EPG Version 1 Mechanical Pump
The flow rate of the slurry was about 50 ips in the ferrofluid systems (single tier systems) ref: tech
The circumference of the mechanical EPG series (single tier systems) was about 50 inches ref rwg replication
Tthe flashing timing led rate was about 60 times/minute in the single tier system ref :Dealership tape posted by irondmax
By adjusting the flow rate and rate of magnetization in the alignment coils ,the magnetized portions of the ferrofluid and/or
mag-gas are synchronized to the position of the pickup coils. This reduces the back eddy current and Lorenz forces while
the slurry or gas are circulated The maggas systems were likely tuned in a similar manner although the 90 ips reported
for multi-tier is due to higher speed required to compensate for the lower magnetic flux per cubic inch
but this is compensated by a greater number of windings in the multi-tier systems
he 7TmaggasEPG 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
The Warp Drive Study
Video credit: the alien scientist website
Some of the concepts may apply to the Stan Meyer technologies.
listen closely at about time stamp 3:25 and following about impedance matching,
something that is necessary and occurs at resonance in the Meyer cells
also at timestamp 5:46 increasing energy within atoms by photons (aka laser or light stimulation)
The Control of the Natural Forces available at:
see link to negative mass article
as mass decreases, and energy is released (aka /Meyer
« Last Edit: May 17, 2021, 16:41:13 pm by jim miller »https://youtu.be/Rr_s28wIOzQ
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 spiralled 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.
Stanley A Meyer EPG and Stable Room Temperature Magnetic Liquid Compounds
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
Shimada, Kunio, et al. “Magnetism and Self-Assembled Structure Utilizing Micro- and Nano-Particles.” Journal of Metastable and
Nanocrystalline Materials, vol. 24–25, Trans Tech Publications, Ltd., Sept. 2005, pp. 121–124
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.
YES the Mechanical Pump EPG Circuit Board is now Available from Secure Supplies
Stanley A Meyer EPG Style 1 Mechanical Pump V1
2 layer board of 9.86 x 9.86 inches (250.5 x 250.5 mm)
P r ic e
Stanley A Meyer Mechanical Pump EPG coil parameters
[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.
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.
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:
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
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
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
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%.
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
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
There are on line calculators also:
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
Coil Physical Properties Calculator
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
A 3-D printing file for creating spiral inserts for the electrical particle generators (EPG's) has been posted at grabcad.com
The idea is to print short inserts that twist the magnetic slurries and/or gases within the 0.5 inch copper piping of the EPG's The work is very impressive but the suggestion that they should be inserted one after the other may lead to an unexpected result
"EPG Gas Core Helix
August 12th, 2013
Fits inside half inch copper tubing for a Stanley Meyer EPG. Print many of them and slide them in...
If the ends of the spiral parts are not aligned to each other to allow a smooth channel between the inserts (let's say 90 degree rotation) then the spiral dividers are essential acting like a powder mixing column with each insert acting to triturate or divide the slurry/gas with each pass though an insert. In the case of a 2 fluted insert, a passage through 3 of the inserts would be essentially dividing i into two channels then dividing again and then once more (. 8 triturations )
"Spitfire(r) propane soldering nozzles used a similar method to swirl and achieve excellent air/propane mixing which allowed for a very hot flame to be able to braze with out using the more expensive "MAP" gas/or pure oxygen..
One reason that alignment coils are used in the EPGs is to correct the turbulence and mixing of the mechanical pump drive in mechanical pump EPG systems In the gas systems, the linear drives function both as an alignment coil and pump so the turbulence and mixing in linear flow is less. While the dividers are essentially adding more "cores" or channels which may be helpful in final power output, it may be outweighed by increased resistance to flow and turbulence effects.
Note for calculations
Some of the factors be considered when using the dividers
1. The number of twists per unit length of divider
This affects the angle of the magnetic flux cutting the pickup coils and power output
2. The volume of the inserted divider per unit length
This decreases amount of gas/liquid per length of channel
3. The increase of surface area contacting the liquid or gas
This affects rheological flow resistance and back pressure
4. The decrease in volume or gas/liquid
This decreases magnetic susceptibility and flux strength per length of channel
CONTRUCTION METHODS AND TIPS
One possible solution to the dividers is to make a very long spiraled helix from silicone rubber with 2 to 3 flutes and to pull this through the copper channel.
Since the friction to do this was significant even when the copper tubing was pre-lubricated with Teflon DriLok(r) or low viscosity Syltherm(r), another approach is to fabricate the tiers in sections o f10 or 20 ft lengths of straight tubing. .
In the multi-tier systems
each spiraled tier required approximately 180 inches of tubing is required depending upon arrangement of the tier connecting tubes, so standard 20 foot length are sufficient.
1. A long silicone helix is then pulled down through vertically and twisting the helix slightly to reduce its diameter (similar to threading a needle or when making rope)
Once the silicone divider helix is through first section, another length of the helix is threaded through the next section of copper pipe or tubing until six or seven are made, one for each tier. Then the soft copper tubing is coiled into the spiraled tier using a jig made from an oil drum or other spool such as a wooden cable spool. Since both the helix and copper are flexible
( because the temper of the copper can be removed prior to helix insertion by heating the copper tubing or pipe, Then the copper channel with helix inside can be formed into the spiraled configuration
2. The pickup windings are then wound upon each tier using a toroidal transformer winder or other similar device
3 The completed tiers are then fitted with. 90 or 45 degree connecting "ells" being careful not to damage tie silicone twist helix by excessive heat and also to remember proper offset angle due to connecting outer and inner ends of the tier openings.