possible substitution for IRFPG50

FWIW, I wonder if the IRF842 would work. I happen to have a couple in my spare parts bin. They are repetitive avalanche rated.

IRF842 Datasheet pdf - N-CHANNEL ENHANCEMENT-MODE SILICON GATE TMOS POWER FIELD EFFECT TRANSISTOR - Motorola
"http://www.datasheetcatalog.com/datasheets_pdf/I/R/F/8/IRF842.shtml"

I'm no expert on reading the datasheets, but the only significant difference I can see is the PG50 is rated for 1000v and Rds@2ohm, and the the 842 is rated for 500v and Rds is 1.1ohm.

I know I could simply plug it in and try it, but alas, I have no oscilloscope and I wouldn't be able to confirm it anyway. (sigh)

-kent

Hi Kent - you could check the heat on the load and the battery draw down? But Fuzzy - we need your expertise here.

EDIT Thanks Fuzzy. Yet again. much appreciated.

Hi Kent,

I cant see on the PDF any information on Single Pulse Avalanche Energy or Repetitive Avalanche Energy these are two very important Mosfet specifications for these "replications".

The IRFPG50 is the standard profile and anything very close to these parameters may work ....

International Rectifier IRFPG50
Single Pulse Avalanche Energy - 800 mJ
Repetitive Avalanche Energy - 19 mJ

Here are some more possible examples ....

Fairchild Semiconductor - FQH8N100C
Fairchild Semiconductor - FQAF11N90C
ST Microelectronics - STW9N150

Hope this helps, Thanks for your parcipitation in this venture !!

Glen

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EDIT- I found a International Rectifier Data Sheet for your IRF842 ......

International Rectifier - IRF842

Single Pulse Avalanche Energy - 610 mJ
Repetitive Avalanche Energy - 13 mJ

The Single Pulse Avalanche Energy is low but it may work, but without a scope it would be hard to know.

Hi Fuzzytomcat,
I did today that small Test, and its like CW gives a 45° Angel control
CCW gives 0° or 90°. CCW is better for that.
There is a technical Term for this Angel Control, but i dont know the exact Word, so cant translate it.
A skilled EE do know about it, just not a bumbler.

I got today some more Info about the Magnetmotor, what i did mention.
The configuration there was Rotor N vs Stator N's, this Effect did then appear as same Poles face eachother.
Not sure, if it helps, but its kind of a side note.





Oh well

The proposed circuit add-on could be built. The AC that feeds the transformer primary would come off directly across the load resistor. This would then feed a diode bride off the secondary and this filtered output could be used to recharge the source battery. If COP>17, then this should allow the circuit to run itself indefinitely. If most of the excess energy manifests as voltage/current across the load resistor then this should work. If you claim the the excess energy manifests elsewhere, then it might not work as proposed.

.99

Not sure what amendments to the switch you are referring to. The diode? I can do the published circuit, with our without the 555 (I would prefer without as it won't achieve 3.7% as published), but I'm not so sure I can do Aaron's. I will have to take a close look. I would also doubt that I can obtain the crazy circuit operation. Unfortunately, with this version of SPICE, one can not tweak the pot values in real time to see the effects. It could take days to try all settings and combinations and even then there is no guarantee that the thing will break into the funky oscillation mode.

You have stated that the circuit will exhibit overunity without the funky oscillation, and with or without the flyback diode. This is what I would prefer to simulate.

May I ask what it is that you are expecting or hoping to see with your requested wave forms?

May I ask what it is that you are expecting or hoping to see with your requested wave forms?poynt

I'm sort of expecting something like Aaron's shown us? But I've no idea. Sorry you can't replicate Aaron's test. But I'd still like to see the published test.

Poynt - that circuit configuration you proposed with the bridge rectifier and the inductor - please give us a schematic. I take it you'll be using a functions generator.

This is not helpful to me. First from Aaron, I can't recall seeing anything conclusive or remotely what I would call "informative" wave forms taken from your original published circuit. Second, if you are asking me but have no idea what you are going to compare it to or why, then it would be time wasted, and I feel it is not fair to ask.

I think many of us (on this side of the fence) are still trying to figure out exactly what Aaron's test was all about. At such low currents it's difficult to get reliable readings. I was hoping you'd have something concrete that you could relay to me as to what you expect to see. Saying "something similar to Aaron's results" just doesn't give me a heck of a lot of incentive.

I'll draw up the proposed add-on. I am certain that if Aaron (or Harvey in proxy) sees this he will devise some reason as to why it is going to "kill the effect", but since you're curious, I'll post it anyway.

.99

COP test?

A proposed COP test. Rosemary asked for the schematic.

HF capable transformer.

Capacitor filtering on output would be optional, but not necessary. With COP>1.5 or so, should work in theory, if excess COP appears as usable V and I in the load to obtain real power output.

Ok. I take it that this is a circuit designed with the intention to defeat unity. Let's see the results.

And regarding your penultimate post. Poynt you're an obsessive compulsive. I know this. I have to read it through again and again and again. I'll skip it if you don't mind. Let's just see the outcome of this one.

From the values I've witnessed in this circuit, you should be fine with the IRF842. I have seen spikes above 750V with different things I've tried, but your Avalanche would probably handle that fine as long as you allow at least 1µs in between Avalanche (let it recover). Nothing I've seen, even during aperiodic mode, comes close to that interval. Get a good heatsink on it just to be sure, but with 1.1 on resistance, it won't get as hot as the IRFPG50 for the same current. Probably why its rated for higher amperage. It will be an interesting thing to see if the 1300pf input capacitance makes a difference in the aperiodic mode - if it even occurs.

If you do not have a scope, try putting a small flashlight bulb between the ground of the battery and your circuit. You will find adjustments that let it glow more than others. When the bulb experiences a reverse current it will glow brighter. Place a diode in series with it momentarily to see if the lamp dims when it loses the reverse current. If it doesn't, then you are not clipping any of the waveform below ground with the body diode. Even so, if you can get a good temperature rise in the resistor without burning out the bulb you may be getting something worth putting a scope on. Keep us posted.

You may wish to revisit the bridge connections

Indeed. Shouldn't draw when so tired.

Thanks for the pickup. Diagram is updated.

.99

I drew back once in answering your posts, but obliged lately in hopes of making a connection. No Go. I simply can't communicate effectively with you. I am also growing rather loathsome of the insults, labels, and consistent and flamboyant convolution of my posts and their intended messages.

Adieu.

.99

Just a quick blog here:

After I signed off from all my ramblings I went to experimenting to see if I could get the negative swing in my circuit. I tried some other inductors and stuff just enjoying the hands on that I have been removed from for so many years. I was looking a bit closer at that 'punch through' I showed on my video and was really trying to pin down how and where that was coming from. Clearly, it occurs at a time that the 555 is supposed to be off. Tracing it back from the gate, and expecting to see it diminish the farther I got from the gate, I found just the opposite. Uh oh...I'm recorded as stating that this can't be coming from the timer , but here it is clearly jumping out when the timer should be off. Why is it there?

My first thought went straight to the ground on this thing - press fit wires in old oxidized breadboard contacts etc. Lot's of room for 'noisy' connections. That all check out clean. Something was telling this chip to fire up the output and then before it even gets on, it was being told to 'unfire' it. But what could do that? This chip has a TTL flip flop in it and the SET / RESET inputs to it have to conform to very specific levels in order for it to flip. So I took a close look at the input waveforms to pins 2 and 6. The were clean. Where is this spike coming from? So I looked at pin 5, it is decoupled to ground through a 0.01nF cap. It clearly had the spikes and this is why it is switching the flip flop. Where are they coming from...the cap? I pulled the cap out, they persisted. The only other way they could get here is via the Vcc line. I could put a big filter system on the Vcc...

So I put the same cap from pin 5 to pin 3. Problem solved, the negative feedback cancels the effect. Very unconventional approach, but it worked.

So... I see that I have a 5 Ohm 50W 5% resistor here. It has a number on it - RCLALN50 with a date stamp of 8507. I wonder what that would do in the circuit. Oh, look there are two there, they look similar. So I put them in series. The waveform looks similar but slightly smaller in amplitude on the spikes. All of a sudden the thing goes into aperiodic oscillation and I just monitor things a bit. Whoa, that little thing is getting hot. So I take a reading. 42°C on one end and 34°C on the other... and climbing. IRFPG50 is cool to the touch, it reads 29°C same as the wood on my desk - ambient. I slide the thermometer laser along the body of the resistor heatsink...it is a gradient. Now I have 45°C on the hot end and 35°C on the cool end. Wierd, must be a flaw in the internal resistance. So I measure the other one... weird, its ambient. A closure look and I realize the second one is a precision 0.1 Ohm 1% 50W. So I turn the 5 Ohm around expecting the gradient to reverse. Same same. I repositioned the device to see if the gradient was related to the matt it was sitting on - nope. This is a thermal conduction matter and since both ends of the resistor have identical alligator clips and wires it must be related to how the energy flows in the device. I'm sure someone reading will know why the heat migrates to the higher voltage side

I was seriously considering running a full test on this and was about to start taking notes and video when it dropped out of aperiodic operation - on its own. I adjusted the gate resistor, changed the pulse width etc and messed with it for about an hour and finally gave up. I could get into operation briefly and then it would drop out. It was late, moving to 3AM IIRC so I set it aside until tonight. So I will see if I can get a better response now. I may try 24V to see if it improves things as last night it was running on only 12V (or less - I suppose I should measure that, been using it for a few days now).