16:55.000
What mode is the circuit in?
01:16:55.000 --> 01:16:57.000
There's a point.
01:16:57.000 --> 01:17:00.000
There's a point about inductance.
01:17:00.000 --> 01:17:03.000
Here's the coil, right?
01:17:03.000 --> 01:17:04.000
Okay.
01:17:04.000 --> 01:17:05.000
Are you listening?
01:17:05.000 --> 01:17:08.000
You asked.
01:17:08.000 --> 01:17:11.000
Okay.
01:17:11.000 --> 01:17:28.000
What mode of operation is this transistor in?
01:17:28.000 --> 01:17:32.000
Well, that's more than Paul's.
01:17:32.000 --> 01:17:35.000
According to what's going on right now, it's open circuit
01:17:35.000 --> 01:17:37.000
so there's no misguided.
01:17:37.000 --> 01:17:43.000
But we already know that.
01:17:43.000 --> 01:17:50.000
So if I was looking at it like an amplifier, Freddie,
01:17:50.000 --> 01:17:53.000
what's its flavor?
01:17:53.000 --> 01:17:57.000
Well, it is partially linear initially,
01:17:57.000 --> 01:18:01.000
but then the more current that goes into the base,
01:18:01.000 --> 01:18:03.000
the more saturated it is.
01:18:03.000 --> 01:18:06.000
It really wants to saturate it, otherwise it would heat up.
01:18:06.000 --> 01:18:08.000
Then it must be saturated.
01:18:08.000 --> 01:18:10.000
Right.
01:18:10.000 --> 01:18:16.000
Okay, let me change a little bit.
01:18:16.000 --> 01:18:17.000
No.
01:18:17.000 --> 01:18:20.000
It's in reverse phase.
01:18:20.000 --> 01:18:25.000
It's in the inverted phase, which is very important
01:18:25.000 --> 01:18:30.000
because where is the gain in the circuit?
01:18:30.000 --> 01:18:32.000
The HFB of the transistor.
01:18:32.000 --> 01:18:35.000
Right.
01:18:35.000 --> 01:18:40.000
But the gain occurs between the collector
01:18:40.000 --> 01:18:46.000
and the collector circuit, so there's a gain here.
01:18:46.000 --> 01:18:54.000
If the coil was down in the emitter circuit...
01:18:54.000 --> 01:18:57.000
Then it has a 0.999 gain.
01:18:57.000 --> 01:19:00.000
Right.
01:19:00.000 --> 01:19:05.000
So that's important to understand that it's inverted.
01:19:05.000 --> 01:19:08.000
So when you look at it, if you put a PNP there,
01:19:08.000 --> 01:19:11.000
then it would be on the opposite side.
01:19:11.000 --> 01:19:14.000
Can you use beds on that part?
01:19:14.000 --> 01:19:18.000
Use what you want. Those skills in the art.
01:19:18.000 --> 01:19:24.000
Just try.
01:19:24.000 --> 01:19:26.000
FETs are a buzzword.
01:19:26.000 --> 01:19:29.000
In fact, I'm going to end it right now
01:19:29.000 --> 01:19:33.000
because then I'm going to let Frank tell you something,
01:19:33.000 --> 01:19:36.000
because Frank brought that up.
01:19:36.000 --> 01:19:41.000
If you're going to use FETs, you better be able to drive them.
01:19:44.000 --> 01:19:49.000
If you use a FET, all power FETs have a tremendous
01:19:49.000 --> 01:19:54.000
gain capacitance, 2000 pass per sol.
01:19:54.000 --> 01:19:57.000
So what you need to do is to charge that capacitance
01:19:57.000 --> 01:20:02.000
really hard, 5 volts, 10 volts or whatever.
01:20:02.000 --> 01:20:07.000
However, when the transistor begins to switch,
01:20:07.000 --> 01:20:10.000
you get what is known as a Miller effect.
01:20:10.000 --> 01:20:13.000
It is an amplified capacitance,
01:20:13.000 --> 01:20:16.000
which is a function of the GM of the transistor,
01:20:16.000 --> 01:20:19.000
which is the gain on the transistor, FET rather.
01:20:19.000 --> 01:20:24.000
And so you suddenly find it's very hard to drive.
01:20:24.000 --> 01:20:26.000
So with this kind of circuit,
01:20:26.000 --> 01:20:29.000
if that does not have enough power to drive a FET,
01:20:29.000 --> 01:20:32.000
you would have to add what is known as a FET driver,
01:20:32.000 --> 01:20:34.000
which is no circuit.
01:20:34.000 --> 01:20:37.000
They're available.
01:20:37.000 --> 01:20:40.000
I'm not saying you can actually do something,
01:20:40.000 --> 01:20:45.000
but it takes people and engineers to do it.
01:20:45.000 --> 01:20:48.000
That's a famous word, Frank.
01:20:48.000 --> 01:20:50.000
But that's the truth of reality.
01:20:50.000 --> 01:20:54.000
For us public guys, we just use the transistor and work with it.
01:20:54.000 --> 01:20:56.000
I want to be a higher power motorist.
01:20:56.000 --> 01:20:58.000
No, no, no, Frank.
01:20:58.000 --> 01:21:00.000
You can use a FET.
01:21:00.000 --> 01:21:03.000
Frank built a tin coiler and saw exactly what happened
01:21:03.000 --> 01:21:06.000
when you couldn't drive it.
01:21:06.000 --> 01:21:08.000
Thank you.
01:21:08.000 --> 01:21:11.000
That's the story of the FG.
01:21:34.000 --> 01:21:36.000
Erin?
01:21:36.000 --> 01:21:39.000
Okay, about what time do you think?
01:21:39.000 --> 01:21:41.000
We're almost there.
01:21:41.000 --> 01:21:43.000
We're almost there.
01:21:43.000 --> 01:21:46.000
So, um...
01:21:46.000 --> 01:21:48.000
Another few minutes.
01:21:48.000 --> 01:21:50.000
Sorry.
01:21:50.000 --> 01:21:52.000
Oh, thank you.
01:21:52.000 --> 01:21:55.000
I figured it would be my sister and my son's last year in life.
01:21:55.000 --> 01:21:57.000
Thank you.
01:21:57.000 --> 01:21:59.000
It's really hard.
01:21:59.000 --> 01:22:01.000
Especially on a show.