Kalafian Vartan -- Electric Perpetual motion

  

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Kalafian VARTAN  
 Electric Perpetual
Motion

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GB2130431  
 Method and Means for
Producing Perpetual Motion with High Power

1984-05-31  
  
Abstract -- The perpetual
static energies, as provided by the electron (self spin) and the
permanent magnet (push and pull) are combined to form a dynamic
function. Electrons emitted from a heated coil F are entrapped
permanently within the central magnetic field of a cylindrical
magnet M5. A second magnet M6, in opposite polarity to the poles
of the electrons causes polar tilt, and precession. This
precession radiates powerful electromagnetic field to a coil L
between the cylindrical magnet and a vacuum chamber C - wound in a
direction perpendicular to the polar axes of the electrons.
Alternatively, the electromagnetic radiation is emitted as
coherent light. The original source of electrons is shut off after
entrapment.  
  
SPECIFICATION  
  
Method and means for producing
perpetual motion with high power  
  
This invention relates to methods and means for producing
perpetual motion. An object of the invention is, therefore, to
produce useful perpetual motion for utility purposes.  
  
Brief embodiment of the invention  
  
The electron has acquired self spin from the very beginning of its
birth during the time of creation of matter, and represents a
perpetual energy. But self spin alone, without polar motion is not
functional, and therefore, useful energy cannot be derived
therefrom. Similarly, the permanent magnet represents a perpetual
energy, but since its poles are stationary, useful energy cannot
be derived from it.  
  
However, the characteristics of these two types of static energies
differ one from the other, and therefore the two types of energies
can be combined in such a manner that, the combined output can be
converted into perpetual polar motion.  
  
In one exemplary mode, a cylindrical vacuum chamber having a
filament and a cathode inside, is enclosed within the central
magnetic field of a cylindrical permanent magnet, the
magnetization of which can be in a direction either along the
longitudinal axis, or from the center to the circumferential outer
surface of the cylinder. When current is passed through the
filament, the emitted electrons from the cathode are compressed
into a beam at the center of the cylindrical chamber by the
magnetic field of the cylindrical magnet. Thus, when the current
through the filament is shut off, the electrons in the beam remain
entrapped within said magnetic field permanently.  
  
In such an arrangement, the poles of the electrons are aligned
uniformly. When a second permanent magnet is held against the beam
in repelling polarity, the poles of the electrons are pushed and
tilted from their normal longitudinal polar axes. In such tilted
orientations, the electrons now start wobbling (precessing) in
gyroscopic motions, just like a spinning top when it is tilted to
one side. The frequency of this wobbling (precessional resonance)
depends upon the field strengths of the two magnets, similar to
the resonance of the violin string relative to its tensional
stretch. The polar movements of the electrons radiate
electromagnetic field, which is receivable by an inductance for
conversion into any desired type of energy. Because of the
uniformly aligned electrons, the output field is coherent, and the
output is high.  
  
Observed examples upon which the
invention is based  
  
The apparatus can best be described by examples of a spinning top
in wobbling motion. Thus, referring to the illustration of Figure
1, assume that the spinning top T is made of magnetic material, as
indicated by the polar signs (S and N). Even though the top is
magnetic, the spin motion does not radiate any type of field, for
reception and conversion into a useful type of energy. This is due
to the known fact that, radiation is created only when the poles
of the magnet are in motion, and in this case, the poles are
stationary.  
  
When a magnet M1 is held from a direction perpendicular to the
longitudinal polar axis of the top, as shown in Figure 2, the
polar axis of the top will be tilted as shown, and keep on
spinning in that tilted direction. When the magnet M1 is removed,
however, the top will try to regain its original vertical posture,
but in doing so, it will wobble in gyroscopic motion, such as
shown in Figure 3. The faster the top spins, the faster the
wobbling motion will be.  
  
The reason that the top tilts angularly, but does not wobble when
the magnet M1 is held from horizontal direction, is that, the one
sided pull prevents the top from moving away from the magnetic
field for free circular wobble. But instead of holding the magnet
M1 from the side of the top, we may also hold the magnet from a
direction above the top, as shown in Figure 4. In this case,
however, the polar signs between the magnet and the top are
oriented in like signs, so that instead of pulling action, there
is pushing action between the magnet and the top - causing angular
tilt of the top, such as shown in Figure 4. The pushing action of
the magnetic field from above the top is now equalized within a
circular area, so that the top finds freedom to wobble in
gyroscopic rotation.  
  
The important point in the above given explanation is that, the
top tries to gain its original vertical position, but it is
prevented to do so by the steady downward push by the static
magnetic field of the magnet M2. Thus, as long as the top is
spinning, it will wobble in a steady state. Since now there is
polar motion in the wobbling motion of the top, this wobbling
motion can easily be converted into useful energy. To make this
conversion into perpetual energy, however, the top must be
spinning perpetually. And nature has already provided a
perpetually spinning magnetic top, which is called, the electron -
guaranteed to spin forever, at a rate of 1.5 x 1023 (one hundred
fifty thousand billion billion revolutions per second).  
  
Brief description of the drawings  
  
Figure 1 illustrates a
magnetic spinning top, for describing the basic principles of the
invention.  
  

![](fig1.jpg)

  
Figure 2 illustrates a
controlled top for describing the basic principles of the
invention.  
  
Figures 3 and 4 illustrate
spinning tops in wobbling states for describing the basic
principles of the invention.  
  

![](fig2.jpg)

  
Figure 5 shows how an
electron can be driven into wobbling state by control of permanent
magnets, according to the invention.  
  
Figure 6 is a practical
arrangement for obtaining perpetual motion.  
  
 

![](fig2a.jpg)

  
 Figure 7shows a natural
atomic arrangement for obtaining precessional resonance.  
Figure 8 shows a different
type of electron trapping permanent magnet, as used in Figure 6.  
  
Figure 9 is a modification
of Figure 6; and  
  

![](fig3.jpg)

  
Figure 10 is a
modification of the electron trapping magnets, as used in Figure
6.  
  
Best mode of carrying out the
invention  
  
Referring to the exemplary illustration of Figure 4, the spinning
top T is pivoted to the base B by gravity.  
  
In the case of the electron, however, it must be held tight
between some magnetic forces. Thus, referring to the illustration
of Figure 5, assume that an electron e is placed in the center of
a cylindrical magnet M4. The direction of magnetization of the
magnet M4, and the polar orientation of the electron e are marked
in the drawing. In this case, when a permanent magnet M3 is placed
at the open end of the cylindrical magnet M4, the electron e will
precess, in a manner, as described by way of the spinning top. The
difficulty in this arrangement is that, electrons cannot be
separated in open air, and a vacuum chamber is required, as in the
following:  
  
Figure 6 shows a vacuum chamber C, which contains a cylindrically
wound filament F, connected to the battery B1 by way of the switch
S1. Thus, when the switch S1 is turned ON, the filament F is
lighted, and it releases electrons.External of the vacuum chamber
C is mounted a cylindrical permanent magnet M5, which compresses
the emitted electrons into a beam at the center of the chamber.  
  
When the beam is formed, the switch is turned OFF, so that the
beam of electrons is entrapped at the center of the chamber
permanently.  
  
The permanent trapping of the electrons in the chamber C
represents a permanent storage of static energy. Thus, when a
permanent magnet M6 is placed to tilt the polar orientations of
the uniformly poled electrons in the beam, they start precessing
perpetually at a resonant frequency, as determined by the field
strengths of the magnets M5 and M6.  
  
The precessing electrons in the beam will radiate quadrature
phased electromagnetic field in a direction perpendicular to the
polar axes of the electrons.  
  
Thus, a coil L may be placed between the magnet M5 and the vacuum
chamber C, to receive the radiated field from the beam. The output
may then be utilized in different modes for practical purposes,
for example, rectified for d-c power use.  
  
The electron beam-forming
cylindrical magnet  
  
M5, which may also be called a focusing magnet, is shown to be
bipolar along the longitudinal axis. The direction of
magnetization, however, may be from the central opening to the
outer periphery of the magnet, as shown by the magnet M7, in
Figure 8.  
  
But the precessing magnet M6 will be needed in either case.  
  
In the arrangement of Figure 6, I have included a current control
grid G. While it is not essential for operation of the arrangement
shown, it may be connected to a high negative potential B2 by the
switch S2 just before switching the S1 in OFF position, so that
during the cooling period of the filament, there will occur no
escape of any electrons from the beam to the cathode. Also, the
grid G may be switched ON during the heating period of the
cathode, so that electrons are not forcibly released from the
cathode during the heating period, and thereby causing no damage
to the cathode, or filament.  
  
Biological precessional resonance  
  
Electron precessional resonance occurs in living tissue matter, as
observed in laboratory tests. This is called ESR (Electron Spin
Resonance) or PMR (Paramagnetic Resonance). In tissue matter,
however, the precessing electron is entrapped between two
electrons, as shown in Figure 7, and the polar orientations are
indicated by the polar signs and shadings, for clarity of drawing.  
  
Simulation  
  
The arrangement of Figure 7 may be simulated artificially in a
manner as shown in Figure 9, wherein, the electron trapping magnet
is a pair of parallel spaced magnets M8. In actual practice,
however, thestructure of this pair of magnets M8 can be modified.
For example, a second pair of magnets M8 may be disposed between
the two pairs, so that the directions of the transverse fields
between the two pairs cross mutually perpendicular at the central
longitudinal axis of the vacuum chamber. The inner field radiating
surfaces of these two pairs of magnets may be shaped circular, and
the two pairs may be assembled, either by physical contact to each
other, or separated from each other.  
  
Modifications  
  
Referring to the arrangements of Figures 6, 9 and 10, when the
electron is in precessional gyroscopic motion, the radiated field
in a direction parallel to the polar axis of the electron, is a
single phased corkscrew waveform, which when precessed at light
frequency, the radiation produces the effect of light.  
  
Whereas, the field in a direction perpendicular to the axis of the
electron produces a quadrature phased electromagnetic radiation.
Thus, instead of utilizing the output of electron precession for
energy purposes, it may be utilized for field radiation of either
light or electromagnetic waves, such as indicated by the arrows in
Figure 9. In this case, the output will be coherent field
radiation.  
  
In reference to the arrangement of Figure 6, the electron emission
is shown to occur within the central magnetic field of the
focusing magnet M5. It may be practically desired, however, that
these electrons are injected into the central field of the
cylindrical magnet from a gun assembly, as shown in an exemplary
arrangement of Figure 10. In this case, the vacuum chamber C is
flanged at the right hand side, for mounting an electron emitting
cathode 1 (the filament not being shown), and a curved
electron-accelerating gun 2. The central part of this flange is
recessed for convenience of mounting an electron-tilting magnet
(as shown), as close as possible to the electron beam. In
operation, when current is passed through the filament, and a
positive voltage is applied (not shown) to the gun 2, the emitted
electrons from the cathode are accelerated and injected into the
central field of the magnet 11. Assuming that the open end of the
gun 2 overlaps slightly the open end of the cylindrical central
field of the magnet M1, and the positive accelerating voltage
applied to the gun 2 is very low, the accelerated electrons will
enter the central field of the magnet My 1, and travel to the
other end of the field. Due to the low speed acceleration of the
electrons, however, they cannot spill out of the field, and become
permanently entrapped therein.  
  
In regard to the direction in which the coil L1 is positioned, its
winding should be in a direction perpendicular to the longitudinal
axis of the beam to which the polar axes of the electrons are
aligned uniformly in parallel. In one practical mode, the coil L1
may be wound in the shape of a surface winding around a tubular
form fitted over the cylindrical vacuum chamber.  
  
In regard to the operability of the apparatus as disclosed herein,
the illustration in Figure 7 shows that the field output in a
direction parallel to the polar axis of the electron is singular
phased, and it produces the effect of light when the precessional
frequency is at a light frequency. Whereas, the output in a
direction perpendicular to the polar axis of the electron is
quadrature phased, which is manifested in practiced
electromagnetic field transmission.  
  
In regard to experimental references, an article entitled
"Magnetic Resonance at high Pressure" in the "Scientific American"
by George B. Benedek, page 105 illustrates a precessing nucleus,
and indicates the direction of the electromagnetic field radiation
by the precessing nucleus. The same technique is also used in the
medical apparatus "Nuclear magnetic resonance" now used in
numerous hospitals for imaging ailing tissues (see "High
Technology" Nov. Dec. 1982. Refer also to the technique of
detecting Electron Spin Resonance, in which electrons (called
"free radicals") are precessed by the application of external
magnetic field to the tissue matter. In all of these practices,
the electromagnetic field detecting coils are directed
perpendicular to the polar axes of the precessing electrons or the
nuclei.  
  
In regard to the production of light by a precessing electron, in
a direction parallel to the polar axis of the precessing electron,
see an experimental reference entitled "Free electrons make
powerful new laser" published in "high Technology" February 1983
page 69.  
  
In regard to the aspect of producing and storing the electrons in
a vacuum chamber, it is a known fact by practice that the
electrons are entrapped within the central field of a cylindrical
permanent magnet, and they will remain entrapped as long as the
magnet remains in position.  
  
In regard to the performance of obtaining precessional resonance
of the electron, the simple example of a wobbling top is
sufficient, as proof of operability.  
  
Having described the preferred embodiments of the invention, and
in view of the suggestions of numerous possibilities of
modifications, adaptations, adjustments and substitutions of
parts, it should be obvious to the skilled in related arts that
other possibilities are within the spirit and scope of the present
invention.

  


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