top of page

Stan Meyer EPG Gas to Power Electric Particle Generator 

The movement of charged particles is what electricity 
is at its most basic level. When a charged particle moves 
it produces a magnetic field.

 

The movement of said charge is quantified as current.
It flows just like moving water flows, which is why we use the same word. 

The force moving the charged particle is voltage.
 

They are different but related
aspects of the same thing. One makes the movement, the other IS the movement.

  Now consider the work with magnetic liquids in California where a drop of magnetic liquid  moving through
      a coil

3 .questions      Are the magnetic droplets acting like the neodymium battery train    ( homopolar magnet)
                         and if the  copper coil is  made into a circular loop and pickup coils  placed around the
                         "track"    ( as in the multitier epg) is useful power obtained from the permanently magnetized droplets
   
comments?

it is our belief that Stans Work has been keep secret and being slowly handed out to universities to keep them showing something

I deleted my post regard ElectroStatic Pulsing over Magnetic Pulsing.
After reviewing the thread below...
/showthread.php?tid=400&pid=4658#pid4658

I understand now that using magnetics is the ideal mode of use of the EPG, but requires the Argon/Cobalt/Nickel, magnetically polarized gas matrix.

I also, reviewed the "House meeting in New Zealand" video where Stan talks about the EPG and the magnetized gas.

I thought for sure that Stan talks about water propulsion on some video...
Maybe I just mis-understood what he was talking about...
...

Just reviewed the 3rd video of the "House meeting in New Zealand", where he covers the fact that when using laser light within the EPG (He does this to increase the mass of the atomic gas matrix), then, you no-longer need to motivate the gas, because it's the shock wave of the light itself that causes the electrical field generation (which is then caught by the pickup coils), as the electrons move away from the atomic nucleus, which then results is a higher magnetic energy in the gas. Thus, powering all of New Zealand with a single EPG, and entering the relm of OU.

Fascinating...

Now, back to the Magnetic Gas Lattice...

Argon (Lubricator, Non Electric, Non Magnetic)
Cobalt Ions
Nickel Ions

Cobalt Ions
Co^2+, Co^3+
Generate using HV to a pure Cobalt wire.

Nickel Ions
Ni^2+, Ni^3+
Generate using HV to a pure Nickel wire.

Iron Ions
Fe^2+, Fe^3+
Generate using HV to a pure Nickel wire.

Generate Cobalt and Nickel Ions using HV within an Argon filled chamber.
- Pass Gas Mixture through VIC and expose to laser energy.
- This destabilizes the Atomic Structures of the main elements in the Gas. So that that we can extract some electrons from them.
- Use electron extraction circuit to remove extra electrons. Now our atoms will be will to take on covalent bonds that they would normally never take on.
- Allow Unstable Gas to stabilize into the new Gas Matrix by making new covalent bonds.

Pump gases into EPG.
Test EPG for appropriate Magnetic Qualities of the Gas Lattice.
- Does pulsing it result in some energy output from the pickup coils?

Damn! That boy was Brilliant!
- Not just theory, but applied science.
- Mechanics, Electronics, Chemistry, Nuclear Physics...
- Amazing stuff!

-Dogs

Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator

The Purpose of these pages is for your to quickly see learn and advance further on replicating Stan Meyers  to Assist us getting this open source to market 

As you experiment share your picture and video on you tube 

As a Team we advance fast 

the dates on this  aprox 2005 

and than 2012 there was alot of work done

than recently 2016 , Years are passing we need people working on this 

Not all of the early EPG models of Stanley Meyer's devices used mechanical pumps to move
magnetic slurry or gas within the copper spiral cores. One model used linear magnetic drive
pumps to circulate the slurry/gases. The other was the magnetic spin EPG. The  six tier multiple
tier EPG  (aka "gega series" or (6Tmaggasepg) designed for home power generation also had
similar pumps. The seven tier system is now thought to have had a bottom tier with electronics
for control of the flow of the magnetic gas but not pickup coils

see attached 2 new images of the EPGs

1. Magnetic Spin EPG
2  Magnetic Drive EPG
3  Example Linear Mag Drive

Stanley A Meyer epg

INDEX TO WFC MEMO 418

COVER

COVER SHEET

PREFACE ELECTRICAL PARTICLE GENERATOR

VOLTAGE INTENSIFIER CIRCUIT AA …                                              … PAGE1

OPERATIONAL PARAMETERS ……                                                         PAGE 2

VARIABLE AMPLITUDE UNIPOLAR PULSE …                                    … PAGE 3

APPLIED VOLTAGE TO PLATES …                                                      … PAGE 4

LC VOLTAGE .…                                                                                      .. PAGE 5

VIC RESISTANCE DUAL-INLINE RLC NETWORK .                           ….. PAGE 6

VOLTAGE DYNAMIC .…                                                                        … PAGE 7

VOLTAGE CALCULATIONS …                                                             …. PAGE 8

ATOMIC INTERACTION TO VOLTAGE STIMULATION …                    … PAGE 9

VOLTAGE STIMULATION OF GAS ATOM …                                       .… PAGE 10

LASER INTERACTION ..…                                                                   … PAGE 11

GAS RESONANT CAVITY …                                                             …… PAGE 12

ELECTRON EXTRACTION PROCESS …                                          ……PAGE 13

ATOMIC BONDING OF UNLIKE ATOMS …                                       ……PAGE 14

MAGNETIC GAS LATTICE ……                                                            … PAGE 15

ELECTROMAGNETIC ENHANCEMENT ……                                       … PAGE 16

OPERATIONAL PARAMETERS ...…                                                      … PAGE 17

APPENDIX .

 

INDEX TO FIGURES FIGURE  1-1 VOLTAGE INTENSIFIER CIRCUIT (AA) PAGE 1 

FIGURE 1-2 LC CIRCUIT SCHEMATIC PAGE 2

FIGURE 9B VARIABLE AMPLITUDE UNIPOLAR PULSE VOLTAGE PAGE 3

VOLTAGE FREQUENCY SUPER IMPOSED ONTO A 50% DUTY CYCLE PULSE TRAIN

FIGURE 9BB. APPLIED VOLTAGE TO PLATES PAGE 4

 

FIGURE 1-3. VOLTAGE POTENTIAL DIFFERENCE PAGE 7

FIGURE 1-5. GAS DESTABILIZATION PROCESS PAGE 10

FIGURE 1-6. LED CLUSTER ARRAY PAGE 11

FIGURE 20 JX GAS RESONANT CAVITY PAGE 12

FIGURE 1-7. ELECTRON EXTRACTION CIRCUIT PAGE 13

FIGURE 1-8. COVALENT LINKUP OF UNLIKE ATOMS PAGE 14

FIGURE 1-9. MAGNETIZED GAS LATTICE PAGE 15

FIGURE 1-10. STIMULATING AN ELECTROMAGNETIC ATOM PAGE 16

FIGURE 1-11. ELECTRICAL PARTICLE GENERATOR PAGE 17 .

APPENDIX TO MEMO 418

 

LIST OF PHOTGRAPHS, FIGURES AND EXHIBITS

FIG. 26 EPG PRINCIPLE: ALLOWING A PERMANENTLY MAGNETIZED FLUID MEDIUM TO PASS THROUGH A PICKUP COIL FIG. 26 C: MULTI-TIER EPG ELECTRICAL GENERATOR

FIG. 27 EPG MECHANICAL DRIVE GAS ACCELERATOR

FIG. 28 EPG ELECTRICAL MAGNETIC GAS ACCELERATOR

FIG. 29 EPG PHOTON DRIVE GAS ACCELERATOR

FIG. 30 LINEAR GAS COIL ACCELERATOR

 

PHOTO EXHIBIT ZX: EPG MECHANICAL DRIVE ASSEMBLY

PHOTO EXHIBIT ZY: EPG ELECTROMAGNETIC PUMP ASSEMBLY

PHOTO EXHIBIT ZB: MAGNETIC SPIN GENERATOR

PHOTO EXHIBIT JX: GAS RESONANT CAVITY ASSEMBLY

 

MAKING MOLECULES*

POLAR MOLECULES*

METAL CONNECTIONS*

ELECTRONS: PARTICLES OF POWER*

ATTRACTION OF OPPOSITES*

 

NOTES: In the original document some pages were out of order and several figures inadvertently included twice.

The appropriate corrections were made in this edition with duplicate pages deleted and pages placed in the proper order.

 

*Also found in other Stan Meyer publications.

Stanley A Meyer EPGk.jpg
Stanley A Meyer EPG.jpg
Stanley A Meyer epg 1.jpg

Above is a photo of one of Stanley's EPG system.  

The EPG system or Electrical Particle Generator is basically a particle accelerator.

The EPG system is something that Stan was working on along with the Water Fuel Cell technology. It is suppose to be able to amplify the incoming signal/power to a much greater amperage / voltage. 

 

It seems that not many people know that Stan was even working on this system. I have been doing extensive research and development on this system.

 

Some Important Notes from alot of study 

 After Studying Searl Magnetic SEG 2 things seam very apparent and possible with Stand machines 

I call these Introvert (Stans Way)  and extrovert.( electrons from our side tube) 

Introvert

1a

The Stan Meyer Invert Method his stated method  of having a magnetic gas move through tube, 

could in fact be improved by have sensitive fer rite pickup inside the tube to make the voltage spikes, further enhancing stand magnetic stimulation of coils on outside of tube.  Some of this was thought of as Searl Using the Gathering and Damming of electron using ferit in his system.

1b

 it could also extract elections from gas inside tube which is not necessary;y same as Stan methods

similar to a Magnetic Flow Meter which would increase sensitivity of a could pickup or magnetic movement of a pick up coil, ( as there seam to be some debate about the copper preventing the magnetic gas making flux in pick up coils coil.

Extrovert

It seams pulsing gas with LED Laser will cause lithium oxygen and h2 to cool and become magnetic. 

Also  of Large Turbine use pure h2 to cool the machines ,gas flows through and cool the steel 

some run the gas through the stators. 

it is total possible that h2 or Magnetic gas compose could impart more electrons into the stator by attracting electron from air.

 

And Such the Epg Stans Unit will get vert cold when gas flowing as a rate of speed through it 

it will in fact attract electron from air these could be harvested just like searl did. As the Ionising and air will flow to centre of egp.  

Further pulsing with laser  will increase the effect 

Reference 

Scientists Create First Ever Magnetic Gas

By Stuart Fox September 18, 2009

https://www.popsci.com/scitech/article/2009-09/scientists-create-first-ever-magnetic-gas

Article Clipping 

For decades, scientists have debated whether or not gasses could display the same magnetic properties

as solids.  Now, thanks to some MIT scientists, they know the answer is a freezing cold yes.


MIT researchers have observed magnetism in an atomic gas of lithium cooled down to 150 millionths 
of a degree above absolute zero. This experiment represents a point of unification between condensed 
matter research and the field of atomic science and lasers, and could influence areas such as data storage 
and medical diagnostics.

 
To get the lithium gas so cold, the researchers trained an infrared laser beam on the gaseous cloud. 
Laser cooling is the primary method physicists use to lower gas temperatures to near absolute zero. 
The laser essentially stun the atoms, slowing them down, and thus lowering the temperature.
After initially growing, the cloud began to shrink. That shrinkage, combined with the speed of 
expansion after the laser turned off, indicated that the lithium atoms had become magnetic.
"It's very important from an overall theoretical point of view because it gives us an understanding 
of magnetism at its smallest possible scale," Scott Pritchard, an MIT professor, and one of 
the experiment leaders, told us.

Improving magnetic gas directions or coil sensitivity 
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Backup of Video 
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator

This is my Copper EPG i will be using for testing. The wire will be installed next, at a bare minimum there will be close to 2 miles of AWG22 magnet wire on this EPG.   

 

You can see my first attempt at the EPG using plastic at the end of this page.

Here is some of the progress i have made. The divider plates are installed, next i start the wire winding.

 

I'm building a wire winder (the wood in the background ) to help wind the 2+ miles of wire... thanks to YouTube user hawk491000 for the idea on the winder!

 

Update Photo Here: as of 2-8-12

 

Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stanley A Meyer Mechanical Pump EPG coil parameters

 

LENGTH

Method 1.
   
The diameter of the outermost EPG channel or loop can be estimated.at  about 17 inches
Therefore the outer circumference can be estimated at  17 x Pi inches
By dividing the circumference by the observed number of coils an estimated length of each coil can be made.

A further refinement in precision can be made by subtraction of  the total length  L occupied by coil spacers.
So in the case where you count, let's say as way of example, 59 coils and 60 coil end spacers, each winding is
1/59th of the circumference of 53.4 inches or calculated at about 0.905 inches long.

Method 2.
Because of  the high resolution photographs available, estimates of  a coil can be made directly.
Using a known measurement such as the outside diameter of tubing  ie.  0.500 inches
in conjunction with a screen distance tool in Photoshop(r) or another program such as
Screen Caliper(r) the length of the coil can be made.

THICKNESS
Since the outside diameter of the core channel is known,  an estimate of the thickness of depth of winding
may be obtained by using  photogrammetry to estimate the  thickness of the winding.
The total thickness or height of the wound coil is first measured. Then the core diameter is then subtracted.
the resulting  figure is then divided by two. This is the height or thickness of the winding around the core

So now we have what is call a winding window with height H and length L.
H TIMES L = A   the area of the winding window. Think of it a a cross-sectional view of
the coil windings with the ends of each wire being viewed.
Something like this:

IIOOOOOOOOOOOOII
IIOOOOOOOOOOOOII
IIOOOOOOOOOOOOII
representing 3 layers of wire with 12 wraps (the II symbolizing the  coil dividers)
3 layers of wire by 12 wires wide or 36 turns or wraps of wire around a bobbin

IIooooooooooooooooooII 
IIooooooooooooooooooII
HooooooooooooooooooII

In this exsmple, a thinner wire could be wound 18 times on the same length of bobbin.

NUMBER OF WINDS
Since the gauge of  the wire can be estimated with a good amount of precision
,the use of circle packing theory (see wiki) theory can be used to determine the
number of turns that can fit through this winding window( Area equals Height
times length.

One factor that helps, is that wires come in standard  thicknesses or diameters
For convenience the AWG  (American Wire Gauge) is used in electrical
and electronic work, Electrical wiring in the U.S. is often 10,12  or 14AWG
Electronic work is often  uses 18,22, or 30  AWG gauge wire
Whatever the reason the smaller the AWG number, the thicker or larger
the diameter of wire!!

The reason this helps in photogrammetry, is that the gauges are discrete values
Look at this table:

AWG      Diameter in inches           AWG     Diameter in Inches
10           .1019                                 20           .0320
12           .0808                                 22           .0253
14           .0641                                 24           .0201
16           .0508                                 26           .0159
18           .0403                                 28           .0126
                                                         30           .0101

The 16 gauge wire is about 25% thicker than 18 gauge
The 22 gauge wire is about 25% thicker than 24 gauge

Not to get too technical, but this is a logarithmic scale,  but the important  concept
is the PERCENTAGE OF DIFFERENCE BETWEEN GAUGES IS LARGE
in relation to the precision achievable in photogrammetry

This means for a given photogrammetric distance is it easier to pick out the exact
gauge of wire used because the precision of the that method is often less than 2 to 5%.

PACKING FRACTION

There is a branch of mathematics which describes how many circles of uniform
size can be drawn in a given area. It goes by several names but let's just call it
Circle Packing Theory. 

By determining the winding window size, the  appropriate circle packing  fraction can be used to
determine a close estimate of the number of windings per coil. In the previous example
cross-section of a coil, it represents one type of winding

Another type is hexagonal winding, with the layers arranged more like a honeycomb

And thirdly there is a random type of winding with lots of crossover and gaps

The hexagonal packing is the closest or most densest  method of winding coils
with a value of 0.906  or about 91% of the area occupied by wire with the
balance of the area being gaps between the wires

Square geometry winding with  each winding of wire directly on top the
layer below(  No offset)   has a value of 0.785  It is not at close or dense
a winding as hexagonal winding

A random wind often a more gaps but the packing ratio is highly dependent
on the size of the wire relative the length and width of the winding window

Consider for a moment two equally sized sheets of sandpaper.
One is coated coarse grade grit, the other coated coated with a fine grit used for
final sanding.  The  arrangement of the sand grains is random in both
cases but there are fewer grain of sand  on the coarse paper and
many more grains of  sand on the finer grit paper.
This is analogous to the number of random winding or wraps of wire in a given
cross sectional area on a bobbin. Intuitively very small wire gauges have a
higher  packing fraction than large. This is a difficult value to quantify

SO IN SOME CASES IT MAY BE POSSIBLE TO CALCULATE THE NUMBER OF TURNS
IN SOME CASES EMPIRCAL METHODS OR TEST WINDINGS MIGHT BE NECESSARY

As an example if the winding window is 1 square inch and the AWG  is 22, and the tighter hexagonal
winding factor is used(0.906) then    0.906 square inches of that window is occupied by the area of the wire..
The cross-sectional area of AWG 22 is 0.0005 inches.
0.906/divided by 0.0005 =approx 1800 turns
 
With precision or square winding a factor of 0.78 can be used resulting in an estimate of 1560 turns through
a 1 inch square window 

SUMMARY

Basically the application of the above method may be used to estimate  the number
of windings for an EPG coil by photogrammetric means in some cases
As search of empircal transformer design charts might be instructive for this third case

MISCELLANEOUS COMMENT
POWER OUTPUT DEPENDS ON  METHOD OF WIRING PICKUP COILS

It appears as though the mechanical drive epg was wired in parallel  lower voltage and  and a
higher amperage due to more coils
While the multitier EPG was higher voltage due to fewer coils and  many windings which required of multiple tiers
It also could be that the effective value of the flux in the mag-gas systems was lower that the higher density ferro fluids
which might explain the need to operate at  90 ips velocity

Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Russ Epg Build Attempt
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator

The Picture Below show the end game System Stan Made 

Top is a HCAT hho no flame can be turned to heat and water  video to right

heat can further go to boiler or steam turbine

Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator

A0201-01 Thanks sandia24 . Nice work

A0201-03  I was setting up the variable list for Problem 4 on the power output ad input see if this is reasonable--Q's on
                   clarification or suggestions to team drop box or pm if your are an ionizationx member
_________________________________________________ _________________________________________________ ________________________
MAIN DISCUSSION FOLLOWS BELOW

                          VARIABLE  LIST AND VALUE RANGE

                              VARIABLE                                                                                                                   VALUE             SOURCE/// REFERENCE
                                 
                              V1 = velocity of magnetic field movement per second                                                             50-90 ips          In 2019 Handout in Bremen Conference
                              N1 = number of twists per unit length of non-magnetic spiral divider per unit length               0.3 - 1.2          Estimate for  M4steel considering thickness
                                                                                                                                                                                                           and core diameter.
                              N3 = value of magnetic field strength                                                                                              ?                 TBD by calc. and type of EPG
                              F1 = value of the frequency pulsing alignment coils for dyne-axis of magnetic field               60 Hz/sec         Mains frequency in US  50 some parts of EU---  wiki
                              N4=  number of coils per tier                                                                                                       1 - 58               Don Gabel, photogrammetry and SEPG022,
                              N5 = number of turns in each coil                                                                                               200 - 12000      Estimates using packing fractions, winding depth,
                                                                                                                                                                                                             length photogrammetry as secondary verification
                                 P1 = effective cross-section winding factor: random, hexagonal or precision winding            0.78- 0.906      Wiki refs circle packing theory
                                 N6 = number of core sectors enclosed by pick-up coil                                                                3- 4                Don Gabel  images of various  EPG's   
                                 N7= number of tiers                                                                                                                      1  - 7                Birth of New Technology   1994 or 1995 ed
                                 A1= cross-sectional area of tubing uses in EPG tier ( in inches0                                               0.218- 0.254     The Copper Handbook

                                Power Input Variables
)
                                W1 = watts required for initiation of flow    ( Initial inertial load)                                 Rheological, mass density and volume consideration   TBC
                                W2= steady state power load for mag-media circulation                                                                          see appendix  TBC
                                W3 = dyne-axis load                                                                                                                                 see  appendix  TBC

                                Known values

                                N1  known
                                N2  known   
                                N3  calculation to be completed
                                N4  known   
                                N5 known
                                N6 known
                                F1 known
                                P1  known
                                V1 known
 
                       Stated  design output  was 220 VAC @ 300 amps       ( per seminar notes)
 
A0202-01    Let's try another attempt  at N3. At one of the conferences in 2019 ( SMC 2019 Bremen Ohio), it was proposed that the Transformer EMF                               
                     equation might be used in the mathematical model of the Meyer EPG series regarding the flux density problem.

                      Through photogrammetry the  maximum number of turns , number of coils, diameter and volume of the core
                      magnetized slurry/gas can be determined. Since the output power, velocity, and frequency are known with some precision

                      It may be possible to arrange the transformer EMF equation to obtain a Beta Max for the flux density!!
                                           
                      Another observation was made at the 2019 Bremen Conference that the larger the core volume, the lower value of the magnetic
                      saturation could be and still maintain the same power output. This is because the total power output for the device is dependent
                      in part  upon the total amount of flux present in the magnetic core.

A0202-02    Correct, if the other design factors such as the number of coils, number of winds and same velocity of the magnetic
                      gas or slurry are maintained, the limitations of the maximum level of  magnetic saturation of the EFH series ferrofluids
                      can be mitigated.  Basically scale up the volume and the magnetic saturation can be lower and still provide the
                      design power output. While the 400 Hz mil-spec converters are still an option for the magnetic drives I think
                      you may want to just keep it simple so that operating frequency matches the 50 or 60 Hz standards for output for
                      residential use.               
     
A0202-03      thnx to thorzpwr 

A0203=01      ok, you forgot to hide your location ,metadata  I'll fix it zo the mib's don't get ya....lol

A0205-01       Since output data is only available for the 6Tmaggas EPG and for the velocity of the magnetic medium, 'I think a problem approach might be
                        to determine the flux in the 6 multi-tier system as if EFH-1 was present and then scale down to the magnetic pump system  and volume of EFH-1
                        at the stated velocity and use a ,calculated flux density to determine output characteristics of the  magnetic pump  device in terms of output.
                        The sizing of the bus bars, the parallel  arrangement of the pick-up coils and the  breakdown voltage of the insulation might put some upper
                        limits to how it was being operated and limits to the possible voltagexs and amps produced

                        Design output  220 VAC at 300 amps  =  66,000 watts

A020601       So now let's assign values to some of the variables
---------------------------------------------------------------------------------------------------------------
   
   Cross sectional area is calculated as follows:

                  1. determine the diameter of the tubing    0.5" obtained by photogrammetry  0.5 outside diameter
                     also confirmed by actual measurement by Don Gabel . (see notebook photos)

                  2. determine the range of. possible internal diameters     Common types of pipe K L and M that have the
                      same outside diameter but thickness of inner diameter and wall thickness vary.
                      Stan Meyer may have used  pre-coiled air conditioning or water supply tubing. for ease of construction.

A very useful free reference is The Copper Tubing Handbook fermi which provides the specifications and measurements
for copper tubing and pipe.

You can google The Copper Tubing Handbook for the pdf  or just click on this link:

https://pbar.fnal.gov/organizationalchart/Leveling/2004%20water%20cage%20work/Cutubehandbook.pdf

One observation concerning the publicly available EPG images, it that there do not seem to be joints on the spiralled sections
themselves although the connecting copper pipes to the pumps or other means of moving the slurry or gas are straight. 
I believe Stan Meyerswas practical and tried to keep things simple, so I believe he just used piping that was already coiled when purchased.

So, now let's use the above reference to get a range of possible values for the cross-sections of the copper tubing and pipes
commonly available.. Copper pipe has three basic wall thicknesses: Type K, Type L and Type  M  So even though the outside
diameter may remain the same, a THICKER wall means a SMALLER cross-section inside the tube

So here's the values of cross-sectional area for different copper tubing and pipe in square inches:

  Type K    0.218   Type L  0.233   Type M  0.254   So the cross-sectional area for coiled copper pipe  is between 0.218 and 0.254 square inches

Since the 6 tier system is not available for examination at this time, there is a degree of  imprecision for the cross-sectional area value
Because the cross-sectional area is used in volume calculations and in the calculation of total magnetic flux for these systems, the estimates
of system performance depend upon the type of tubing used in the construction
--------------------------------------------------------------------------------------------------------------------------------------------------------
Length of tubing carrying magnetic slurry/gas

Since the EPGs are of a general circular design, the formula    C = D x Pi  or stated -- Circumference of a circle equals the
diameter of the circle multiplied by Pi    (approximately 3.1416)

Now, if you are trying to find the total length of tubing  used in an EPG which is a spiral, for example(In this case exactly
3 loops, then thinkof this as 3 circles each with a different diameter and circumference
The outer loop is longer than the middle loop which is in turn larger the the innermost ring of loop.

So roughly speaking, let's say you had an EPG like the Magnetic Drive (Red Pump) System and that by examination
or photogrammetryand it was determined that diameter was 17 inches.

If you are using 1/2  inch tubing in the construction, what would be the diameter of the middle loop?

The radius  of the middle loop is moved in by 1/2 inch because of the width of the outer loop or to put it another
way, the diameter of the middle loop would be 16 inches measured across its outside  By a similar reasoning, the innermost  loop
is  or about 15 inches in diameter.

So the length the spiral is approximately ( 15 + 16 + 17) times Pi.   Now Stan Meyer for reasons of type of pump used (B-500 had input and output
connections at right angles)then some portions of the spiral had four loops instead of three so adjustments will have to be
made for this added length.   The total length of is important because this is used in the calculations
for the Volume of gas or ferrofluid being used  and also in the calculations for inductance and the number windings for the
coils as well as the length of wire required for making the  windings
--------------------------------------------------------------------------------------------------------------------------------------------------------
Coils and length of wire need for project and per coil
 
                                                                                                                                         End View                "Tube" length

A formula for a single wind around a single circular  core                                                    O                    diameter of wire times 1

1.A formula for multiple winds around a singular tubular core  of length L               O                    diameter of wire  x N  number of windings or wraps

2 A formula for multiple winds around  two adjacent tubular cores of length L        OO                  diameter of wire  x N  number of windings or wraps

.3 A formula for multiple winds around three adjacent tubular cores of length     OOO                    diameter of wire  x N number of windings  or wraps
   
4 General Formula for multiple winds around  multiple tubes                                         OOOO...               diameter of wire  x N number of windings or wraps 

So the length of the tube determines the total number of wraps possible independent of the number of adjacent tubes
(close wraps  no spacing between wraps on tube

Formula  Length of tube (think inductor core) equals the number of wraps times the width or diameter of the wire  L= N times W or    L/ divided by W  = N
ay of determining the number of wraps  that can fit on a given length of  tube or core

-------------------------------------------------------------------------------------------------------------------------------------------------------
Now for the fun part determining the Length of Wire   needed for one wrap around multiple adjacent cores


Formula for 1 core                                 O           L   = Diameter of core times Pi

Formula for 2 adjacent cores              OO           L = (Diameter of core times Pi)  PLUS  2D  <---    for the wire that bridges the "notch" between the adjacent tubes  (top and bottom)

Formula foe 3 adjacent cores            OOO          L = (Diameter of  core times Pi)  PLUS  4D  <---   to account for the length needed to bridge 2 notches between the adjacent tubes (top and bottom)

Formula for 4 adjacent cores          OOOO          L = Diameter of core times Pi)    PLUS  6D <---    To account for the length  needed to bridge 3 notches between the adjacent tubes (top and bottom)


In summary, we now can calculate the length of a single wrap of wire around multiple adjacent cores and if we multiply that by the number of wraps  or turns that can be wrapped on a given  linear length of core
     it is helpfun in deciding amount of wire needed

General Formula for Single Layer 1 wrap or turn around multiple adjacent tubes

L length equals ( Diameter of core or tube) plus ( ( N or number of cores minus 1) times 2)

So now is possible to calculate the number of winds or wraps (single layer0 around an EPG if we know the diameter of the outermost core of a spiralled EPG, the number of "loops" in the spiral, the outside
diameter of the core tubing and the gauge, diameter or width of the wire used to  wrap the core
t
So lets give a quick try for the multitier 6TmaggasEPG

1 tier is about 17 inches in diameter.   Since the line drawing of the 7 tier system  and photographs show the drain/connecting tubes are 180 degrees apart so its possible to keep the number of loops for a tier to
be 2.5 3.5 or 4.5 loops or if the connecting tubes are all  exact  integers of loops the connecting tube could be all on one side.  Or the direction of the flow could be counterclockwise  one one tier and clockwise in the other tier. So based on the line drawing lets say that that each tier has 3.5 loops

Length of core for 1 tier       [ ( 15+16+17)]times Pi ]  plus( 1/2 times 14 times Pi) = 150.78 + 29.99 =  172.77 inches   6 tiers 1036 inches
172.77 inches  divided by .025 inches per turn  (22 gauge wire by photogrammetry  = maximum 6910 turns per tier
6 times 6910  = 41,460 turns  or if you use exactly 3 loops per tier    150.78 times 6 = 904  inches  904 divided by  0.025 = about 36,191 turns  6 tiers 906 inches

Image a n inductor with between 36 and 41 thousand turns of wire and  between  75 and 86 feet long !! depending on method of construction
 
Design parameters                                                                                                                                   Metric

The design output is 220 volts at 300 amp draw  66,000 watts  (Watts)           
(W) 220 times 300 amp draw   = 66,000 watts

The cross-sectional area of the core is between 0.218 and  0.254 square in
or (A)  =  1.406 to 1.634  sq cm or 0.0001406 0.0001634  square meters

F (frequency) is  60 cycle/ second AC
                                                                         
V (voltage) is 220 volts AC output
                                     
K Constant  = 4.44
                                                                                                           
Solving of Bm =BetaMax

Basic equation

  V   =  voltage
  F  = supply frequency
  N = number of turns
  A = cross sectional area in square meters
  B = peak  magnetic flux density in Weber / meter squared or T tesla
  K = 4.44
 
   V = 4.44  x F x N x A x B or rearranging this

    B =   divided by( 4.44    x  f x  N    x   a )           

  so let's try plugging in a few figures for a six tier device



         V = voltage       220 VAC
         F=  60 hertz per second in the US
         N= 11,873
         A =  0. 000468  sq m area         3 channels of pipe  x 0.242 sq inches divided by conversion factor 1550  =  000468 square metres
         4.44 = constant
                      Bmax  =   220/ 1480  or      0.1486  Wb/M squared  or Tesla     for the 5/8" six tier system4.44 times F*N * BetaMax * A
 
Rearranging: BetaMax  =  V  divided by ( 4.44 x F x  N x  A)
       
                      220 divided by(  4.44 times  60 Hz/sec  frequency times 36191 x .218 A sq inches   =  .0001046

now to work on units. with a different diameter..
              V = 220 VAC...
              F = supply frequency
              N = number of turns 
              A = cross sectional area in square meters
              B = peak  magnetic flux density in Wb / meter squared or T tesla
              K = constant

                     V = 4.44  x F  x N  x A x Bmax,   or rearranging this

                      Bmax  =        V divided by( 4.44 * F *  N * A )           

  so let's try plugging in a few figures for a six tier device with a  5/8"  OD copper spiral


V = voltage       220 VAC
F= 60 hertz per second in the U
N = 11,87
A =   0. 000468  sq m area                                       3 channels of pipe  x 0.242 sq inches divided by conversion factor 1550  =  000468 square metres
B = BetaMax
K = 4.44   ( constant )

Thus Bmax  =   220/ 1480  or      0.1486  Wb/M squared  or Tesla     for the 5/8" six tier system

      [    b]Next Topic Multiple layer coils

In terms of construction if the cross sectional area is changed because of using a larger diameter tubing but keeping N number of turns the same and the length of the
spiralled coils is the same and other factors the same (same desired output) t because the output is related to the amount of flux of the core, the larger the core in terms
of cross section (and volume) means that a lower Beta value in the core of  the upsized EPG can  still result in the desired power output.  Basically if more power is
needed the large core can allow for a lower amount of flux to be used if there is a limit to magnetic saturation for the slurry or mag-gas matrix.

This is more useful to calculate wire requirements for the Mechanical Pump EPG .
Since it's possible to estimate the thickness of the coils, the length of the original coils,
the gauge of the wire and velocity of the ferrofluid 50 ips  and using a flux value estimate
a power output for the Mechanical Pump EPG.

Stanley A Meyer Useful Reference Books for EPG Design

« on: February 16, 2021, 16:58:44 pm »

 Inductance Calculations by Frederick W Grover
Classical Electromagnetism by Jerrold Franklin
Solved Problems in Classical Magnetism by Jerrold Franklin
all published at one time or another by   www.doverpublications.com

inductor calculator

 https://www.allaboutcircuits.com/tools/coil-inductance-calculator/

link to EFH-1 permeability

https://www.elektr.polsl.pl/images/elektryka/229/229-2.pdf

p 18   mu = 1.789 for ferrotec EPH1

Stanley A Meyer Negative Viscosity of Ferrofluids and EPG Design Considerations

« on: February 21, 2021, 14:38:29 pm »

The ability of ferrofluids to exhibit negative viscosities has implications for the selection of ferrofluids
used in the Meyer mechanical drive EPG as well as the  linear magnetic drive systems.

Although there are viscosity measurements provided by the manufacturer of the  EFH series ferrofluids and
it was postulated that the selection of the  EFH -1 over the then available EFH- 4 which had a greater viscosity
(but also a higher percent of magnetite and magnetic susceptibility) was primarily given a greater importance
then magnetic susceptibility as a design factor.

If ferrofluids have a lower viscosity under an alternating magnetic field this observation might allow the use of
higher viscosity ferrofluids than those used by Stanley A Meyer

A possible effect of the alignment coils in the mechanical pump EPG design may be to reduce the viscosity
of the ferrofluid before and after pumping. There are also implications for the velocity of gaseous magnetic
matrices in the multi-tier series of EPG which used linear magnetic pumps.

see attachment  or internet search for "negative viscosity of ferrofluid under alternating magnetic field"

TY  - JOUR

AU  - Shliomis, Mark

AU  - Morozov, Konstantin

PY  - 1994/08/01

SP  - 2855

EP  - 2861

T1  - Negative viscosity of ferrofluid under alternating magnetic field

VL  - 6

DO  - 10.1063/1.868108

JO  - Physics of Fluids - PHYS FLUIDS

ER  -

Stanley A Meyer EPG and Manufacture of Paramagnetic Slurries

« on: March 04, 2021, 01:51:44 am »  

A previous post detailed a possible process for the manufacture of  ferro argonide dust or powders to be circulated in
the electrical particle generated with the circular or spiraled channel of the devices

Ferro-Tec, a major supplier of ferrofluids to the world sells dry magnetite powders. It might be possible to mix these with
low viscosity carrier fluids perhaps a thin silane ,or mineral oil to create a slurry with high magnetic saturation
with viscosity appropriate for the mechanical pump and linear magnetic drive series of  EPGs

The new polyethylene glycol  PEG ferrofluids have very low viscosity but are aqueous in nature
Other dry powders are available with various  for coatings which might allow a variety of optimum liquid carriers.

Not all of the early EPG models of Stanley Meyer's devices used mechanical pumps to move
magnetic slurry or gas within the copper spiral cores. One model used linear magnetic drive
pumps to circulate the slurry/gases. The other was the magnetic spin EPG. The  six tier multiple
tier EPG  (aka "gega series" or (6Tmaggasepg) designed for home power generation also had
similar pumps. The seven tier system is now thought to have had a bottom tier with electronics
for control of the flow of the magnetic gas but not pickup coils. The library group has located
documentation by people who either saw the device or saw an arkived video recording of it
powering a row of incandescent bulbs

see attached 3 new images of the EPGs and  a linear pump cross-section

Photo Label                                       Source                             
1  Mechanical Drive EPG                  Stanley Meyer Arkive (c)
2  Magnetic Drive EPG                     Stanley Meyer Arkive (c)
3  Example Linear Mag Drive           Wiki

 

Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator
Stan-Meyer-EPG-Gas-to-Power-Electric-Particle-Generator

The 7Tier maggas EPG had a plywood base and row of 6 incandescent. bulbs.


After Stan's passing  this was not present in the inventory that QCI ultimately acquired
Also it was not present at the L3 unit when the TOP assessment was made.

Stanley A Meyer 6 Candesent Bulbs.jpg
But Which Gas?
I think helium is a good choice. I looked up Helium 3 which is used with MRI machines to scan the inside of lung passage ways. He3 has magnetic properties that can be viewed on the MRI machine.
ote the similarity to what Haisch and Moddel did with a Casimir cavity and a noble gas...

https://ocw.mit.edu/courses/physics/8-05-quantum-physics-ii-fall-2013/lecture-notes/MIT8_05F13_Chap_07.pdf#page=13

 
BACK UP DOCUMENT 

One can use a voltage gradient to separate the two states of ammonia (N-Up, N-Down), pump the N-Up into a resonant cavity, then feed that resonant cavity with 23.87 GHz to force the N-Up ammonia molecules to relax to their ground state, giving off microwave photons in the process. The energy given off is in resonance with the 23.87 GHz pump. https://www.kenwood.com/i/products/info/amateur/ts50s.html

Since ammonia will naturally be a mixture of N-Up and N-Down, given time, the 'relaxed' ammonia when released from the resonant cavity will regain the normal proportion of N-Up and N-Down due to random thermal fluctuations forcing some of the ammonia molecules back into an N-Up state. Rinse and repeat.

This is the basis for a MASER (Microwave Amplification by Stimulated Emission of Radiation).

Could this have been what Stan Meyer was doing with his "magnetic gas", using the microwaves to dissociate water?
Fascinating!

I seem to remember that the exhaust of his buggy was reported as foul smelling, ammonia. Would he only exhaust it after an extraction cycle? Is there enough to be extracted? From what I understood before, the water (or it's components) from the fuel tank was somehow made to react with intake air, the nitrogen finding it's way to the NH3 ammonia exhaust fumes. If there is some serious energy left in the form of ammonia obtained this way, one can expect Stan to have extracted it.

Stan's work is very compelling, way above my comprehension. I hope someone figures it out, or takes a part of the work and gets it to stand by itself.
 US2780069 Precession.pdf -
 
Back up Doc
stanley meyer epg fuser gas maker magnet
stanley meyer epg fuser gas maker magnet
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley A Meyer EPG and Stable Room Temperature Magnetic Liquid Compounds

« on: March 21, 2021, 16:12:07 pm 

Stanley A Meyer is said to have designed EPG devices that circulated magnetic gases and liquids
To date, the creation of magnetic gas matrices has proven challenging to the various EPG researchers
and working groups .  While the  EPG design and concepts have been fairly well elucidated by Miner,
Greis, and Hauswirth, et al,' the use of stable magnetic compounds that are single entity liquids may open
up a novel method of electrical generation in the liquid EPG systems.

"Hamaguchi et al. observed magnetic ionic liquids by introducing FeCl4 to the anion part to form
1-butyl-3-methylimidazolium tetrachloroferrate, (Bmim)FeCl4.1,2) A magnetic fluid is a liquid with
magnetic properties. However, a conventional magnetic fluid contains volatile solvents. It causes a
change of viscosity and phase separation by cohesion/precipitation. On the other hand, the magnetic
ionic liquid is a highly stable and non-volatile liquid. Moreover, this magnetic ionic
liquid responds to a magnetic field by a permanent magnet, because it shows large magnetic
susceptibility at room temperature."

The magnetic susceptibility can be further increased by the addition of  nano-particles in the 10 to 100 size range
that are used in the ferrofluid technologies. In this situation  the carrier fluid has a magnetic component to it as
well as the particles in suspension.   The kerosene based ferro-fluids such EFH and EMG series Ferrotech(r)
would  be good choice for the Series 6 trial    The ionic/aqueous ferrofluids will be addressed in Series 7 trials

source diagrams and chemicals
https://www.tcichemicals.com/US/en/c/12839�

Magnetic Ionic Liquids

 Ionic liquids consist of only ionic components, having high ionic conductivity suitable for a liquid electrolyte. An electrolyte for a secondary battery requires not only high ionic conductivity but also non-volatility, heat-resistivity, non-inflammability, and non-corrosiveness. Ionic liquids cover these conditions. The cationic component of ionic liquid involves alkyl-substituted imidazolium, pyrrolidinium, piperidinium, ammonium, phosphonium, sulfonium and the anionic component involves halide, BF4, PF6, thiocyanate, and di(sulfonyl)imide. Chemical modifications of the cation and anion control melting point, viscosity and ionic conductivity. Hamaguchi et al. observed magnetic ionic liquids by introducing FeCl4 to the anion part to form 1-butyl-3-methylimidazolium tetrachloroferrate, (Bmim)FeCl4.1,2) A magnetic fluid is a liquid with magnetic properties. However, a conventional magnetic fluid contains volatile solvents. It causes a change of viscosity and phase separation by cohesion/precipitation. On the other hand, the magnetic ionic liquid is a highly stable and non-volatile liquid. Moreover, this magnetic ionic liquid responds to a magnetic field by a permanent magnet, because it shows large magnetic susceptibility at room temperature.

Stanley A Meyer EPG Chemical structure.p
Stanley A Meyer EPG magnetic compound li
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
US4613304-2 Stanley Meyer Electrical Pow
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanley A Meyer EPG  Magnet
Stanley A Meyer EPG  Magnet
Stanley A Meyer EPG  Magnet
Stanley A Meyer EPG  Magnet
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanley A Meyer EPG Magnetic Gas  (1).jp
Stanley A Meyer EPG Magnetic Gas  (2).jp

Attached is a representation of a Nickel Argonide (NiAr) gas matrix based on
the FeAr gas matrix shown in the Meyer New Zealand video and also the CoAr


it's interesting that Meyer shows (in a 2d representation) iron and argon sharing 4 electrons
The argon +1 ion can be achieved by high voltage sparks in a rarified argon gas
Additional "laser" excitement might allow more atoms in the outer shell to
leave the outer ring especially if in the presence of an electron extraction circuit

A  number of factors make it easier to extract the electrons from the transitional
metals used partly because of a lower ionization energy due to the greater distance
of the outer electron shell from the positive nucleus and that there\are more available
electrons to be pulled off. I suspect that in a 3d  configuration of the FeAr matrix
is similar to the cubic orthography of NaCl.   However the stability of the FeAr matrix
may be enhanced by the stabilizing forces due to the paramagnetism of FE Co or Ni
This is in addition to the ionic bonding force qq

The gas may be more of a nanocluster light enough to be carried by the Argon
carrier gas  analogous to sand in water or quicksand   3 to 20 FeAr per clump

Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanley Meyer Electrical Power Generator
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g
Stanleu Meyer Epg Electrical power gas g

EPG Power System 

Gas Transformer

Could the very first patent Stan Meyer ever submitted be the key to understanding his subsequent water fuel related inventions? Meyer titled this patent “Electrical Particle Generator”, a name which would not attract too much attention to itself.

 

Furthermore, Meyer never patented this device in the USA. He only patented it in the Canadian patent office which had much less traffic at the time. Did Meyer want to place this invention into the public record while, in some sense, keeping the “secret” hidden in plain sight.

 

The patent for this invention can be downloaded here.

Stan referred to this device in his subsequent patents as the “Unipolar Pulsing Core Transformer”, a name which anyone who has spent time on Meyer’s work will recognize.

But what exactly is this device?

Stanley A Meyer EPG electrical power

Here is how it operates:

Stanley A Meyer EPG electrical power

How can one get magnetized gas into the core? Here is the approach that I took:

Stanley A Meyer EPG electrical power
Stanley A Meyer EPG electrical power

Here are pictures of my first implementation of the device.

Stanley A Meyer EPG electrical power

When one adds primary and secondary windings on to this core and then energizes the primary with a flow of charge, a magnetic field is produced.

 

The magnetized oxyhydrogen gas particles which have been added into the core are attracted to the S end of the primary magnetic field and repelled by the N end of the same field.

 

The effect is accelerative upon the particles. As the gas flow velocity increases, the particles move ever faster around the core.

 

The faster the particles are accelerated, the greater the charge amplitude induced on the secondary side as the “tiny magnets” pass in a fluid aggregate over these windings.

Stanley A Meyer EPG electrical power

Note that PVC or flexible vinyl tubing works better for fluid core construction then copper or aluminum.

 

The first core I made (shown above) was made from copper, but in subsequent builds I used PVC.

 

Copper and aluminum have a dampening effect upon magnetic fields and so are a poor choice for use in the core.

In many of Meyer’s patents (such as seen below), he refers to a Unipolar Magnetic Field Coupling and uses his “Loop” symbol notation.

Stanley A Meyer EPG electrical power

Here Meyer refers to the gas filled “pulsing core”, and it’s “unipolar magnetic field coupling” action.

 

He always used these cryptic circles on his block diagrams to indicate the effect. Of course, he never disclosed this notation explicitly.

 

I think this notation represents the magnetic fields of tiny magnetized gas ions, which when accelerated by the primary coil on the gas core, moves across the secondary coil.

Stanley A Meyer EPG electrical power

A0201-03  I was setting up the variable list for Problem 4 on the power output ad input see if this is reasonable--Q's on
                   clarification or suggestions to team drop box or pm if your are an ionizationx member
_________________________________________________ _________________________________________________ ________________________
MAIN DISCUSSION FOLLOWS BELOW

                                  VARIABLE  LIST AND VALUE RANGE

                                 VARIABLE                                                                                                                   VALUE             SOURCE/// REFERENCE
                                 
                                 V1 = velocity of magnetic field movement per second                                                  50-90 ips          In 2019 Handout in Bremen Conference
                                 N1= number of twists per unit length of non-magnetic spiral divider per unit length   .3 - 1.2              Estimate for  M4 considering thickness and core diameter
                                 N3= value of magnetic field strength                                                                                ?                     TBD by calc. and type of EPG
                                 F1 = value of the frequency pulsing alignment coils for dyne-axis of magnetic field   60 Hz/sec         Mains frequency in US  50 some parts of EU---  wiki
                                 N4= number of coils per tier                                                                                           1 - 58               Don Gabel, photogrammetry and SM EPG022,
                                 N5 =number of turns in each coil                                                                                   200 - 12000      Estimates using packing fractions, winding depth and length and
                                                                                                                                                                                                   photogrammetry
                                 P1 = effective cross-section winding factor: random, hexagonal or precision winding  0.78- 0.906      Wiki refs circle packing theory
                                 N6 = number of core sectors enclosed by pick-up coil                                                   3- 4                   Don Gabel  images of various  EPG's   
                                 N7= number of tiers                                                                                                        1  - 7                 Birth  of New Technology   1994 or 1995 editions
                                 A1= cross-sectional area of tubing uses in EPG tier ( in inches0                                   0.218- 0.254     The Copper Handbook

                                Power Input Variables
)
                                W1 = watts required for initiation of flow    ( Initial inertial load)                                 Rheological, mass density and volume consideration   TBC
                                W2= steady state power load for mag-media circulation                                                                          see appendix  TBC
                                W3 = dyne-axis load                                                                                                                                 see  appendix  TBC

                                Known values

                                N1  known
                                N2  known   
                                N3  calculation to be completed
                                N4  known   
                                N5 known
                                N6 known
                                F1 known
                                P1  known
                                V1 known
 
                       Stated  design output  was 220 VAC @ 300 amps                                                                                                                        seminar notes
 
A0202-01    Let's try another attempt  at N3. At one of the conferences in 2019, it was proposed that the Transformer EMF                                    SMC 2019 Bremen Oh
                     equation might be used in the mathematical model of the Meyer EPG series regarding the flux density problem
                     Through photogrammetry the  maximum number of turns , number of coils, diameter and volume of the core
                      magnetized slurry/gas can be determined. Since the output power, velocity, and frequency are known with some precision,
                      it may be possible to arrange the transformer EMF equation to obtain a Beta Max for the flux density!!
                                           
                      Another observation was made at the 2019 Bremen Conference that the larger the core volume, the lower value of the magnetic
                      saturation could be and still maintain the same power output. This is because the total power output for the device is dependent
                      in part  upon the total amount of flux present in the magnetic core.

A0202-02    Correct, if the other design factors such as the number of coils, number of winds and same velocity of the magnetic
                      gas or slurry are maintained, the limitations of the maximum level of  magnetic saturation of the EFH series ferrofluids
                      can be mitigated.  Basically scale up the volume and the magnetic saturation can be lower and still provide the
                      design power output. While the 400 Hz mil-spec converters are still an option for the magnetic drives I think
                      you may want to just keep it simple so that operating frequency matches the 50 or 60 Hz standards for output for
                      residential use.               
     
A0202-03      thnx to thorzpwr 

A0203=01      ok, you forgot to hide your location ,metadata  i'll fix it zo the mib's don't get ya......lol

A0205-01       Since output data is only available for the 6Tmaggas EPG and for the velocity of the magnetic medium, 'I think a problem approach might be
                        to determine the flux in the 6 multi-tier system as if EFH-1 was present and then scale down to the magnetic pump system  and volume of EFH-1
                        at the stated velocity and use a ,calculated flux density to determine output characteristics of the  magnetic pump  device in terms of output.
                        The sizing of the bus bars, the parallel  arrangement of the pick-up coils and the  breakdown voltage of the insulation might put some upper
                        limits to how it was being operated and limits to the possible voltagexs and amps produced

                        Design output  220 VAC at 300 amps  =  66,000 watts

A020601       So now let's assign values to some of the variables
---------------------------------------------------------------------------------------------------------------
   
   Cross sectional area is calculated as follows:
                  1. determine the diameter of the tubing    0.5" obtaiined by
photogrammetry  0.5 outside diameter also by Don Gabel measurement
                  2. determine the range of. possible internal diameters      common types of pipe  K L and M same outside diameter but thickness
of wall may have used coiled tubing.

A very useful free reference is The Copper Tubing Handbook fermi which provides the specifications and measurements for copper tubing and pipe
book

You can google The Copper Tubing Handbook for the pdf  or just click on this link:

https://pbar.fnal.gov/organizationalchart/Leveling/2004%20water%20cage%20work/Cutubehandbook.pdf

One observation concerning the publicly available EPG images, it that there do not seem to be joints on the spiralled sections themselves although the connecting
copper pipes to the pumps or other means of moving the slurry or gas are straight.  I believe Stan Meyers was practical and tried to keep things simple, so I believe
he just used
piping that was already coiled when purchased.

So, now let's use the above reference to get a range of possible values for the cross-sections of the copper tubing and pipes commonly available.. Copper pipe has three
basic wall thicknesses: Type K, Type L and Type  M  So even though the outside diameter may remain the same, a THICKER wall means a SMALLER cross-section inside the tube

So here's the values of cross-sectional area for different copper tubing and pipe in square inches:

  Type K    0.218   Type L  0.233   Type M  0.254    So the cross-sectional area for coiled copper pipe  is between 0.218 and 0.254 square inches

Since the 6 tier system is not available for examination at this time, there is a degree of  imprecision for the cross-sectional area value
Because the cross-sectional area is used in volume calculations and in the calculation of total magnetic flux for these systems, the estimates
of system performance depend upon the type of tubing used in the construction
--------------------------------------------------------------------------------------------------------------------------------------------------------
Length of tubing carrying magnetic slurry/gas


Since the EPGs are of a general circular design, the formula    C = D x Pi  or stated -- Circumference of a circle equals the diameter of the circle multiplied by Pi    (approx 3.1416)

Now, if you are trying to find the total length of tubing  used in an EPG which is a spiral, for example(In this case exactly 3 loops, then think of this as 3 circles each with a different circumference
The outer loop is longer than the middle loop which is in turn larger the the innermost ring of loop.

So roughly speaking, let's say you had an EPG like the Magnetic Drive (Red Pump) System and that by examination or photogrammetry and it was determined that diameter was 17 inches
If you are using 1/2 inch tubing in the construction, what would be the diameter of the middle loop?

The radius  of the middle loop is moved in by 1/2 inch because of the width of the outer loop or to put it another way the diameter of the middle loop would be 16 inches measured across its outside  By a similar means of reasoning, the innermost  loop is  or about 15 inches in diameter.

So the length the spiral is approximately ( 15 + 16 + 17) times Pi.   Now Stan Meyer for reasons of type of pump used, has some portions of the spiral having four loops instead
of three so adjustments will have to be made for this added length.   The total length of is important because this is used in some on the calculations for the Volume of gas or
ferrofluid being used  and also in the calculations for inductance and the number windings for the coils as well as the length of wire required for making the  winding.
--------------------------------------------------------------------------------------------------------------------------------------------------------
Coils and length of wire need for project and per coil

                                                                                                                                    End View                "Tube" length
    A formula for a single wind around a single circular  core                                            O                    diameter of wire times 1

1.A formula for multiple winds around a singular tubular core  of length L           O                      diameter of wire  times N  number of windings or wraps

2 A formula for multiple winds around  two adjacent tubular cores of length L     OO                    diameter of wire times N number of windings or wraps

.3 A formula for multiple winds around three adjacent tubular cores of length      OOO                 diameter of wire times N number of windings  or wraps

4 General Formula for multiple winds around  multiple tubes                                         OOOO...             diameter of wire times N number of windings or wraps 

So the length of the tube determines the total number of wraps possible independent of the number of adjacent tubes (close wraps  no spacing between wraps on tube

Formula  Length of tube (think inductor core) equals the number of wraps times the width or diameter of the wire  L= N times W or    L/ divided by W  = N
ay of determining the number of wraps  that can fit on a given length of  tube or core

-------------------------------------------------------------------------------------------------------------------------------------------------------
Now for the fun part determining the Length of Wire   needed for one wrap around multiple adjacent cores


Formula for 1 core                                 O           L   = Diameter of core times Pi

Formula for 2 adjacent cores              OO           L = (Diameter of core times Pi)  PLUS  2D  <---    for the wire that bridges the "notch" between the adjacent tubes  (top and bottom)

Formula foe 3 adjacent cores            OOO          L = (Diameter of  core times Pi)  PLUS  4D  <---   to account for the length needed to bridge 2 notches between the adjacent tubes (top and bottom)

Formula for 4 adjacent cores          OOOO          L = Diameter of core times Pi)    PLUS  6D <---    To account for the length  needed to bridge 3 notches between the adjacent tubes (top and bottom)


In summary, we now can calculate the length of a single wrap of wire around multiple adjacent cores and if we multiply that by the number of wraps  or turns that can be wrapped on a given  linear length of core
     it is helpfun in deciding amount of wire needed

General Formula for Single Layer 1 wrap or turn around multiple adjacent tubes

 L length equals ( Diameter of core or tube) plus ( ( N or number of cores minus 1) times 2)

So now is possible to calculate the number of winds or wraps (single layer0 around an EPG if we know the diameter of the outermost core of a spiralled EPG, the number of "loops" in the spiral, the outside
diameter of the core tubing and the gauge, diameter or width of the wire used to  wrap the core
t
So lets give a quick try for the multitier 6TmaggasEPG

1 tier is about 17 inches in diameter.   Since the line drawing of the 7 tier system  and photographs show the drain/connecting tubes are 180 degrees apart so its possible to keep the number of loops for a tier to
be 2.5 3.5 or 4.5 loops or if the connecting tubes are all  exact  integers of loops the connecting tube could be all on one side.  Or the direction of the flow could be counterclockwise  one one tier and clockwise in the other tier. So based on the line drawing lets say that that each tier has 3.5 loops

Length of core for 1 tier       [ ( 15+16+17)]times Pi ]  plus( 1/2 times 14 times Pi) = 150.78 + 29.99 =  172.77 inches   6 tiers 1036 inches
172.77 inches  divided by .025 inches per turn  (22 gauge wire by photogrammetry  = maximum 6910 turns per tier
6 times 6910  = 41,460 turns  or if you use exactly 3 loops per tier    150.78 times 6 = 904  inches  904 divided by  0.025 = about 36,191 turns  6 tiers 906 inches

Image a n inductor with between 36 and 41 thousand turns of wire and  between  75 and 86 feet long !! depending on method of construction 

Design parameters                                                                                                                                   Metric

The design output is 220 volts at 300 amp draw  66,000 watts  (Watts)           
(W) 220 times 300 amp draw   = 66,000 watts
The cross-sectional area of the core is between 0.218 and  0.254 square in (A)  =  1.406 to1.634  sq cm
0.0001634  square meters
The frequency is  60 cycle AC                                                                            (F)  (=     60 cycles per second                               
The voltage is 220                                                                                              ( V)  =    220 volts
Constant   4.44                                                                                                           k   = 4.44   
Bm =BetaMax

     V   = 4.44 times F*N * BetaMax * A
     Solving for Betamax
       
      220 divided by(  4.44 times  60 Hz/sec  frequency times 36191 x .218 A sq inches   =  .0001046

      now to work on units......

Next Topic Multiple layer coils

 
This is more useful to calculate wire requirements for the Mechanical Pump EPG .

Since it's possible to estimate the thickness of the coils, the length of the original coils,
the gauge of the wire and velocity of the ferrofluid 50 ips  and using a flux value estimate
a power output for the Mechanical Pump EPG.........

Stanley A Meyer EPG
Stanley A Meyer EPG
Stanley A Meyer EPG

If you put a vacuum on one end of 
a long plastic tubing and hold the other
end in some steam, closely spaced little
plugs of water will form and start
flowing through the tube in succession.

A bunch of ionized atomic hydroxy gas particles, 
injected with the steam, would then form regions
of negative charge between the plugs of water.

Would the diamagnetism of the water flowing in 
a loop around a coil affect the charge clumps' 
ability to generate a signal in the coil?  
Or would it make it stronger?
=============================
A regulator could send a series of bubbles through 
a riser tube surrounded with a number of rings. 
A ring which is grounded while a charged bubble 
passes through it will retain a charge after the bubble
and ground connection are gone. 
More rings provide more available potential to 
feed back to the cell.
========================
I'm starting to think this is a pretty good idea.
  The Miliken charged water drop apparatus can build 
up a substantial charge sending drops through a 
single ring.  Using a large number of rings in 
tandem with charged bubbles could rapidly accumulate 
a usable amount of energy.  It's just a question of 
how many rings each bubble has to pass through to 
provide enough milli Amps to generate a new bubble
in an appropriate amount of time.  Or it could be
wired up to output a series of pulses, rather than 
for accumulating a heavy charge.
==========================
With electrostatic induction, a ring will 'see' an ion
filled bubble when it's at a distance of two and a 
half times the radius of the bubble.  Anything greater 
than that is considered as infinity, electrically.  
Two rings have to be spaced a little more than two and
a half times the diameter of the bubble sitting between 
them, in order for the rings to be discharged.  
If the bubbles are tightly fitting in the riser tube,
the rings can be spaced at two and a half times the
tube diameter.  And this spacing is between adjacent
edges of the rings, discounting the width of the rings. 
The number of rings is limited only by the length of 
the riser.  Which could be dangled from a tall building 
or even a high altitude balloon.

This thing will either never produce enough energy 
to generate it's own bubbles, or the bubble stream 
will require only a specific number of rings to close 
the loop.  Even if this number is large, many more
rings can be added.  Apparently, the charge on the
ions doesn't leak off, or else the bubbles would 
shrink, due to less Coulombic repulsion. 
==================================

Having charged ions inside the bubbles is an important part 
of it.  This doesn't happen with normal electrolysis.  
My electrode with baffles added produces bigger
bubbles which shoot upwards, zipping back and forth
at certain points.  This tells me the bubbles are charged. 
Another part of it which is just as important 
is increasing bubble production.

I've found out that I can run a MOT at 5.8 Watts
on the power meter.  I use the same current limiting 
capacitors (7 Mfd) as before in series with one input wire.
This makes about the same number of bubbles. 
But switching the caps for a much larger value, then a 60 W
light bulb doesn't make a bit more.  More milli Amps doesn't
make more bubbles.  So I'll see if it's voltage related 
by using some other little transformers for 3.5 kV and 12 kV. 
Current limited, of course.
======================================

to  form the magnetic gas matrix, both the argon and the paramagnetic
metals from the transitional series must be in an ionized
state.  The removal of electrons using the electron extraction
circuit helps to stabilize the orientation of the paramagnetic
atoms with the argon acting as a neutral spacer in the matrix. 
By pressurizing the mag gas the amount of magnetic flux per
unit volume is increased thereby increasing the output obtained
with the pickup coils surrounding the copper tubing  channels

link to njce epg site

https://www.nikola-truck.com/epg-electric-particle-generator

in the multi-tier epg, two linear magnetic pumps were used.

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

His gasses were magnetic, passing through wire pickup coils.
  (A MAGNETIC Particle Generator). My proposal involves electrified
gasses from water, passing through electrostatic charge coupling rings.
  I'm not sure a coil would register a static charge.

I just tested a 1.5 V adaptor plug transformer.  
This should produce 9.6 kV when reverse wired. 
It does make a decent hV spark, even with a current limited primary.
  I should have time to check the bubble quantity in a few days.

=======================================
An electric charged particle is a Soure of electric field...

Electric Field Alone wont be able to induce current anywhere. 

To have current output first we need to add work to it energy in
form of movement... second this movement must be pulsed or oscilatory
so it can induce in a second output coil.

From my perspective the epg tube can be of of this set of coils... 
I imagine it working like the primary of a tesla transformer...

I did few on the epg tests... hope to have more condition in the 
future to be able to make more tests...

One thing about the charged particle is that when it's moving is 
like a wire flowing electricity so it works like a coil and have 
a certain magnetic field associated with that charge... however 
a charged particle inside a metallic tube will readily lose its 
charge to the tube raising the voltage...

The epg should have a manner to keep the charge inside... 

Must have high isolation or there will be no charge at all

The power input is the pressure of the hydrogen produced... 
and flow is perhaps pulsed by solenoid valves..

Stan show a motor recirculating and so perhaps it mean that 
the main problems is to keep the ionized particles inside because
it takes also power to ionize them... the output will be gases
that were not ionized in the process... a tokamak keeps the 
plasma from touching the walls of the toroid using a toroidal
magnetic field... so particles with no charge is not trapped... 
the higher the pressure more particles will be inside... 
and hotter it get.

============================================
============================================
A moving electrical charge produces a circumferential 
magnetic field.  When a charge moves axially through a coil, 
the charge's magnetic field is parallel to the windings. 
This will not produce an output from the coil, whose windings
must be cut by the flux.  Getting current from the coil
requires a different geometry, such as shown, for example,
in Figure 1a of patent #3,196,296.  This demonstrates 
conclusively that Stan's EPG circuit does not use ionized gas.

I think what he meant by EPG was an electrically
powered particle generator, with the particles 
being magnetic.
================================================

These magnetic particles are not Monopoles.  
Each particle has a North and a South.  When moving, 
the particles will line up N-S-N-S.  There won't be 
any adjacent particles both having the same pole pointing
in the same direction, askance to the flow.  
So, when a pulse enters a coil, the flux lines will
be perpendicular to the coil windings.  As the pulse
moves towards, then past the center of a coil, the 
flux will expand, then contract, as seen by the coil.
  This produces a rising, then falling output 
from the coil.  How this might produce more output
than input is a mystery to me.  But it would provide 
a convenient non electronic pulse generating system.
=================================================
imho Unlike liquids, gases can manifest compressional waves. 
For the mag gas systems linear magnetic pumping  creates 
sequential zones or waves of greater and lower flux levels.
in the circulating
gas. This is analogous to soundwaves and varying pressure
and air density The movement of varying flux past the
pickup coils induces a current.
Also by decreasing the distance between the zones or 
waves of higher flux density ( think increasing frequency
of mag pulses in linear drives) it is analogous
to cutting more lines per/sec 

 In the mechanical drive EPGS, it is the increasing
velocity that increases the output but only if the
increased magnetic zones are
synchronized to the coil spaces. For example if the
mechanical drive has let's say sixty pick up coils
and the velocity of the ferrofluid is( as reported0"
50 ips and the ferrofluid is pulsed once per second 
and the alignment coils and the circumference of the 
"loop" is about 50 inches  (pi times 16), there would 
be 1 zone of aligned ferrofluid imparting
a magnetic pulse to 60 coils in 1 second. But if you 
create 2 magnetic pulses in the core at twice the 
frequency, you now have all  the pickup coils being
subject to 2 pulses per second It is like having 2 
magnets on a generator rotor. If you pulse 60 times
per second in the final alignment coil AND have proper
tuning so that all the magnetized zones in the ferrofluid 
are passing the pickup coils at the same time 
you have multiplied the output by sixty times

In the parallel setup, it the train of  pulses 
are not aligned properly, the one current induced 
in one coil could be cancelled out by another 
magnetic zone arriving too soon or too late
or leaving the next adjacent pickup coil...
That why Stan is seen adjusting the EPGs

Question 1
   Theoretically, when creating the Argonide series with the paramagnetic transitional metals for mag-gas matrix formation, is it better to flood the
   reaction chamber with excess argon with subsequent centrifuge separation of the heavier metal Argonide gas or to use a 4 or 6 :1 ratio to approximate
   the preferred lattice arrangement thereby increasing the magnetic coupling of  and alignment of the formed metal Argon matrix prior to the final pulse magnetization?

Question 2
    In the available EPG imagery, tapered hose fitting are sometimes used. Are thye used to evacuate .the copper spiraled channels of air or in the filling of the
    copper channels with ferrofluid or mag gas?.

===========

Regarding the 2 EPGS that use tapered tube connections
1 is visible at the top tier of the multi-tier mag-gas EPG   (aka GEGA).
Another is visible on the EPG coil that has the tag 1 and 1/4 cup affixed

I think a vacuum was used to draw the ferrofluid through the ferrofluid devices
Perhaps the multi-tier was filled at the top

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

imho Unlike liquids, gases can manifest compressional waves.  For the mag gas systems linear magnetic pumping  creates sequential zones or waves of greater and lower flux levels. in the circulating
gas. This is analogous to soundwaves and varying pressure and air density The movement of varying flux past the pickup coils induces a current.
Also by decreasing the distance between the zones or waves of higher flux density ( think increasing frequency of mag pulses in linear drives) it is analogous
to cutting more lines per/sec 

In the mechanical drive EPGS, it is the increasing velocity that increases the output but only if the increased magnetic zones are
synchronized to the coil spaces. For example if the mechanical drive has let's say sixty pick up coils and the velocity of the ferrofluid is( as reported0"
50 ips and the ferrofluid is pulsed once per second and the alignment coils and the circumference of the "loop" is about 50 inches  (pi times 16), there would be 1 zone of aligned ferrofluid imparting
a magnetic pulse to 60 coils in 1 second. But if you  create 2 magnetic pulses in the core at twice the frequency, you now have all  the pickup coils being
subject to 2 pulses per second It is like having 2 magnets on a generator rotor. If you pulse 60 times per second in the final alignment coil AND have proper
tuning so that all the magnetized zones in the ferrofluid are passing the pickup coils at the same time you have multiplied the output by sixty times

In the parallel setup, it the train of  pulses are not aligned properly, the one current induced in one coil could be cancelled out by another magnetic zone arriving too soon or too late
or leaving the next adjacent pickup coil...That why Stan is seen adjusting the EPGs

q for wolverine69     req  image zb from memo 418 appendix if  available
a  thanks                   i think i already saw this at a conference 3 or 4 years ago but thank again
                                 posted as attachment 2

q for sandia 24          req for velocity measurements epg mag gas/slurry
a thanks                     posted as attachment 1

q for librarian12        req for epg detail photos series 1 or 2

Stanley A Meyer EPG
Stanley A Meyer EPG

EPG Brainiac Annex

Stanley A Meyer EPG

 transducer that measures fluid flow by the voltage induced across the liquid by its flow through a magnetic field. A magnetic field is applied to the metering tube, which results in a potential difference proportional to the flow velocity perpendicular to the flux lines. The physical principle at work is electromagnetic induction. The magnetic flow meter requires a conducting fluid, for example, water that contains ions, and an electrical insulating pipe surface, for example, a rubber-lined steel tube.

If the magnetic field direction were constant, electrochemical and other effects at the electrodes would make the potential difference difficult to distinguish from the fluid flow induced potential difference. To mitigate this in modern magnetic flowmeters, the magnetic field is constantly reversed, cancelling out the electrochemical potential difference, which does not change direction with the magnetic field. This however prevents the use of permanent magnets for magnetic flowmeters.

A magnetic flow meter relies on Faraday's Law of Induction to measure the flow of a fluid. Magnets outside the pipe create a magnetic field. Electrodes are located perpendicular to the magnets.

 

A conductive fluid moving through the pipe will generate a voltage (electromotive force) between the electrodes due to Faraday’s law. The faster the fluid moves through the pipe, the higher the voltage. Once you know the velocity of the fluid, you can calculate flow using the cross sectional area of the pipe. In this video,

 

I walk through some of the details that electrical engineers have worked out so that this ingenious device can work properly. Unfortunately I couldn't get it working very well myself! Want to learn more?

 

Wikipedia -  https://en.wikipedia.org/wiki/Magnetic_flow_meter

Neha Girme Blog - https://nehagirme.wordpress.com/2011/11/19/electromagnetic-flowmeter-design/

Arudino Code - https://github.com/gradyh/dc_pulse_gen

Due to the Rarity of this knowledge and methods and components and products

 

I Suggest and invite your

Donation at this time 

Stanley A Meyer EPG

PRINCIPLE OF OPERATION:

The operation of a magnetic flow meter is based upon Faraday’s Law, which states that the voltage induced across any conductor as it moves at right angles through a magnetic field is proportional to the velocity of that conductor.

 

Faraday’s Formula:

E is proportional to V x B x D

Where:
E = The voltage generated in a conductor
V = The velocity of the conductor
B = The magnetic field strength
D = The length of the conductor

  • Maximum EMF is induced when the electrodes are placed across the diameter of the pipe and the direction of the flow.

  • The direction of the magnetic field and the line joining the electrodes are all mutually perpendicular to each other.since the liquid is in continuous contact with the element of conductor between the electrodes,there will be an equivalent of short circuiting effect.

  • Thus the actual voltage across the electrodes will be less than VBD.

  • If the field extends over the large area ,this effect is less at the central portion of the field

Stanley A Meyer EPG.jpg

Read Further for Details!!!

 

Finally, I could find some pictures of the running model of magnetic flow meter which I had developed! Quality of the image is not quite good but still I would post them!

Stanley A Meyer EPG.png
Stanley A Meyer EPG v.png
Stanley A Meyer Epg 1.jpg
POWER SUPPLY: 
  • The circuit needs 12V power supply for generation of biphasic waveform and the amplifier needs +6V and -6V supply. Sample and hold circuit needs dual power supply of 5 volts

  • BIPHASIC WAVEFORM GENERATOR:

  •  

  • The driving circuitry used to drive the coils of the sensor. The clock for IC4017 is generated using Schmitt trigger inverter 74HC14.the IC4017 gives 10 decoded outputs . Out of them 3 outputs are taken as reference for measurement for sample and hold circuitry; decoded output 3,6 and 9. The four channel push-pull driver IC L293D is used to drive the coils.

          The output of this driving circuitry can be obtained as

Stanley A Meyer EPG dee.jpg

  Why Biphasic waveform is used to drive the coils??

  1. Sine wave is a continuously varying waveform. And if this signal is given to coils then the magnetic field generated will be continuously varying and that may create problems in measurement of output.

  2. Square wave consist of either positive or negative peaks but in this case we need the waveform generating positive as well as negative peaks.

  3. Due to ionic contact between electrodes and conductor some electrochemical voltages and currents are generated. These may interfere in the measurement of EMF due to water .So to avoid these errors,biphasic electromagnetic field is used.

  4. Rapidly changing polarity of currents ensure that, electrodes are not actively corroded.

  5. Due to symmetrically opposite currents errors due to charging time of boundary layer capacitance are also avoided.

  • SENSOR:

The flow meter sensor consists of two coils with specific number of turns and two sensing electrodes made up of stainless steel 304 (SS304). As the coil resistance is very small the current variation in coil is very negligible.

 

The sensing electrodes placed diametrically opposite to pick up maximum signal. This signal is very small i.e. in mV which is given to 2 stage amplifier.

SPECIFICATIONS:

  1. Number of turns in coil: 850

  2. Coil resistance: 50ohms each

  3. Electrodes Material: Stainless steel 304,nonmagnetic.

  4. Pipe size: 1inch

  5. Pipe material: PVC.

  6. Constant voltage source used

  • AMPLIFIER CIRCUIT:

 This is a two stage circuitry consisting of instrumentation amplifier AD620 with variable gain and a variable gain amplifier OP07. As the signal coming from the sensor is very small in magnitude the signal needs to be amplified considerably.

  • SAMPLE AND HOLD CIRCUIT:

 

The decoded output coming from decoded IC 4017 is taken out for measurement from biphasic waveform generator circuitry. The positive peak and ground signal is sampled and given to the differentiator. The o/p of differentiator is again sampled and hold with the use of analog switches and high input impedance operational amplifier.

  • DIGITAL PANEL METER:

LCD digital panel meter is used to display the signal of flow meter. It needs 9V power supply.

CONSTRUCTION:

The magnetic flow meter consists of a flow tube, which is a non-magnetic pipe lined with an insulating material. Embedded within the flow tube are a pair of magnetic coils, positioned 180° from each. Positioned 90° to the center line of the magnetic field are a pair of electrodes which penetrate the pipe and its lining.  An integral or remotely mounted signal converter amplifies the signal and converts it into a standard analog signal (4 to 20 mA) and/or pulse output representing a predetermined volumetric unit.

Stanley A Meyer EPG g.png

SIZE OF THE TUBE:

The size of the tube used is a one inch diameter pipe. One of the reasons for using this size is that it is easy for demonstration purpose. The tube is coupled with variable pump or series motor pump so that the flow can be varied. For calibration purpose a precalibrated drum or an existing commercial magnetic flow meter or both can be used for calibrating and checking purpose.

ELECTROCHEMICAL EFFECTS:

A magneto-inductive flow meter includes a measuring tube containing an electrode that is provided with an electro-conductive coating, as a result of which the galvanic contact between the electrode and the medium that flows through the measuring tube is indirect, i.e. via the electro-conductive coating. This produces an electrode that offers mechanical strength and is conducive to interference-free measuring signals.

  • Metal electrodes that are in direct contact with the flowing medium form an electrochemical boundary layer, capable of producing electrochemical direct-current voltages whose order of magnitude may be several 100 mV.

  • These electrochemical direct-current voltages can change quite rapidly, for instance as a function of variations in the local flow rate of the medium at the electrodes due to turbulences, of operating-pressure fluctuations, of the pH value of the medium, of the composition of the medium especially while chemical reactions are still going on in the medium, of solid particles carried by or particles suspended in the medium and interfering with the boundary layer on the electrodes, or of solid particles in contact with or indeed impinging on the electrodes.

  • All these factors lead to statistical fluctuations of the electrochemical direct current at the electrodes with amplitudes ranging from a few μV to several 10 mV. These statistical voltage fluctuations are also referred to as random noise.

 

PROBLEMS DUE TO MEASUREMENT OF ELECTROLYTIC CAPACITANCE:

 An magnetic flow meter is provided which includes a reference electrode configured to electrically couple process fluid flowing within a flow tube of the flow meter. The reference electrode is adapted to measure potential of the process fluid. A current limiter is configured to limit current flow through the reference electrode and thereby reduce corrosion of the reference electrode.

NEED FOR HIGH INPUT IMPEDENCE DIFFERENTIAL AMPLIFIER:

Since we are using biphasic excitation of magnetic field with no generation of magnetic field in between and we provide synchronous sampling of the generated emf, there is a need of having a very high input impedence differential amplifier. Another reason being the choice of electrode we opt. in this case we are using the stainless steel electrodes.

NEED FOR BASELINE CORRECTION:

Baseline correction is very important to get a steady signal. The baseline subtraction is done by inducing emf during zero magnetic field is subtracted from the observed emf during the steady state of the magnetic field.

Stanley A Meyer EPG vp.png

You can see there are some spikes at the edges of the pulse.

 

PROBLEMS FACED WHILE IMPLEMENTING:

  • Coil size

  • Leakage

  • Material for electrodes

  • Grounding trouble: The ground conductor should not transmit any interference voltages, therefore, do not ground any other electrical devices together with this conductor.

OBSERVATIONS:

  • It is observed that due to the ionic contact with the unit-moving element, certain electrochemical voltages and currents are generated.

  • These may interfere the measurement of the EMF generated due to fluid movement.

  • It is necessary to generate a biphasic electromagnetic field.

  • The symmetrical currents in the opposite direction ensure that the sensing electrodes are not corroded.

  • The rapidly changing alternating polarity also avoids errors due to the charging time required by the boundary layer capacitance.

Stanley A Meyer EPG gjj.png
Stanley A Meyer Epg 1kjkj.jpg
  • When magnetic flux lines generated by coils are cut by conductor then corresponding output voltage can be seen from the above waveform. The amplitude of this voltage is proportional to the velocity of the conductor,i.e,flow rate.

  • Total flow can be given by,

  • Total flow = flow rate X time

  • The difference between the positive and the negative peaks is proportional to the flow rate. Thus samples are taken at positive, negative and baseline to get the corresponding differential output.

 

 

“Due to the huge response to this post, I am giving away the designed hardware PCBs (with complete BOM) at a discounted price.

Stanley A Meyer Mechanical Pump EPG coil parameters

« on: February 08, 2021, 04:05:44 am »

[An intrinsic portion of the Stanley Meyer technology had inductors, chokes and coils as important components
if devices. The voltage intensifier circuits( VIC)and the electrical  particle generators (EPG)
Many of Stanley Meyer's patents and publications provide diagrams provide the general description or have live
drawings that lack  exact component values of the resistors, capacitors , coils and chokes. Fortunately the high resolution
photographs from the L3 storage unit and by Don Gabel, The Orion Project and others allow for many printed circuits
to be closely  reconstructed.  The following article is related to the photogrammetric analysis of coils and inductors.

The values of the capacitors and resistors is much more straightforward using programs that match color code bands on resistors
with values and  OCR image data files input cross-matched with component  files based on supplier catalog scans.




METHOD 1. Determine Length of bobbin, thickness or depth of winding,/the wire gauge and method of winding
   
The diameter of the outermost EPG channel or loop can be estimated.at  about 17 inches
Therefore the outer circumference can be estimated at  17 x Pi inches
By dividing the circumference by the observed number of coils an estimated length of each coil can be made.

A further refinement in precision can be made by subtraction of  the total length  L occupied by coil spacers.
So in the case where you count, let's say as way of example, 59 coils and 60 coil end spacers, each winding is
1/59th of the circumference of 53.4 inches or calculated at about 0.905 inches long.

Method 2.
Because of  the high resolution photographs available, estimates of  a coil can be made directly.
Using a known measurement such as the outside diameter of tubing  ie.  0.500 inches
in conjunction with a screen distance tool in Photoshop(r) or another program such as
Screen Caliper(r) the length of the coil can be made.

THICKNESS
Since the outside diameter of the core channel is known,  an estimate of the thickness of depth of winding
may be obtained by using  photogrammetry to estimate the  thickness of the winding.
The total thickness or height of the wound coil is first measured. Then the core diameter is then subtracted.
the resulting  figure is then divided by two. This is the height or thickness of the winding around the core

So now we have what is call a winding window with height H and length L.
H TIMES L = A   the area of the winding window. Think of it a a cross-sectional view of
the coil windings with the ends of each wire being viewed.
Something like this:

IIOOOOOOOOOOOOII
IIOOOOOOOOOOOOII
IIOOOOOOOOOOOOII
representing 3 layers of wire with 12 wraps (the II symbolizing the  coil dividers)
3 layers of wire by 12 wires wide or 36 turns or wraps of wire around a bobbin

IIooooooooooooooooooII 
IIooooooooooooooooooII
HooooooooooooooooooII

In this exsmple, a thinner wire could be wound 18 times on the same length of bobbin.

NUMBER OF WINDS
Since the gauge of  the wire can be estimated with a good amount of precision
,the use of circle packing theory (see wiki) theory can be used to determine the
number of turns that can fit through this winding window( Area equals Height
times length.

One factor that helps, is that wires come in standard  thicknesses or diameters
For convenience the AWG  (American Wire Gauge) is used in electrical
and electronic work, Electrical wiring in the U.S. is often 10,12  or 14AWG
Electronic work is often  uses 18,22, or 30  AWG gauge wire
Whatever the reason the smaller the AWG number, the thicker or larger
the diameter of wire!!

The reason this helps in photogrammetry, is that the gauges are discrete values
Look at this table:

AWG      Diameter in inches           AWG     Diameter in Inches
10           .1019                                 20           .0320
12           .0808                                 22           .0253
14           .0641                                 24           .0201
16           .0508                                 26           .0159
18           .0403                                 28           .0126
                                                         30           .0101

The 16 gauge wire is about 25% thicker than 18 gauge
The 22 gauge wire is about 25% thicker than 24 gauge

Not to get too technical, but this is a logarithmic scale,  but the important  concept
is the PERCENTAGE OF DIFFERENCE BETWEEN GAUGES IS LARGE
in relation to the precision achievable in photogrammetry

This means for a given photogrammetric distance is it easier to pick out the exact
gauge of wire used because the precision of the that method is often less than 2 to 5%.

PACKING FRACTION

There is a branch of mathematics which describes how many circles of uniform
size can be drawn in a given area. It goes by several names but let's just call it
Circle Packing Theory. 

By determining the winding window size, the  appropriate circle packing  fraction can be used to
determine a close estimate of the number of windings per coil. In the previous example
cross-section of a coil, it represents one type of winding

One type of winding known as square or precision winding has each layer of winding with
turns directly on top the wires in the layer beneath with no offset.

Another type is hexagonal winding, with the layers arranged more like a honeycomb

And thirdly there is a random type of winding with lots of crossover and gaps

The hexagonal packing is the closest or most densest  method of winding coils
with a value of 0.906  or about 91% of the area occupied by wire with the
balance of the area being gaps between the wires

Square geometry winding with  each winding of wire directly on top the
layer below(  No offset)   has a value of 0.785  It is not at close or dense
a winding as hexagonal winding.

A random wind often a more gaps but the packing ratio is highly dependent
on the size of the wire relative the length and width of the winding window

Consider for a moment two equally sized sheets of sandpaper.
One is coated coarse grade grit, the other coated coated with a fine grit used for
final sanding.  The  arrangement of the sand grains is random in both
cases but there are fewer grain of sand  on the coarse paper and
many more grains of  sand on the finer grit paper.
This is analogous to the number of random winding or wraps of wire in a given
cross sectional area on a bobbin. Intuitively very small wire gauges have a
higher  packing fraction than large. This is a difficult value to quantify

SO IN SOME CASES IT MAY BE POSSIBLE TO CALCULATE THE NUMBER OF TURNS
IN SOME CASES EMPIRCAL METHODS OR TEST WINDINGS MIGHT BE NECESSARY

As an example if the winding window is 1 square inch and the AWG  is 22, and the tighter hexagonal
winding factor is used(0.906) then    0.906 square inches of that window is occupied by the area of the wire..
The cross-sectional area of AWG 22 is 0.0005 inches.
0.906/divided by 0.0005 =approx 1800 turns
 
With precision or square winding a factor of 0.78 can be used resulting in an estimate of 1560 turns through
a 1 inch square window
 

SUMMARY

Basically the application of the above method may be used to estimate  the number
of windings for an EPG coil by photogrammetric means in some cases
 
A search of empirical transformer design charts might be instructive for this third case
of random winding.  Empirical  as well as advanced computer iteration calculations
are used
 

Method 3

There are on line calculators also:

https://www.daycounter.com/Calculators/Coil-Physical-Properties-Calculator.phtml

MISCELLANEOUS COMMENT
POWER OUTPUT DEPENDS ON  METHOD OF WIRING PICKUP COILS

It appears as though the mechanical drive epg was wired in parallel  lower voltage and  and a
higher amperage due to more coils
While the multitier EPG was higher voltage due to fewer coils and  many windings which required of multiple tiers
It also could be that the effective value of the flux in the mag-gas systems was lower that the higher density ferro fluids
which might explain the need to operate at  90 ips velocity

Russ Greis has a nice build of the EPG that had jumper connectors at the ends of each coil so that the coils could be individually
So depending on how the jumpers were used the output amperage and voltage can be changed. The output voltage or amperage
can be varied but also be dividing the coils into 3 groups  resulting in a three phase system

Other  phase systems are possible such as six phase systems

A sixty coil  system   1*2*2*3*5= 60 will allow for 1,2,3,4,,5,6,10 and 12 cycle output

Stanley A Meyer The Magnetic GEL EPG

« on: March 07, 2021, 20:02:55 pm »

It is well known that Brownian movement can suspend small particles of solids, such an in muddy water
or small fat globules as  milk. In this  novel  approach to energy generation, Permanently
magnetized particles, and materials that that exhibit paramagnetism such as the transitional metals Fe, Ni
and Co are suspended in a liquid clear optical adhesive, a clear methyl methacrylate, Castolite(r) or
one of the glass hydrogels and clear SillyPutty(TM)

In the case of the clear optical adhesives a uv light hardens the adhesive
and the suspended magnetic material or magnetizable media is now
held in a fixed position  (good way to make custom shape magnets)

In the case of the casting resins the hardening agent is acting like the uv light

During this process the gentle rotation of the reaction vessel can prevent settling before the
plastic or glue "sets" or solidifies

By proper selection of the viscosity and particle size,  rate of sedimentation of nano magnetites
of the 10nM size or metal powders on the order of 50nM is not a factor during the hardening process

By injecting the casting resin or viscous optical glue into the spiral configuration  of copper tubing
you now have a clear non-settling magnetics or matrix of magnetite and/or magnetizable  particles

Now you have a tube that laser light can pass through in a pulsing manner, causing changes in the
magnetic flux in the pick up coils surrounding the light guide. Lenz law is not an issue since the magnets
are not moving , only the magnetic pulse wave in a linear and radial fashion.

The amount of Flux is dependent on the number of coils, the number turns, the length of the tube or
channel,  and the frequency   Because the amount of magnetic susceptibility is dependent upon the
concentration of the particles because of light scattering, the  vol/vol ratio of nanospheres must be
low but first surface mirroring with chrome or silver plated  conduction channel the light energy
is re-reflected within the channel   Also manipulation of the index of refraction can reduce  losses
of light energy And by increasing the frequency of pulse 400Hz the cloudiness of higher concentrations
can be offset to some degree

It's roughly analogous to a ruby crystal laser but in this case the energy is affecting the magnetic field
of the transitional metals and/or the paramagnetism of nanospheres of magnetite used in EPG power generation
In general the higher the viscosity of the suspension phase, the lower the sedimentation rate of  particulate matter

The smaller the size of the particulate size, the lower the sedimentation rate

In the ferrofluids  the typical  particle is 10 Nm in diameter and  Brownian movement can keep the small particle is suspension for
long periods of time  especially if coated or in the prescience of a surfactant

So this led to investigation of  more viscous  liquids as  Syltherm silicone oils, polyethylene glycols, and hydroarbon oils similar
to  kerosene for the oil phase of the ferrofluids

The fact that nanorods of iron or magnetite are large enough to have a discrete north and south pole s( nanobar  magnets )were then possible

Circulating aligned  polar magnets seem to be part of the solution to the EPG generators
In general the higher the viscosity of the suspension phase, the lower the sedimentation rate of  particulate matter

The smaller the size of the particulate size, the lower the sedimentation rate

In the ferrofluids  the typical  particle is 10 Nm in diameter and  Brownian movement can keep the small particle is suspension for
long periods of time  especially if coated or in the prescience of a surfactant

So this led to investigation of  more viscous  liquids as  Syltherm silicone oils, polyethylene glycols, and hydroarbon oils similar
to  kerosene for the oil phase of the ferrofluids

The fact that nanorods of iron or magnetite are large enough to have a discrete north and south pole s( nanobar  magnets )were then possible

Circulating aligned  polar magnets seem to be part of the solution to the EPG generators
the reduced
viscosity concept put the research on the right track

Stanley A Meyer Multi-Tier EPG Part List and Designators

« on: March 08, 2021, 17:21:26 pm » 

Multi-tier EPG Build Listing  6TMaggasEPG     mod 5    listing in progress

COPPER AND PLUMBING

Quantity         Description                                         Part Designator                                                                Materials

6                     Spiral Tier                                          ST                                                                                    300 cm tubing per tier
6                     Inter-tier Tube                                    IT                                                                                     22 cm each connecter
14                   45 Degree fittings                               ITF                                                                                    2 for each IT
1                      Recycling tube                                   RT                                                                                     1
1                      Top Feed tube                                    TFT                                                                                   22 cm
1                      90 Degree fitting                                TFTF                                                                                  1    * Recycling tube is greater diameter  fitting harder to locate if 45 degree option
4                       Linear  Pump fittings                        LMPF                                                                                 4   to connect linear mag pumps to  RT
2                      Taper Fittings                                     TPF                                                                                    2 for vacuum evacuation and  gas/slurry fill
2                      Magnetic pumps                                 LMP                                                                                  for  gas/slurry movement
1                      vacuum pump

Wire               22 ga AWG                                          IWW                                                                                        inductor windings
                       28   awg                                               ACW                                                                                        alignment coils
qs                      0  awg
                        4  awg
                      10-12  awg                             Romex(r)  3 conductor/w ground

HARDWARE
           
          1 Plywood base for 7T gega Perspex for the 6T model  use the Perspex  40 x 40 cm,  for plywood  larger to accommodate EEW ass'y

GAS
       
                Quantity of  gas required is pressure dependent, evacuate spiral core first  open fill valve  FV2 for gas introduction
                for ferrofluid models measure out calculated fill volume for device and introduce from bottom slowly  use2  inline
                fluid traps before vacuum pump

ELECTRON EXTRACTION WELL (EEW)

6          Porcelain  Light Bulb fixtures
6          Square metal outlet boxes
1          stepping switch                                     to increase load on warm up
6          Incandescent Bulbs 100 or150 watts    depends on amount of energy to be dissipated in electron extraction well (EEW)
                                                                          do not use LED bulbs , they are too energy efficient!
qs        Mounting hardware                               screws/bolts

Stan Meyer- Magnetized Iron Nanorods in Fluid EPGs Electrical Particle Generator

« on: March 11, 2021, 21:19:51 pm » 

Advances in nanotechnology has provided a new area of research for the fluids used in mechanical drive electrical particle generators  (EPG's)
The production of nanorods  with lengths of 20 NM to 100Nm with transitional metals is now a topic  that needs investigation The
100Nm length with S.A.Rs approaching 20, allows for discrete dipolar magnetic domains to be created in these nanorods just as electric
polarity has been shown in similar nanorods with polar ligands

For nanoparticles , whether spherical or not, Brownian movement is far outweighed b  electrostatic and electromagnetic forces acting upon
the individual particles. Nanospheres have  a Standard aspect ratio (length /width) of 1 with smaller nanorods having a standard aspect
ratio of 3 to5. The preparation of nanorods  of 100 Nm are now possible resulting in larger Aspect ratios making even stronger discrete magnetic
domains possible

Electron microscopy is needed to  view many of these structures due to their small size compared to the wavelength of visible light.

When the iron nanotubes are placed  in a strong 400-800 gauss magnetic field the iron nanorods are not only magnetized but also become
aligned and are able to be moved and directed as  are the  medical ferro-fluids and chemotherapeutic when used..

Although the surface area of nanospheres is greater than for a similar molal -weight of nanotubes, the magnetic saturation is
approximately the same.   Thus concentrations on vol/vol basis can be similar  to the EFH-1 series ferrofluids used in the
mechanical drive  EPGs by Meyer et al  Once the iron microrods are magnetized permanently   they can be circulated mechanically
with pumps and  magneticallyaligned using a lesser magnetic force from smaller smaller
alignment coils prior and after flow turbulence and mixing by mechanical ( or even peristaltic pumps

Also magnet linear pumps can be used to create magnetic wave or zones of varying magnetic strength that pass by tie pickup coils
with the magnetic fields radiating  outward from the magnetic moving core. Each nanorod is functioning as a small permanent
and aligned magnet  Synchronization of the varying magnetic wave with relative to the speed of circulation
and spacing of the pickup coils would enhance output power.

Thanks to the blue team

Image attachment
1 Nanorods
2 Magnetically oriented nanoroads

Following the Berkeley concept--" the use of nanorods instead of nanospheres can increase the magnetic saturation of the 3d
printed structures". Also by "applying a rapidly changing external magnetic field, the structures vibrate allowing for localized
agitation  as an aid in the removal of blockages at a  microscale in the capillaries."

pat app JNL 3 days ago


 2 Berkley 3d printed nano liquids

  Now consider the work with magnetic liquids in California where a drop of magnetic liquid  moving through
      a coil

3 .questions      Are the magnetic droplets acting like the neodymium battery train    ( homopolar magnet)
                         and if the  copper coil is  made into a circular loop and pickup coils  placed around the
                         "track"    ( as in the multitier epg) is useful power obtained from the permanently magnetized droplets
   
comments?

                         
regardsThe MHD technology has bee utilized in a Chinese power plant for a silent running
cruiser.  The principles involved were discussed in WFC Memo 455 "Hyperdrive"

relevant site: click below

https://www.theregister.com/2017/10/27/chinese_navy_silent_magnetic_propulsion/

nanorods Gold.jpg
bottom of page