Joe Cell Summary
Three Kinds of Tube Design
Using Joe Cells in the Northern Hemisphere would appear to be more
challenging then in the Southern Hemisphere. Waters natural spin must
be fully overcome and then reversed.
Since we discovered that vibrational resonance has specific parameters
that can be engineered, we can now divide all the tube devices,
including Joe Cells into three major groups, with minor spin offs
of each one.
- Random size tubes -
These rely on atomic or molecular linking - this is the hardest
to achieve vibrational resonance and represented by a standard Joe
We have identified a few tube lengths that simply will not work, due to
the voltage gradient becoming identical on all the tubes.
See 925 Hz document: magnetism site.
2 - One dimensional resonant tubes -
These are tubes cut to length to match an external vibration that is
emanating from the earth - the GL is an earth powered segment length
and one of the strongest having a connection with water directly from
the matrix document. Also using 8" tubes may be linked to the 60
hz power lines in North America and seem to be linked with power grid
loading times of the day, dropping at night time considerably. For the
earth resonant lengths and "one dimensional cutting" see the matrix
document and the earth vibration document.
3 - Two dimensional
resonant tubes -
These are self resonant and vibrate up from their own mass
which is always in vibration. They use the polygon formulas, or the tetrahedron,
pyramid, or diameter formula.
Only on this generation of tubes, is the center of the tubes meat used
for calculation. These tubes do not appear to go dead at night time
between the hours of 1 and 2 am as often do the earth generated
lengths, as well as standard Joe Cells. There is a 15 Minute window where cells dip. Also these tubes can be
designed for proper cell phasing of the waves such that voltage
reversals on gaps can be eliminated. For
two dimensional cutting on self resonance see the polygon series of
preceding documents show the development sequence to this discovery.
you are not familiar with platonic vibration, you might want to scan down the
entire series, and note the work with spheres also.
It is suggested that having 7 active water gaps may produce a much
stronger torsion system then having only 3 or 5, this means the
perfect 1/4" cell will have 8 tubes including the outer can, and may
have 8 times the power for the same water volume. For a cell with this
many tubes each tubes wavelength must be set accurately, tube lengths
off by over .01" may go out of range and accuracy of .002" is
recommended. A design chart for this cell is found below.
4 - Two dimensional dual resonance -
A new set of 2D resonance tubes is now in the planning stages where two
sets of rings will overlap at 1/4 wave length. This cell is
expected to produce extremely high pressure
fields. It will most likely use two sets of 1/2" spacing with each one
setting at 1/4" to the other. It is not yet known how the taper will
look. From the top it will look similar to a 1/4" polygon tube set but
each tube will be tunned for a 1/2" wavelength so every other tube
couples in resonance and the two sets fight one another at a 90 degree
shift to produce a strong pressure field. This effect has been observed
in Light rods already to peak directly at center spacing.
This remains to be tested to see if the voltages can remain stable with
this layout, or if they will tend to flip on every other tube.
Using standard commercial tube
sizes, Cells can be designed with approximately 1/2" water gaps, or
with 1/4" water gaps. The 1/4" gapped cells have a higher frequency,
but generally hold less water mass. A factory tube is generally machined to
have an OD or outer diameter exactly on 1" 2" 3" etc and the inner
diameter or ID is somewhat less. .065" seems to be a good wall thickness
and all the tubes can often be matched at this thickness. However
to make up a final lathing chart, it is recommended to place a
micrometer on the tubes, and do a final adjustment to the calculations
before cutting them if there is a variance in the tubes you end up
Pipe is different then tubing,
and the ID measurement is always slightly larger then the base
dimension, 1" 2" 3" etc. Pipe diameters are bigger, and designed to fit
elbows and such that are over sized. Pipe is designed to carry a volume
inside it of the inch rating or slightly larger. Wall thickness for
pipe will be heavier, and materials more costly. Often a tube will
slide into a pipe with just enough clearance to move smoothly.
304L Stainless Steel [SS], and 316L Stainless Steel have been used
successfully. 316L is about twice as expensive but has better guarantee
of being non magnetic. If you can test your tubes before purchase with
a neo magnet you can avoid bad welds where Annealing has failed.
Stainless Steel should not be magnetic for JC work. If the outer
can is welded it must be Annealed to fully degauss it and ensure it
will not become magnetic at a later date. This is done at
1200 degrees in a kiln, having a nitrogen gas so metals are not
scorched or burned on the outer surfaces due to Oxygen presence.
Sample tube source 1
Sample tube Source 2
Materials for a 304L cell can run around $100 or less for a full set of
1 foot tubes, that can probably make a couple cells. 316L will start at
If you are still trying to decide whether to use other materials for
your cell such as copper , tin, or aluminum let me save you some time
here, don't. Electrolysis will destroy all these in short order as soon
as both water and electric field come together on them. Stainless Steel
is a very unique mix of metals offering both diamagnetic chromium and
magnetic iron in a chemically bonded ratio that is perfect for
vibrational energy to manifest. I have found no other alloy at present,
as it replaces two elements of similar operation [copper and iron].
Never use plastic or PVC on sealed cells, they will swell and explode
when vacuum is placed on them from the engine. Stainless Steel will
flex inwards under the same conditions as PVC will flex outwards. SS
must be thick enough to hold the vacuum. Do not expect a paper thin
system to offer much at all.
To know what to expect from celery, one needs to identify their
objectives. This will have bearing on which cell design technique they
choose to use in engineering a cell.
Car - Engine
Joe Cell energy, can improve gas mileage to ~15 percent in shandy mode if the energy is coupled to the engine effectively.
The cell will not be gassing or producing any Hydrogen gas into the
engine, but rather a "spin field" or a space compression that will
alter the engines vibrational parameters [Torsion Field, Orgone]. Engine
vibration is lowered or smoothed out [canceled] and inertial resistance of the
entire car can drop. Extreme cases have been reported to become nearly weightless in the Southern hemisphere.
Cells can be plumbed in traditionally under
the hood of the car to the carb vacuum. These cells need to have
completely sealed cans around them.
Celery This document shows the basic traditional cell placement for an engine with a carburetor.
Cells can be wired into the oil dipstick, or
can be wired through a dimmer switch also and tunned to match or peak
these vibrational parameters through the oil system or the water system.
coupling tube device can be made to resonate with a cylinder under load
condition for shandy mode, where the cell sets on the passenger side
floor area or elevated up slightly to ride approximately level with the
heads of the engine with no connecting tube or wire to the engine, only
a vehicle ground to the center tube.
The larger cells, 1/2" gap, having more water mass seem to effect cars
inertial and motional fields more. These must have center tube grounded
to the cars frame at a resonant point. Cornering and accelerating
actually feel to be far less force then normal. The smaller 1/4" gap
cells seem to effect engine power more as they approach the piston
displacement dimensions, or probably some multiple of it.
Meditation - Learning and study of the field - Development
Higher frequency is better. The 1/4" gapped cells cut with polygon
formula are a delight to touch. They are concentrated in size and more
intense. The entire field is held close, within 1/4" distance of the
tubes if accurately cut. This allows for easy exit from the field if it
is desired to get away from the vibration. Random length and GL cells
create a much larger vibrational bubble and one must dump the water out
to get the large fields to drop over time. A field once established
strongly can last for many days after the cell has been torn down. This
field is shown to be attached to the space where it was created and not
to the device. This speaks to the ability of these devices to move
through space with the altered space or Aether actually pushing them
Good "learning cells" do not need to have sealed covers at all, and
make easy access to touching and feeling the vibrations on the tubes
from the top side. Many do not even have covers. A cover will reduce
water losses, and on a resonant tube system cell this will be very high
compared to a standard Joe Cell.
A nice set of resonant tubes on the desk, can give practice at cell
alignment, and node location, using various palming techniques.
Expansive side goes up on all the tubes, and if the nodes are aligned
correctly the cell will hold a voltage fairly constant without
reversing the voltage on any of the gaps over extended periods. Normal
practice is to align the seams, however on poor designed tubes this
will only work for 2 to 3 water gaps before phase coupling is lost.
Inner tubes will begin to fight outer tubes and gaps may reverse their
Wave interactions become visible through touch and sensing distance
from the tubes where the ringed shaped fields will form around the
cells, similar to orbital distances around planets, or atoms.
Discovery of this field is paramount to understanding vibrational geometry and gravity fields.
A 7x Joe Cell
[Sample Design - Using the 7x segment count for active water gaps,
which has been shown to be a most powerful combination for other tube
Note: If you want to experiment with this cell design, you can make it
as long as desired, by altering the "Seg X Stack" count column, and
calculate new tube Lengths.
13x were chosen in my case only to come close to Piston stroke distance.
Polygon Formula - Tube design Table
- Wall = Mean * pi
Seg X Length
.2175" 13 2.875"
1.5" .065" 1.435"
.249185" 13 3.2394"
15 .252568" 13 3.2833"
2.5" .065" 2.435"
10 .255802" 13 3.3254"
3.5" .065" 3.435"
8 Can 4" .065"
8 Display Can
1/2" extra clearance at cell bottom - all tops flat
Piston Power Sweet Spot RAV = 3.005" Stroke distance = 3.115"
9 Coupler 3"
Displacement volume coupler for 2003 Toyota RAV
nodes = polygon sides count
FS = Fractal Segment Length = Vibrational Wavelength or 1/2 the sine wave distance.
FS = Diameter * (sine (1/2 the angle))
Seg X Stack = Segment count in length of tube
Round all lengths to the nearest .001" as a "target" during lathe process, and see how close you can come.
Tubes should vibrate up within .01" of the target lengths, to the sensitive touch.
[Photos and descriptions - Compliments of Ron Pugh]
The first picture shows what is needed, two washers and a support tube
or solid bar that will fit in the headstock taper. The piece that I’m
using here is called a chuck blank but it fits nicely in the headstock
reducing taper, the large lump. It just happens to have a 1 inch plain
portion that the piece of 1 inch tubing slips over.
Now in this
version the sole purpose of the one inch tube is to hold back the blank
in the turning end of the 3 inch tube. This is just a slip fit in the
tube and would just slide down inside the tube if it were not for
something holding it back. So the one inch tube can be anything, just
as long as it is somewhere centered behind the live center. The little
plate, supported by the live center, supports the end of the three inch
The second picture shows it in place, with the chuck off, for a better visual understanding.
The third picture shows it ready for turning.
The forth picture is a different system and requires your imagination
to fill in the other three set screws. The advantage here is you
don’t require plates for each size tube, only bolts of the right
length. The hub would have a setscrew to locate it lengthwise and
either a bigger live center or a bung in the end of the one inch tube
(or a solid shaft with a center drilled hole in it.)
Use of either system ensures that the end of the tube being turned stays where it is supposed to be… in the lathe!
Short tubes, well supported by the chuck jaws, can be turned with just the one washer in the chuck end of the tube.
Public Domain Document
c_s_s_p group 10 - 15 - 2009