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9XA Stanley Meyer PWM

The 9XA is a repelication of the Voltage Intensifier  VIC signal pwm  a 5 khz pulse dc signal with a overlayed 5 khz gate timed to 3 seconds. 

 

In later versions the gate voltage level is adjustable with in the

3 second space. 

 

The Gate is used to avoid dead short and avoid grounding cell, hich w want to emain in a charged + state. To keep it charged state with a large + cathod the outer tube larger than the = inner - annode tube with a 1 to 2 mm gap using distilled water only.

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The 9XA was a circuit that Stan used to produce a gated pulse frequency via two H11D1 optocouplers.

The optocouplers were driven by two independent stages of 555 timer clock frequency into 3 7490 decade counter ICs.

 

The 7490s provided divisions of 555 frequency, but also produced 50% duty cycle pulses.

 

Below, "A" is one 555/7490 stage and "B" is second 555/7490 stage. The two optocouplers produce an equivalent to AND logic gate.

9XAM

Now a Merged Circuit is released to public with Transistor  to simplify assembly  of the voltrolysis training circuit which has 9xs 2 9xbs providing power a gate and a over layed

5 khz signal on 5 khz 

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9XAM Stanley A Meyer 9xa including Transisitor.jpg
Stanley A Meyer 9XA

Meyer 9xa PWM  makes a 50% duty, The 9xa is 2 8xa, designed to be used with a transistor, and make a frequency and then gate that same frequency.

 

The 9XA has a max freq output after the opto-coupler of 1.41KHz max.

This is on PWM-A with switch-2 ON. With switch-1 ON, the freq seems so high,

 

that the opto-coupler does not have the frequency response to discern the pulses. I tested using 9V at the opto-coupler (maybe need a higher voltage)? With freq doubling after the chokes, the freq will be closer to 3KHz.

 

I'm thinking that I need to be closer to 4KHz to get to resonance. Do you get similar outputs on the 9XAs that you use? Never the less, I'll try it out on my cell setup once I've put together the SCR and some chokes. it is probibly your transistor. not the opto coupler. yes the opto has a top speed. it is higher then 1khz

 

Tested them, higher than 1khz. Finally, figured out how to adjust the blue trimmer knobs on pmw-a, so that on switch 2, the top end is about 5.8khz, which registers properly after the opto.coupler. At switch 1, freq gets to high for opto, so I'll stick with switch 2 on pwm-a.

 

if you want faster, you can change a cap and it will go faster

 

This is Stan's Electrical Polarization Process Unit signal on the scope. The other signal is replicationsignal on the Rigol scope.

We have a LC Tank Circuit with a H Bridge and a 2 Pwm 5kz 2nd 5 khz  gate driving a 2000+ Perm Core with chokes/ ballast creates a charge to a
 water capacitor with a quartz tube this  break water efficiently I post drawing for those of you want to play with circuit  building there is a blocking diode which uses circuit ringing to keep cap charged  we tap out some electrons to keep the bounce power dc and stop it from switching
to ac the cap circuit must stay dc to work the plasma charge build up on the + plate is the catalyst  for more information please visit  securesupplies.biz

 

Stanley A Meyer 9xa Circuuit board Voltr
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Stanley A Meyer Circuit PLan PCB PWM
Stanley A Meyer 9XA
Stanley A Meyer 9XA
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Stanley A Meyer Circuit PLan PCB PWM
9xa Circut Stanley A Meyer
9xa Circut Stanley A Meyer
Stanley A Meyer 7139465t.jpg
Stanley A Meyer 7139671e.jpg


9XA part list 

  • KBU808G bridged rectifier 

  • 3300 uf cap 

  • 330uf cap 

  • 7805 regulator 

  • 4x 5k trimmer pots 

  • 2x 5 position dip switches 

  • 2x red led 

  • 104 cap x 11 parts 

  • 2x H11D1 opto 

  • 2x 555 timer 

  • 103 cap 

  • 7404 inverter 

  • 6x 7490 decade counter 

  • 4x 220R resistor 

  • 2x 1k resistors 

  • 2 1m resisters 

  • 2 100k pot

-----

SCR  (SWITCH) part list 

  • KBU808G bridged rectifier 

  • 100 ohm resistor (20 watt or so) 

  • S4025L 

       (or simular use a heat sink and make sure the pin out matches) 

  • 1N4007 diode 

  • 6 Amp 1000 volt diode 

  • H11D2 and 220 resistor

       ( not needed if using the 9xa or the 9xb) 

Sourcing 9XA Parts

 

4 Channel Band Rotary Switch Selector 2-Pole 4-Position on that frequency switch

 

http://www.ebay.com/itm/1k-2k-5k-10k-100k-100-50k-20k-500-ohm-Potentiometer-pot-10Turn-Counting-Dial-mah-/321089650019?pt=LH_DefaultDomain_0&var=&hash=item4ac26f3d63

 

any rotary switch should do the job. if it has more then 4 positions......just connect the channels not in use to the last one in use. then when you forget, and turn it there

 

Variac 

 

0-270V variac 5A, would it offer me any advantages or better production of gas? Would the inductor coil & SCR be capable of running it at the 270v?

the opto coupler and resistor stan used will fail at some voltage you will see it on your scope, the gate will be lost 120 volts is no propblem, as it is designed for that. i have a 350 volt transformer,

 

i just plug it into my variac. you can change your opto or the resistor to get different higher voltages...or make a resistor voltage devider for the opto. a voltage devider would be like 2 of those resistors, one goes to pos and the other to neg, then pull power from the center of the 2 resistor. if the resistors are the same value, then you split the voltage in 2. https://en.wikipedia.org/wiki/Voltage_divider there is no limit to what you can do with electronics.  just because you do something that did not copy meyer, does not mean it will not work. just remember, the voltage will go up passed what you put in.

 

SCR Up Grade to make change to high Variac 

Changes to the SCR board to allow the 0-270v on the Variac Transformer.

well over rated for what I would need it for! NTE5531 25 Amp 800 Volt SCR (QTY 1 ea) $7.50

http://www.ebay.com/itm/250277119863?ssPageName=STRK:MEWAX:IT&_trksid=p3984.m1438.l2649

 

Shoul work. and be over rated

Here are the folowing of my experiments on the SCR board and a bifilar coil : How to compute the gate frequency in order to build a specific pulse.

https://www.youtube.com/watch?v=k9OPlubNptA

Here under a memo. 

9xa Circut Stanley A Meyer
9xa Circut Stanley A Meyer

what I take from this experience is that I need a precise frequency if I want a proper functionning of my circuit. Juste pulsing a gate at 33 Hz is not enought, 33.30 Hz or 33.36 Hz make a big difference in the stabilisation of the amp consumption because the more the pulse is regular (the number of pulses is an integer ) the more the amp consumption is stable.

What I don't know is "what is a regular amp consumption on this type of circuit ?" in other words, do I properly set the circuit or do I have other things to work before going further ?

 

Need more cells now and to build a VIC.

Hum...   there is something wrong in my theory  ... I have tried to make a 7 pulses wave form with this formula but I got only 5. 
As the frequency generator output is a 50% duty cycle, the gate duration is equal to the train pulses duration. My formula is wrong

So back to the worktable  

 

In fact it's

fg = (2 x Fw )/ 2n ( because of the 50% duty cycle)

It can also be adjusted for variable duty cycle. ( ...back to the worktable...)

might be:

fg = (2 x Fw x D) / n

 Where :

fg : Gate frequency

Fw : Wall frequency

D : Duty cycle

n : Number of pulses in the pulse train

 

So for 50% duty cycle ,

- a 5 pulses pulse train give us :

fg = (2 * 50 * 0.5)/5

fg = 10 Hz 

 - a 6 pulses pulse train give us :

fg = (2 * 50 * 0.5)/6

fg = 8.33 Hz

 - a 2 pulses pulse train give us

fg = (2 * 50 * 0.5)/2

fg = 25 Hz

 

9XA   Has the 9XD Power Supply Built in 

9XA and SCR Sync Video 

9XA Gated Pulse Train 

9XA addendum

this circuit addendum is for those who want the “gated” pulse not just a 9XB output. 
if you like this I also have another circuit that does not use the 555 as an oscillator 

ok on to the explanation: 

the two mosfets are the BS170 that’s a small 
TO-92 case, and are good for up to 500mA 

the output is at the arrow. 

the two resistors in parallel are 100 ohm 1 watt, and are for biasing the mosfet. currently the circuit is running at 240mA, and is capable to drive whatever you want, 2N3055, or IRFP260N that is capable of 200V, 50A with a max of 300Watts 

make sure you tie all the grounds together, or you’ll get some weird scope traces. 

if you’re interested in the non 555 oscillator, 
that has adjustment for frequency, duty cycle, and amplitude. post a reply with your email address, because of the limit of file size I can’t post it here. 

thanks mike

=========================

this is the explanation for the circuit: 
comparators in oscillator configuration 

firstly you don’t need more than one decade /SN74LS90 because the frequency group can be changed by using jumpers on the header pins to select different freq. groups. this is the same for the gate freq. 

the main or resonant freq. is run through the decade 
to maintain the 50% duty cycle. 

resistors R24, 26, and 27 need to be set for brightness due to the oscillations the resistor will be lower in value make the LED brighter. 

resistor values will be the same for the gate circuit, but the capacitors will be larger for a lower freq. 

both chips are the same LM311, I recommend using 
separate chips so as to keep the noise down. 

the reason there are no values capacitors, is because need to selected caps find your resonant freq. 

I recommend using a separate 5V regulator for the decade and a 12V regulator to supply the rest of the circuit, to give greater output. you could also use the totem pole mosfet driver circuit that Max posted to boost output. I like it. 

R20, and 21 are the same 100 ohm 1 watt resistors as in the beginning of this tread. 

connectors J1 through J8 are for header pins to use jumpers to select frequency groups, simpler that a multi position switch, more that one jumper can be used to add caps to increase capacitance and lower freq. 

decade/ SN74LS90 is connected the same way that Max has posted for the 9XA and 9XB. 

thanks, if you have any questions you can email me at snaprollin@yahoo.com 
the name is mike 
good luck I hope this helps, I have more circuits to add as soon as I can get to them. 

down load pic below here 

Here Brad shows his pwm into his driver board VIC replication in multisim.
 
The circuit produces a step charging waveform and is a great learning tool. In the simulation you can change frequency, voltage, current, and any component. The Switch Drriver is close Replication to the Vic Driver,
 
I put in this 9XA section so people can see the transition from 9XA to a more ddvanced driver add on with room for inputs from accellerator peedal PLL to driver and to switch and Mosfet /tansistor diving step, Brad show a Simple but reliable base circuit to start that progession here in this video.

Updated  2020 Chart the More Pure the Water the more powerful the gas and water fuel will be. As the gases will not ground or stabilize. Making bigger Bang with more explosive force than

Implosiv heat force.

48275136_810907259252247_262168605223393

Take Some time to Study this Chart 

Basically is shows that nature is a balanced system. 

Gases and elements are seking to be stable and grounded and balanced. 

We know that during a imbalance,( voltrolysis and electron removal EEC) 

 if we have a technique to maintain the imbalance

Energy can come into the system to try to rebalance, from nature 

Just like a Nuclear reaction.But miniture.

Water to gas expansion is x 1800

A Engine is not a closed system it interacts with nature  air comes in.

and air goes back out to nature. 

 

We when we remove electrons from o2 we make it unable to reform to water

nor rebalance readily . Causing the momentary imblance allow gases to remain

gases in air or water longer.

if all ( or the majority) of  negative charged electrons are removed from the air and surfaces the fuel gas or fuel nano bubble water fuel  can not ground,

and when combusts finally  it has no choice but to explode to re arrange balance

instead of the typical implosion

- 1800 times back to water we get a second expansion  with more force than heat

of x 3600, before finally contract - 3600 back to water again and balanced neutral charges.

 

48208588_810897585919881_313977884322981

Hre is another Chart the traditional Ph scale does not correctly measure nor show dissolved nano Bubbles and cnocentration of h21 h2 O1O2. 

Ww Know  that when dealing with ph of fuel ph can go to 20 to 30 ph on charts.  It is the Same wwith dissolved nano bubbles of h1h2 + charged and + charged O1 O2 nano bubbles. 

It is a new area of technology by which we measure dissolved gas density with laser and measure the size and density of bubbles from 20nm to 50 nm 

Nano Bubble Fuels H2 Hydrogen

CORE MATERIAL - Core from Standard 50 Hz transformer (with ferrite core from Flyback transformer not working !!!!!) Primary coil - 300 turns / 1 mm. copper wire Secondary coil - 300 turns / 1 mm. copper wire (Primary and Secondary coils are wind bifilar (together with two wires) on one spool for best transfer !!!!!) In this case - without Resonant chokes C1 and C2 !!!! !!! If the Primary coil terminals are "reversed", Step Charge not occur !!! Using voltage to Primary coil: 24 Volts / 0.3 Amps (After 4 diode bridge Graetz, has a filtering capacitor 10000 uF). (Note that at terminals of the primary winding is not connected diode). Output Voltage to the Cell: +24 Vpp / 0.3 Amps High frequency - 1 kHz Gated frequency - 50 Hz To Primary coil Stan Meyer not use 12 Vots! Meyer use 120 Volts !!!! See Figure 1-14 from Memo WFC 420:

Stanley A Meyer Circuits
Stanley A Meyer Circuits
Stanley A Meyer Circuits
Stanley A Meyer Circuits
Stanley A Meyer Circuits

Stanley Meyer's 9XA Waveform

CORE MATERIAL - Core from Standard 50 Hz transformer

(with ferrite core from Flyback transformer not working  )

 

Primary coil - 300 turns / 1 mm. copper wire Secondary coil - 300 turns / 1 mm. copper wire

(Primary and Secondary coils are wind bifilar (together with two wires) on one spool for best transfer  )

 

In this case - without Resonant chokes C1 and C2   

 

If the Primary coil terminals are "reversed", Step Charge not occur   

 

Using voltage to Primary coil: 24 Volts / 0.3 Amps (After 4 diode bridge Graetz, has a filtering capacitor 10000 uF).

 

(Note that at terminals of the primary winding is not connected diode).

 

Output Voltage to the Cell: +24 Vpp / 0.3 Amps High frequency - 1 kHz Gated frequency - 50 Hz

 

To Primary coil Stan Meyer not use 12 Volts 

 

Meyer uses 120 Volts !!!! See Figure 1-14 from Memo WFC 420:

This video shows capability of making an independent duty cycle with a 555.

 

Used two 1N4148 diodes, each one with a series 100k precision 10-turn potentiometer to allow full control of both ON and OFF time durations.

 

This output from 555 also is tied to a series of CD4017 to produce a gated pulse train.

This allows only 5 pulses per gate ON time due to clock synchronization.

Putting both 555/CD4017 waveform generators into 7408 AND logic gate.

This method only requires one H11D1 optocoupler.

 

Should be noted that clocks aren't synchronized when both have independent

555 used. Simply attached both CD4017 driver stages to one 555 to keep

synchronized clock.

This locks in a proportion of 10 however.

Below is an 9xa scope shot, showing how two independent 9XB style frequency generator's outputs were used to trigger two H11D1 optocouplers to produce a gated pulse train as shown in schematic.

 

In this setup, I had 555's produce a 100khz output to 4 CD4017 dividers.

 

This allowed a 10khz with 50/50 duty cycle to be achieved. LED is just for visual confirmation. If looking closely, you can see how the gating generator isn't synchronized with frequency generator.

 

This causes extra pulses to arise during gated ON times, also called "clock drift". 

NOTE: CD4017s were used in place of 7490s, they accomplish the same task with less wiring required.

9xa stanley a meyer.png

 

2nd setup had a modification where both signals from 555/CD4017 were fed into an 7408 AND logic gate. This produced the waveform seen below. In this instance, only 1 H11D1 optocoupler was required. 

9xa stanley a meyer 2.png

 

LED providing visual verification of pulse waveform.

9xa stanley a meyer 3.png

 

9XA does provide a 50% duty cycle pulse frequency with a 50% duty cycle gate frequency.

 

However, clock drifting is an issue if both waveform generators are used independently. If both decade counter stages are driven from same 555, a synchronized clock can be achieved. It is unclear if Stan synchronized with one 555. 

Original 50% duty cycle 9XA circuit using two independent 555/7490 frequency generator stages. Two optocouplers produce equivalent to an AND logic gate. Note that in this circuit, CD4017 decade counters were used in place of 7490. They serve the same function, but provide less wiring than 7490.

The Dave Lawton 9XA
An adjustable duty cycle dual 555 timer using a MOSFET to drive the VIC

basic circuit shown for historical reference 5khz
with overlayed 5 khz gate 

Source: http://quanthomme.free.fr/qhsuite/2011News/imagenews11/MeyerReplicatAnglais29pages.pdf

The Dave Lawton 9XA is a versatile pulse and gate generator with variable duty cycle on both 555 timers.

 

One design note that exists here, is that Pin 3 Output of timer 1 is used to provide Vcc power to Pin 4 on Timer 2. This means an inherent latency is always introduced by the 1st RC charge cycle to power up the 2nd timer. This would cause a partial leading pulse. Other than that issue, it's a pretty solid circuit.

Using a BUZ350 mosfetto pull down the B+ 12V through the cell and negative choke.

Dave Lawton Circuit.jpg

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