Roschin & Godin: Magneto-Gravity Effects; Verification of
the Searl Effect

 
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  **[rexresearch.com](http://rexresearch.com/index.htm)**

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**V. ROSCHIN & S. GODIN**

**Magneto-Gravitational
Converter**   
 **(Searl Effect Generator)**

---



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 **[V. Roschin & S. Godin: Experimental
Research of Magnetic-Gravity Effects](#xpresmgfx)**   
  **[V. Roschin & S. Godin: *Technical
Physics Letters* 26 (12): 1105-1107 (2000) ~ "An
Experimental Investigation..."](#xpinv)**   
  **[M. Pitkanen: About Strange Effects Related
to Rotating Magnetic Systems](http://rexresearch.com/roschin/pitkanen.pdf)**   
  **[V. Roschin & S. Godin: Russian Patent #
2,155,435 ~ "Mechanical Energy Generating Device &
Process"](http://rexresearch.com/roschin/rg1.htm)**   
  **[V. Roschin & S. Godin: US
Patent # 6,822,361 ~ "Orbiting Multi-Rotor Homopolar System"](#usp)  
  
[P. Murad, et al. : Morningstar Energy Box
Replication of Roschin-Godin-Searl Generator](#murad)**



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 **Experimental Research of the Magnetic-Gravity
Effects**

by **V. V. Roschin** ( rochtchin@mail.ru )
& **S. M. Godin** (
serjio@glasnet.ru )   
Institute for High Temperatures, Russian Academy of Science,
Izhorskaya 13/19, Moscow 127412, Russia   
[ This file is reproduced by courtesy of Alex Frolov:
http://alexfrolov.narod.ru ]

![](roschin.jpg)

**Abstract ~**

In the present paper
the results of the experimental research of Magnetic-Gravity
Effects are presented. The abnormal magnetic and thermal
changes in the radius of 15  meters from the researched
device were measured as well. PACS: 41.20.-q; 44.60.+k; 
76.50.+q

**Introduction ~**

There has been a
great interest in examining nonlinear effects in the system of
rotating magnetic fields. Such effects have been observed in
the device called Searl's generator or SEG (SEG, Searl Effect
Generator) [1-4]. An SEG consists of a series of three rings
and rollers that go around those rings. All parts of SEG are
based on the Law of the Squares. The rollers revolve around
the plates that form the rings, but they do not touch them.
There's a primary north and south pole on the rollers and a
primary  north and south pole on the plates. Obviously
you will have the north pole of the roller attracted to the
south pole of the plate. The plate and the rollers have
layered structure. The external layer - Titan, then Iron,
Nylon and last internal layer was made from Neodymium. John
R.R. Searl has supposed that the electrons are given off from
the central element (which is neodymium), and they travel out
through other elements.  If nylon had not been put there,
the SEG would act like a laser and one pulse would go out and
it would stop, build up, and another pulse would go out. But,
with the nylon being, nylon acts as a control gate, and that
control gate gives you an even flow of  electrons
throughout the SEG [4]. In [4] it was shown that in the
process of  magnetization of the plate and rollers, the
combination of constant and variable magnetic fields for
creating a special wave (sine wave) pattern on a plate surface
and rollers surface was used. The basic effects are the
rollers selfrunning around a ring plate and reduction of
weight up to occurrence of propulsion and flying up of all
magnetic system. These effects come about because of a special
geometry of experimental setup. It was shown that the work of
the device in critical regime is accompanied by biological and
real physical phenomena. Unfortunately except for the listed
references we could not find other information where similar
effects are be mentioned. In this paper we present the
experimental device the results we have obtained.

**The Description
of the Experimental Installation ~**

The basic difficulty
is in a choosing the materials and maintaining the necessary
pattern imprinting on the plate and rollers surfaces. To
simplify the technology we decided to use a one-ring design
with one-ring plate (stator) and one-ring of rollers (rotor).
It is obvious, that it was necessary to strengthen the rollers
on a rotor by the bearings and balance the rollers well. In
the suggested design the air bearings were used which provided
the minimum losses due to friction. From the available
description [1-4] it was not clear how it is possible to make
and magnetize the stator with a diameter of about one meter.
In order to make the stator from separate magnetized segments
executed on the basis of rare earth magnets with the residual
induction 1T; the segments were magnetized in a usual way by
discharging capacitor battery through the coil. Afterwards the
segments were assembled and glued together in a special
iron  armature, which reduced magnetic energy. To
manufacture the stator 110 KGs of rare earth magnets were
used, and to manufacture the rotor 115 KGs of that material
was used. High-frequency field under magnetization was not
applied. It was decided to replace an imprinting technology
described in [1-4] with cross-magnetic inserts having a flux
vector directed at 90 degrees to a vector of basic
magnetization of a stator and rollers of a rotor. For these
cross inserts the modified rare earth magnets with a residual
magnetization of 1,2 T and coercive force a little bit greater
than in a base material was used. In Figure 1 and Figure 2 the
joint arrangement of stator 1, elements of a rotor - rollers 2
and a way of their mutual gearing by means of cross magnetic
inserts 19, are shown. Between the stator and roller surfaces
the air gap *d* of 1 mm is left.

No layered structure
was used except a continuous copper foil of 0.8 mm thickness
which wrapped up the stator and rollers. This foil has the
direct electrical contact to magnets of a stator and rollers.
Distance between inserts in the rollers is equal to distance
between inserts on the stator.

**Figure 1: Variant
of One-Ring Converter ~**

The ratio of
parameters of the stator 1 and the rotor 2 in Figure 2 is
chosen so that the relation of stator diameter  D and
roller diameter d is an integer equal to or greater then 12.
Choosing such a ratio allows us to achieve a magnetic spin
wave resonant mode between elements of a working body of the
device.

![](rogo1.jpg)

**Figure 2:
Organization of Magnetic Gearing Stator & Rollers ~**

The elements of
magnetic system were assembled in a uniform design on the
aluminium platform. In Figure 3 the general view of the
platform with one-ring converter is displayed. This platform
was supplied with springs, amortizators and had a possibility
of moving vertical on three supports. The value of
displacement was measured by the induction meter of
displacement 14; thus the change of the platform weight at
once has been defined during the experiment in real time.
Gross weight of the platform with magnetic system in the
initial condition was 350 KGs.

![](rogo2.jpg)

**Figure 3: General
View of the Platform with One-Ring Converter ~**

![](rogo3.jpg)

The stator 1 was
mounted motionlessly, and the rollers 2 were assembled on a
mobile common separator 3, connected with the basic shaft 4 of
the device. Through this shaft the rotary moment was
transferred. The basic shaft by the means of friction muff 5
was connected to the electrodynamics generator 7 and starting
engine 6, which accelerated the converter up to a mode of
self-sustained rotation. Along a rotor the electromagnetic
inductors 8 with open cores 9 were located. The magnetic
rollers 2 crossed the open cores of inductors and closed the
magnetic flux through electromagnetic inductors 8, and induced
emf in them, which acted directly on an active load 10 (a set
of incandescent lamps with total power 1 kW). The
electromagnetic inductors 8 were equipped with an electrical
drive 11 and had an opportunity to smoothly move on supports
12. To study the influence of the external high voltage on the
characteristics of the converter the system of radial
electrical polarization was  mounted. On periphery of the
rotor ring electrodes 13 were set between the electromagnetic
inductors 8 having with the rollers 2 air gap of 10 mm. The
electrodes are connected to a high-voltage source; the
positive potential was connected to the stator, and the
negative to the polarization electrodes. The voltage was
adjusted in a range of 0-20 kV. In experiments the constant
value of 20 kV was used. In case of emergency braking,
friction disk from the ordinary car braking system was mounted
on a basic shaft of the rotor. The electrodynamics generator 7
was connected to active load through a set of switches
ensuring step connection of the load from 1 kW to 10 kW. The
converter under going testing had in its inner structure the
oil friction generator of thermal energy 15, intended for
taping a superfluous power (more than 10 kW) into the
thermo-exchange contour. But since the real output power of
the converter in experiment has not exceeded 7 kW, the oil
friction thermal generator was not used. The complete
stabilization of revolutions of the rotor was carried out by
electromagnetic inductors connected to an additional load,
which was set of incandescent lamps with total power 1 kW.

**Experimental
Results ~**

The magnetic-gravity
converter was built in a laboratory  room on three
concrete supports at a ground level. The ceiling height the
lab room was  3 meters. Besides the presence of the
iron-concrete ceiling, in immediate proximity from the
magnetic system there was a generator and electric motor,
which contained some tens KGs of iron and could potentially
deform the field's pattern. The device was started by the
electric motor, which accelerated the rotation of the rotor.
The revolutions were smoothly increased up to the moment the
ammeter included in a circuit of the electric motor started to
show zero or lower value of a consumed current or even a
presence of the back current. The presence of the back current
is detected at approx. 550 rpm. The magnetic moving sensor 14
starts to detect the change in weight of the whole
installation at 200 rpm. Afterwards the electric motor is
completely disconnected by the electromagnetic muff and the
ordinary electrodynamics generator is connected to the basic
shaft of the device through the same muff. The rotor of the
converter continues to self-accelerate and with the approach
to the critical mode of 550 rpm, the weight of the device
quickly changes. In addition to the change speed of rotation
the weight depend of the power, removed into active load, (the
set of ten ordinary electrical water heaters of 1 kW was used)
and of the applied polarizing voltage, as well. At the maximum
output power equal to 6-7 kW the change of weight G of the
whole platform (total weight is about 350 KGs), reaches 35 %
of the weight in an initial condition G?. A load of more than
7 kW results in a gradual decrease of revolutions and exit
from the mode of self-generation with the subsequent complete
stop of the rotor. The weight of a platform can be controlled
by applying of a high voltage to cellular ring electrodes
located at a distance of 10 mm from external surfaces of the
rollers. Under the high 20 kV voltage (electrodes negative
pole) the increase of taped power in circuit of the basic
generator more than 6 kW does not influence G while the
revolutions per min is not decreased to 400 rpm. "Tightening"
of this effect is observed as well as the effect of hysteresis
on G (a kind of "residual induction"). The experimental
diagrams given on Fig.4 illustrate the modes of the converter
operations.

**Figure 4: Modes
of Operation of the Magnet-Gravity Converter ~**

![](rogo4.jpg)

The effect of a
local change of the platform weight is convertible relative to
the direction of rotor turning, and has the same hysteresis.
At clockwise rotation the critical mode comes in the area of
550 rpm and the propulsion force against the direction of
gravitation vector is created, by analogy, at
counter-clockwise rotation the critical mode comes the in area
of 600 rpm and the propulsion on the direction of gravitation
vector is created. The difference in approach to a critical
mode of 50-60 rpm was observed. It is necessary to mention
that the most interesting region lies above the critical area
of 550 rpm, but due to of a number of circumstances the
implementation of such research was not possible. Other
interesting effects include the work of the converter in the
dark room when corona discharges are observed around the
converter's rotor as a blue-pink glowing luminescence and a
characteristic ozone  smell. The cloud of ionization
covers the area of a stator and a rotor and has accordingly
toroidal form. On the background of luminescence glowing on
rollers' surfaces we distinguished wave picture. A number of
more vigorous strips of discharges around the rollers were
observed. These discharges were of the white - yellow colour
is, but the characteristic for the arc discharges sound was
not audible.  One more effect previously not mentioned
was observed i.e. the vertical magnetic  "walls" around
the installation. We noticed and measured the abnormal
permanent magnetic field around the converter in the radius of
15 meters. The zones of an  increased intensity of a
magnetic flux 0,05T located concentrically from the centre of
the installation were detected. The direction of 
magnetic field vector in these walls coincided with the
direction of rollers' field vector. The structure of these
zones reminded circles on water from the thrown stone. Between
these zones a portable magnetometer, which used the Hall's
sensor as a sensitive element, did not register abnormal
magnetic fields. The layers of an increased intensity are
distributed practically without losses up to a distance of
about 15 meters from the centre of the converter and quickly
decrease at the border of this zone. The thickness of each
layer is about 5 - 8 cm. The border of each layer has sharp
shape, the distance between layers is about 50 - 60 cm and it
slightly accrues when moving from the centre of the converter.
The steady picture of this field was observed as well at a
height of 6 m above the installation (on the second floor
above the lab.). Above the second floor the measurements were
not carried out. The abnormal fall of the temperature in
direct affinity from the converter was also found. While the
common temperature background in laboratory was + 22? (2?) the
fall of temperature equal to 6-8? was noticed. The same
phenomenon was observed in vertical magnetic walls as well as.
The measurements of temperature inside the magnetic walls were
carried out by the ordinary alcohol thermometer with inertia
of indication about 1,5 min. In the magnetic walls the
temperature changes can be distinctly observed even by hand.
The hand when placed into this magnetic wall feels real cold
at once. The similar picture was observed at the height above
installation, i.e. on the second floor of the laboratory as
well as despite the ferro-concrete blocking of ceiling.

**Discussion ~**

All the results we
obtained are extremely unusual and require some theoretical
explanation. Unfortunately the interpretation of results
within the framework of the conventional physical theory
cannot explain all the observed phenomena and first of all the
change of weight. The change of weight is possible to
interpret as a local change of gravity force or as an
occurrence of propulsion force by repelling from its own
field.

Direct experiment,
confirming a presence of draft force was not performed, but in
any case both interpretations of the weight change do not
correspond to the modern physical paradigm and demand
reconsideration of the standard theory of gravitation or
criticism of the second law of Newton, both of which are only
possible if we take into consideration the now-advert physical
media ether as understood by   Faraday-Maxwell-Mie.
From the modern physics position electrization and
luminescence of the converter's magnetic system in the near
zone is not completely clear. The phenomenon of the magnetic
and thermal "walls" may be connected with  Alphen's
magnetic-sound waves raised in near zone in magnetized plasma
induced by a variable magnetic field of a rotating rotor [5].

At the present time
we can not give an exact description of the interactions
mechanism with environment and transformation of energy, but
it is completely obvious, that without the use of the concept
of physical media --- the ether in a sense of
Faraday-Maxwell-Mie we are completely unable to give
physically substantial theory of these phenomena. In
conclusion, we emphasize that the issues of the biological
influence effects and especially of the variations of real
time stream effects, which must be taking place in an
operative zone of the converter, were not considered at
all.  These issues are extremely important and absolutely
unexplored; though there are some mentions of J.R.R.Searl
about healing action of the SEG's radiation. Our own
experience allows to make only cautious assumption that the
short-term stay (dozen minutes) in a working zone of the
converter with the fixed output power of 6 kW remains for the
people without observed consequences. The present paper is
only a  beginning.

**References ~**

1. Herbert
Schneider, Dr. J.B. Koeppl, Hans-Joachim Ehlers: "Begegnung
mit John R.R. Searl"; *Raum und Zeit*, #39 (1989), pp.
75-80.   
2. S. Gunnar Sandberg: "Was ist Dran am Searl-Effect; *Raum
und Zeit*, #40 (1989), pp. 67-75.   
3. Herbert Schneider & Harry Watt: "Dem Searl-Effect auf
der Spur"; *Raum und Zeit*,  # 42 (1989), pp.75-81;
#43, pp.73-77.   
4. John A. Thomas, Jr.: "Anti-Gravity: The Dream Made
Reality"; *Extraordinary Science*, VI (2) 1994.   
5. L.D.Landau, E.M.Lifshits: *Electrodynamics of Continuous
Media*; Moscow, Nauka, 1982. (in Russian)

---

  
   
 **Technical
Physics Letters** 26 (12): 1105-1107 (2000) 


**"An
Experimental Investigation of the Physical Effects in a
Dynamic Magnetic System"**

**V.V. Roschin
& S.M. Godin**   
Inst. of High Temperatures, Russian Academy of Sciences,
Moscow, Russia

**Abstract ~**

It is demonstrated
that a magnetic system based on rare-earth magnets is capable
of converting various forms of the energy, provided that a
certain critical operating regime is set up. As the critical
regime is attained, the experimental setup becomes
energetically fully autonomous. This is accompanied by local
variations in the total structure weight, a decrease in the
surrounding air temperature, and the formation of concentric
"magnetic walls" at a distance of up to 15 meters from the
experimental setup.

**Introduction ~**

We have
experimentally studied the physical effects in a system based
on rotating permanent magnets (1). Below we describe the
technology of manufacture, assembly, and the results of
testing this experimental setup, which is referred to as the
converter.

**Technological
Description ~**

The converter
comprises an immobile stator and a rotor moving around the
stator and carrying fixed magnetic rollers. The magnetic
system of the working body of the converter has a diameter of
about 1 meter. The stator and magnetic rollers were
manufactured from separate magnetized segments made of
rare-earth magnets (REMs) with a residual magnetization of
0.85 T, a coercive force of [Hc] ~ 600 kA/m, and a specific
magnetic energy of [W] ~ 150 K/m3. The segments were
magnetized by a conventional method based on a discharge of a
capacitor bank through an inductor coil. Then the magnetized
segments were assembled and glued together in a special
mounting stage, which provided for the necessary tolerance in
positioning the segments and for the removal of magnetic
energy. Using this mounting stage, it was possible to glue the
elements into the common unit. The stable incorporated REMs
with a total weight of 110 kg and the rollers contained 115 kg
of the same REM material.

The magnetic system
elements were assembled into a single structure on a special
platform made of non-magnetic structural alloys. The platform
construction was provided with springs and shock absorbers and
allowed the converter setup to move in the vertical direction
on three sides. The motion was monitored by an inductive
transducer. Which allowed changes ion the platform weight to
be determined in the course of the experiment. The total
weight of the platform with the magnetic system in the initial
state was 350 kg.

**Description of
the Observed Effects ~**

The converter was
installed in a 2.5-meter high laboratory room using three
concrete supports on a ground level. In addition to the
ordinary steel-reinforced concrete ceiling blocks, the
converter equipment featured a usual electrodynamic generator
and an electric motor, with a total iron weight of several
tens of kilograms (only these parts could, in principle,
introduce distortions into the electromagnetic field pattern
observed).

The converter was
set to operate by over-speeding the rotor with the aid of the
electric motor. The motor speed was gradually increased until
the ammeter connected in the motor circuit showed zero
consumed current and the current direction reversal. This
state corresponded to a rotor speed of approximately 550 rpm,
but the motion transducer began to indicate a change in the
platform weight already at 200 rpm. Then the electric motor
was disconnected using an electromagnetic overrunning clutch,
and a usual electrodynamic generator was connected instead to
the main shaft of the converter via another electromagnetic
clutch. On attaining the critical regime (~550 rpm), the rotor
exhibited a sharp increase in the rotation speed; this was
accompanied by a slow-down in the rate of the current weight
reduction. At this instant, the first 1 kW load was connected
to the system. Immediately upon this connection, the rotation
speed began to decrease, while the Delta G value kept
increasing, and so on as depicted in the figure.

![](rogo4.jpg)

A diagram
illustrating various operation regimes of the
magnetogravitational converter showing (I) load power (kW) and
system weight variation; (II) 7-kW load (high voltage off);
(III) 7-kW load (high voltage on); (IV) supercritical regime;
(V) subcritical regime (1, high voltage off; 2, high voltage
on).

The system weight
variation depend both on the power consumed by the active load
(the load consisted of 10 ordinary 1-kW heating elements) and
on the polarization voltage applied. For a maximum consumed
power (7 kW), a change in the total platform weight reached
35% of the initial value in the immobile state (350 kg), which
corresponded to 50% of the pure weight of the working body of
the converter. An increase in the load power above 7 kW led to
a gradual decrease in the rotor speed and, eventually, to the
system going out of the self-generation regime and the rotor
speed decreasing until the full stop. The platform weight
could be controlled by applying a high-voltage signal to the
cellular ring electrodes situated 10 mm above the external
roller surface. Upon applying a 20 kV signal (negative
polarity on the electrodes), an increase in the load power
consumption above 6 kW did not affect the Delta G value even
when the rotor speed decreased down to 400 rpm. This was
equivalent to "prolongation" of the effect and was accompanied
by phenomena of the remnant induction" type with respect to
Delta G. The converter operation in various experimental
regimes is illustrated in the figure.

The effect of the
system weight variation is reversible with respect to the
direction of rotor motion and exhibits certain hysteresis. For
the clockwise rotation, the critical regime is observed in the
region of 550 rpm and is accompanied by development of the
force acting against the gravity vector. For the
counter-clockwise rotation, the onset of the critical regime
is observed at approximately 600 rpm and the extra force
coincides in direction with the gravity vector. The onset of
the critical regime exhibited a scatter within 50-60 rpm. It
should be noted that, probably, some other critical resonance
regimes may exist, which correspond to higher rotor speeds and
markedly greater useful load levels. Proceeding from the
general theoretical consideration, the output mechanical
energy must nonlinearly depend on the internal parameters of
the converter magnetic system and the rotor speed, so that the
observed effects are likely to be far from optimum.
Establishing of the maximum output power maximum weight
variation, and the converter energy resource is of
considerable theoretical and practical interest.

Besides the
phenomena described above, a number of other interesting
effects were observed in the system studied. In particular,
the converter operation in the dark is accompanied by a corona
discharge with a pink-blue light emission and by the
production of ozone. The ionization cloud is formed around the
stator and rotor, acquiring a toroidal shape. The general
corona discharge background is superimposed with a wavy
pattern corresponding to the surface of the rollers: the zones
of increased emission intensity are distributed along the
roller height in a manner similar to that observed for the
high-voltage microwave induction energy storage in the
pre-breakdown state. These zones appeared yellowish-white, but
the emission was not accompanied by sounds characteristic of
the arc discharge. Nor did we observe any visible erosive
damage on the stator and rotor surfaces.

One more effect,
which was never reported previously, is the appearance of
vertical "magnetic walls" surrounding the setup. We have
detected and measured an anomalous constant magnetic field
around the converter. The measurements revealed zones of
increased magnetic strength on the order of 0.05 T arranged
coaxially relative to the system center. The direction of the
magnetic field vector on the "walls" coincides with that in
the rollers. The structure of these magnetic zones resembles
the pattern of circular waves on the water surface. No
anomalous field is detected by a mobile magnetometer,
employing the Hall effect transducer, in the area between
zones. The layers of increased magnetic field strength are
propagating with virtually no attenuation to a distance of 15
meters from the converter center and then rapidly decayed at
the boundary of this 15-meter area. Each layer zone is 5-8 cm
thick and exhibits sharp boundaries. The layers are spaced by
50-60 cm, the spacing slightly increasing with the distance
from the converter center. A stable pattern was also observed
at  a height of 5 meters above the setup (the
measurements were conducted in a 2nd floor room above the
laboratory; no tests were conducted on a still higher level).

Another interesting
phenomenon consists in an anomalous temperature drop in the
immediate vicinity of the converter. At a general room
temperature level in the laboratory (+22 +-2 C), the
temperature at the converter surface was 6-8 C lower. Similar
temperature variations were detected in the vertical magnetic
"walls". The temperature changes in the walls were detected by
an ordinary alcohol thermometer with a reading set time of 1.5
minutes. The temperature variations in the magnetic "walls"
can even be sensed by the human body: a hand placed inside the
"wall" immediately feels cold. The same pattern was observed
at a height of 5 meters above the setup in a 2nd floor room
above the laboratory (despite the steel-reinforced concrete
blocks separating the rooms).

**Discussion of
Results ~**

All the experimental
results described above are very unusual and need some
theoretical rationalization. Unfortunately, attempts at
interpreting the obtained results within the framework of the
existing physical theories showed that no one of these models
can explain the whole set of experimental data.

Recently, Dyatlov
(2) attempted to combine the concepts of electricity and
gravity by introducing the so-called electronavigation and
magnetic-spin coefficients into the Heaviside gravity
equations and the Maxwell field equations. This provides for a
relationship between the gravitational and electrical
components, as well as between the magnetic and rotational
components in a given medium. The assumptions are built around
a special model of inhomogenous physical vacuum, called the
vacuum domain model (2). It is suggested that the extra
relationships are absent outside the vacuum domain. Although
it is difficult to imagine a long-living vacuum domain, the
proposed model provides for a satisfactory explanation (at
least on a qualitative phenomenological level) for the
appearance of emission, the system weight variations, and the
conversion of energy taken from the surrounding medium into
the rotational mechanical moment of the rollers.
Unfortunately, the theory cannot provide a physical pattern of
the observed phenomena.

**Conclusion ~**

At present, the work
on a developed variant of the converter are in progress at the
Glushko "NPE Energomash" company (Moscow). This setup would
allow a deeper insight into the physics of observed phenomena.
Another aim is the creation of commercial samples for various
practical applications.

**References ~**

(1) Thomas, J.A.: *Anti-Gravity:
The Dream Made Reality ~ The Story of John R.R. Searl*;
Direct International  Science Consortium, London, 1994),
Vol. 1, Issue 2.   
(2) Dyatlov, V.L.: *Polarization Model Heterogenous
Physical Vacuum* (Inst. Mat., Novosibirsk, 1998);
Translated by P. Pozdeev.

---

**[M. Pitkanen: About Strange Effects
Related to Rotating Magnetic Systems](http://rexresearch.com/roschin/pitkanen.pdf)**

 An explanation
of the Roschin-Godin experiment in terms of Topological
Geometro-Dynamics (TGD). [PDF]

---

**Russian Patent # 2,155,435**  
**Mechanical Energy Generating Device &
Process**

 
**[ [PDF](http://rexresearch.com/roschin/RU2155435C1.pdf) ]**
 
Publication
date:  2000-08-27   
Application Number:  RU19990122275 19991027 ~ Priority
Number(s):  RU19990122275 19991027   
IPC Classification: H02N11/00; F03H5/00 

**Abstract ~**

Power engineering
and transport; miscellaneous industries.  UBSTANCE:
Single-row power module has stator and rotor with rollers
combined by common separator. Stator and rotor are made of
permanent magnets or electromagnets based on composite
laminated magnetic, conducting, and insulating materials. Main
shaft of device is coupled via free-wheel clutches with
starting motor that brings device to automatic
speed-maintaining mode of operation and device loading system
which is, essentially, electrodynamic generator mechanically
coupled with main shaft of device. Electromagnetic transducers
are radially arranged on device periphery. Propulsion control
is effected by adjusting mechanical energy taken off the
device and by producing radial electric polarization on its
periphery by means of annular electrodes separated from rotor
rollers by air gap. Electrodes are connected to high-voltage
power supply. Generating process includes electric power
supply to starting gear, acceleration of rotor shaft to
working speed, take-off of generated energy, and adjustment of
mentioned energy and propulsion by varying rotor and stator
speed through varying load of generator connected to device as
well as by adjusting high voltage applied from external power
supply. EFFECT: Reduced energy consumption. 9 cl, 17 dwg.

![](rg2.jpg) ![](rg3a.jpg)  
 ![](rg3b.jpg)  ![](rg3c.jpg)  
   
 ![](rg3d.jpg) ![](rg3e.jpg)  
   
 ![](rg3f.jpg)   ![](rg3g.jpg)  
   
 ![](rg3h.jpg)  

 
---

**US Patent # 6,822,361** **Orbiting Multi-Rotor Homopolar System  
  
[ [PDF](http://rexresearch.com/roschin/US6822361B1.pdf) ]**

**Roschin;
Vladimir Vitalievich** (Moscow, RU); **Godin; Sergi
Mikhailovich** (Moscow, RU)

**Abstract --** An
orbiting multi-rotor homopolar machine employs axially
parallel, cylindrical, electrically conductive magnets
arranged circumferentially around vertical axis of central
stator ring, intimately contacting and engaging non-slip
rolling between rotor magnets and stator. A bearing rotatably
secures each end of each magnet to a corresponding
electrically conductive circular endplate, each slightly wider
than the stator. An electrically conductive axle located in
the center of the stator rigidly attaches to one of the top
circular endplate, and an electrically insulating bearing
means attaches the center of bottom circular endplate to a
coaxial inner cylinder, located between the axle and the
stator.

**Assignee: Energy
& Propulsion Systems LLC** (Valencia, CA)

**References Cited**
  
 **U.S.
Patent Documents:**   
406,068 ~ Jul., 1889 ~ Tesla ~ 310/178   
645,943 ~ Mar., 1900 ~ Dalen, et al. ~ 310/178   
3,185,877 ~ May., 1965 ~ Sears ~ 310/178   
3,465,187 ~ Sep., 1969 ~ Breaux ~ 310/178   
5,241,232 ~ Aug., 1993 ~ Reed ~ 310/178   
5,278,470 ~ Jan., 1994 ~ Neag ~ 310/178   
5,977,684 ~ Nov., 1999 ~ Lin ~ 310/178   
6,051,905 ~ Apr., 2000 ~ Clark ~ 310/178   
 **Foreign
Patent Documents:**   
2,094,066 ~ Sep., 1982 ~ GB   
2000-324,786 ~ Nov., 2000 ~ JP   
2001-286,117 ~ Oct., 2001 ~ JP   
2003-47,226 ~ Feb., 2004 ~ JP

*Primary Examiner:*
Mullins; Burton ~ *Attorney, Agent or Firm:* Our Pal LLC

***Description ~***

FIELD OF THE
INVENTION

This invention
relates generally to the field of direct current electrical
motors and generators that operate without the need for
commutation and/or rectification, and more particularly to
multi-rotor homopolar machines which derive their emf
(electromotive force) from co-rotational magnets and metallic
disk embodiment.

BACKGROUND

Back in 1831,
Michael Faraday discovered that a cylindrical magnet suspended
by a string and touching a mercury bath at the bottom could
generate electricity while spinning along its axis if a second
electrical contact was made at the periphery of the midpoint
of the magnet. His experiment was a one-piece homopolar
machine since the magnet and conductor were joined together.
Such Faraday generators have also been called acyclic,
unipolar or homopolar generators because no commutation or
alternating of the magnetic poles is necessary for this
machine in order to generate electricity.

The type of
electrical output is most often direct current (DC) unless
specific means are designed to provide an interruption of
radial conduction and thus simulate alternating current (AC).
Historically, DC was championed by Thomas Edison during the
early part of the 20th century while at the same time AC was
championed by Nikola Tesla and George Westinghouse. In the
future, DC will be coming back into style with the emergence
of ambient temperature superconductive cables. Therefore,
highly efficient homopolar generators will be in demand to
meet the future market demand for DC electricity.

Homopolar generators
usually have a single disk or drum rotating in a stationary
magnetic field with sliding contacts. The sliding contacts
often present high resistance however. The construction and
operation of homopolar machines for electric propulsion of
marine vessels or railguns for example is already well known.
Such machines include motors and generators wherein electrical
current flows through a conductor situated in a magnetic field
during rotation of the machine rotor.

In the case of a
homopolar motor, the current will develop a J.times.B force
perpendicular to the direction of its flow through the
conductor and that of the magnetic field. In the case of a
homopolar generator, a voltage dependent on the rotational
speed, magnetic field, and radius, is induced in a conductor
moving within the magnetic field. When current is drawn from
the homopolar generator, it also develops a J.times.B force
for the same reason as with the motor but is referred to as
back torque or armature reaction. General reference
information including basic principles used to reduce back
torque can be found in The Homopolar Handbook by Thomas Valone
(ISBN 0-9641070-1-5).

The prior art rarely
includes a one-piece homopolar machines that rotate the magnet
with the disk. Even more unknown is the concept of rolling
contacts. Eliminating sliding contacts is shown in the
"Planetary Homopolar Generator," IBM Technical Disklosure
Bulletin, Vol. 17, No. 6, p. 1786-87, November, 1974, H. D.
Varadarajan.

Using a conducting
belt or rolling contacts to gather current from a magnetic
field flux cutting rotor, there is an annular magnetic field
through which the rotor executes a planetary motion.

The large stresses
resulting from the centrifugal force of the massive,
unbalanced planetary rotor is a distinct disadvantage,
prohibiting high speed operation. Thus, only a low rate of
rotation is possible with the IBM design.

The "Direct Current
Homopolar Machine" U.S. Pat. No. 5,587,618 to Hathaway
demonstrates an analogous concept of relative motion between
conductive orbiting shaft and a stationary disk-shaped
magnetized armature.

However, the design
is a bit cumbersome to be practical. Science Applications
International Corporation claims a conductive belt, dual disk
"Homopolar Motor-Generator" in U.S. Pat. No. 5,241,232 to Reed
that apparently reinvents the "Dynamo Electric Machine" of
U.S. Pat. No. 406,968 patented by none other than Nikola Tesla
in 1889 that also has two unipolar magnetized rotors connected
by a conductive belt. The belted dual unipolar machines solve
one of the problems that plague the field by offering two
sliding contacts at the low speed surface on the axle.
However, the present invention requires only one sliding
contact on the axle. These conductive belt machines also
demonstrate, in principle, the concept of a multi-rotor,
planetary design, by the process of coordinate transformation,
since relative motion is the key to the operation of a
homopolar generator. The concept of rolling contact is
demonstrated with the Dalen "Dynamo Electric Machine" U.S.
Pat. No. 645,943, where two disks are turning in opposite
directions while in contact with each other at their
periphery. However, the axle of each disk must remain fixed in
place whereas each axle is in orbiting motion in the present
invention.

Homopolar machines
can reversibly function as motors as well, such as flywheels,
and used as energy storage devices. First used in
transportation applications in the 1950's, flywheel powered
buses were designed to have the flywheel accelerated at every
stop. Composite rotors currently have been developed which can
spin at very high revolutions (100,000 revolutions per
second); and the speed is limited by the tensile strength of
the rim of the rotor. By using a multi-rotor design, the
centrifugal forces of a large disk can be greatly reduced and
still maintain high-energy storage or production. By using
magnetic bearings, the friction on the axis of the rotor can
be reduced sufficiently so that such rotors can maintain most
of the energy for several days.

The IBM Varadarajan
planetary rotor is unbalanced and has a low rate of magnetic
flux cutting due to its annular magnetic field design. The
Hathaway direct current machine has a lot of unbalanced
conductive material orbiting the central magnetized disk which
limits the rotational speed.

The conductive belt
designs can be subject to oxidation and slippage, even
requiring a toothed timing belt on each axle as well. With
most disk models of homopolar generators, as opposed to drum
designs, sliding contacts are the single most important
contribution of resistance inhibiting the power output of the
machine. Internal resistance is the only limit to the output
capability of a homopolar generator and it is important to
reduce all sources of internal resistance to obtain maximum
power output for a given input torque. Rather than use high
resistance carbon brushes, medium resistance silver-graphite
brushes or dangerous conductive liquids such as mercury, low
temperature solder, or sodium-potassium, there is a need to
eliminate frictional sliding contact at the high speed
periphery of the magnetized rotor completely. Furthermore,
rather than maintaining two sliding contacts which contribute
friction and resistance, even in the rolling and belted
designs, there is a need to cut the number in half to only one
high current sliding contact. The present invention satisfies
both of these needs.

SUMMARY

The present
invention derives direct current electricity by co-rotating a
plurality of magnets and a metallic disk. It comprises an
improved homopolar machine with dynamically balancing, axially
parallel, cylindrical, electrically conductive magnets
arranged circumferentially around the vertical axis of central
stator ring. Such a design can be referred to as distributed
generation since each magnet rotor generates only a fraction
of the current that is transmitted through the machine. Thus,
the conductive bearings contacting the center of each end of
the magnet rotors may carry only one tenth or less of the
total current.

The multi-rotor
orbiting homopolar also does not include sliding contacts at
each magnetized rotor rim but instead utilizes a suitable
rolling means attached separately to magnets and also to the
stator ring for intimately contacting and engaging non-slip
rolling between magnets and stator as they orbit around the
stator. The magnetized rotors maintain rotational synchronism
and equal relative position to each other with a bearing means
rotatably securing the top and bottom end of each magnet to a
corresponding electrically conductive circular endplate.

The electrical
energy is extracted, or input if used as a motor, through
contacts on the conductive stator and at the machine's
electrically conductive axle located in the center of the
machine while rigidly attached to the top circular endplate
that rotates with all of the individually magnetized rotors.
The only single, high current, moving contact that is required
is an electrically conductive thrust bearing that supports the
central axle. An insulating thrust bearing meanwhile separates
the axle from the center of bottom circular endplate. The
stator, which is of course stationary, accomplishes the second
contact means through a standard electrical connection with no
need for any relative motion sliding contact. The stator may
be optionally magnetized in the opposite direction to the
magnetized rotors in order to increase the coercive force or
magnetic flux density.

The drawings
constitute a part of this specification and include exemplary
embodiments to the invention, which may be embodied in various
forms. It is to be understood that in some instances various
aspects of the invention may be shown exaggerated or enlarged
to facilitate an understanding of the invention.

*The Problem ~*

The problem this
invention solves is that it generates high power direct
current electricity without the need for commutation and
rectification, otherwise the internal resistance losses are
high.

The problems with
prior art devices, processes and systems can be categorized as
follows.

1. Require
commutation or rectification to generate direct current
electricity.

2. Rely on more than
one current brush which often have high speed contact.

3. Do not distribute
magnetic field power generation by multi-rotor orbiting
magnets in homopolar machines or systems.

4. Internal
resistance losses are usually high.

5. Neither efficient
nor cost effective.

6. Neither simple
nor practical for most applications.

*Prior Art ~*

A preliminary
limited prior art search was not commissioned but the inventor
is intimately familiar with the prior art. Following are
typical examples of the prior art arranged in reverse
chronological order for ready reference of the reader.

11) Non-Provisional
Utility U.S. Pat. No. 6,051,905 issued to Richard Clark on
Apr. 18, 2000 for "Homopolar Generator"

10) Non-Provisional
Utility U.S. Pat. No. 5,977,684 presented to Ted Lin on Nov.
2, 1999 for "Rotating Machine Configurable as True DC
Generator or Motor"

09) Non-Provisional
Utility U.S. Pat. No. 5,864,198 earned by Joseph Pinkerton on
Jan. 26, 1999 for "Brushless Generator"

08) Non-Provisional
Utility U.S. Pat. No. 5,587,618 issued to George Hathaway on
Dec. 24, 1996 for "Direct Current Homopolar Machine"

07) Non-Provisional
Utility U.S. Pat. No. 5,278,470 graced upon Zacharias Neag on
Jan. 11, 1994 for "Homopolar Machine which acts as a Direct
Current (DC) High Voltage Generator or Motor"

06) Non-Provisional
Utility U.S. Pat. No. 5,241,232 honorably given to Jay Reed on
Aug. 31, 1993 for "Homopolar Motor-Generator"

05) Non-Provisional
Utility U.S. Pat. No. 5,011,821 published in the name of
Charley McCullough on Apr. 30, 1991 for "Method and Apparatus
for Generating Electricity"

04) Non-Provisional
Utility U.S. Pat. No. 3,465,187 issued to Onezime Breaux on
Sep. 2, 1969 for "Homopolar Generator Having Parallel
Positioned Faraday Disk Structures"

03) Non-Provisional
Utility U.S. Pat. No. 3,185,877 presented to Anthony Sears on
May 25, 1965 for "Direct Current Homopolar Generator"

02) Non-Provisional
Utility U.S. Pat. No. 645,943 graced upon inventor Gustaf
Dalen on Mar. 27, 1900 for "Dynamo Electric Machine"

01) Non-Provisional
Utility U.S. Pat. No. 406,968 bestowed upon none other than
Nikola Tesla himself in 1889 for "Dynamo Electric Machine"

None of the prior
art devices known to the applicant or his attorney disclose
the EXACT embodiment of this inventor that constitutes a
simple, elegant and affordable system for an orbiting
Multi-Rotor Homopolar direct current electricity generation

*Objectives ~*

Unfortunately none
of the prior art devices singly or even in combination provide
for all of the objectives as established by the inventor for
this system as enumerated below.

1. It is an
objective of this invention to provide devices, method and
system for generation of high power direct current electricity
without commutation and rectification.

2. The primary
objective of the invention is orbiting multi-rotor cylindrical
magnets in rolling contact that eliminates friction while
generating DC electricity.

3. Another objective
of the invention is to provide high efficiency, low noise and
low resistance in a high current generator.

4. Another objective
of the invention is that it uses readily available materials
in a dynamically balanced arrangement.

5. Another objective
of the invention is safety through reduced internal stress
than comparable homopolar machines with a single rotor.

6. Another objective
of the invention is that it provides distributed generation
around an air core.

7. Another objective
of this invention is to provide an easy, quick, simple
practical way to generate more efficient and cost effective
direct current electricity.

8. Another objective
of this invention is that it promote and encourage other
inventors to do additional research in homopolar machines
generally but co-rotational magnets and disk embodiments in
particular.

9. Another objective
of this invention is to provide a system that is integrated
and flexible.

10. Another
objective of this invention is to provide a system that is
easily useable and requires little if any training for
manufacturing and use.

11. Another
objective of this invention is that it meet all federal,
state, local and other private standards guidelines,
regulations and recommendations with respect to safety,
environment, and energy consumption.

12. Another
objective of this invention is that it can be made from
modular standard materials and components that are also easily
maintainable.

Other objectives
advantages and features of this invention reside in its
simplicity, elegance of design, ease of manufacture, service
and use and even aesthetics as will become apparent from the
following brief description of the drawings and the detailed
description of the best mode preferred embodiments taken in
connection with the accompanying drawings.

BRIEF DESCRIPTION OF
THE DRAWINGS

**FIG. 1** is a
prior art diagram of a typical homopolar generator.

![usp 6822361 fig 1](usp1.jpg)  
 

**FIG. 2** is a
perspective, cutaway view of the magnetized rotor and stator.

![usp 6822361 figs 2-3](usp2-3.jpg)

**FIG. 3** is an
elevational view of the complete orbiting multi-rotor machine.

**FIG. 4** is a
cross sectional view of the invention.

![usp 6822361 fig 4](usp4.jpg)

**FIG. 5** is a
plan view from the top of the invention.

![usp 6822361 fig 5](usp5.jpg)

DETAILED DESCRIPTION
OF THE BEST MODE PREFERRED EMBODIMENT

As shown in the
drawings wherein like numerals represent like parts throughout
the several views, there is generally disclosed in FIG. 1 is a
state of the prior art.

Detailed
descriptions of the preferred embodiment are provided herein.
It is to be understood, however, that the present invention
may be embodied in various forms. Therefore, specific details
disclosed herein are not to be interpreted as limiting, but
rather as a basis for the claims and as a representative basis
for teaching one skilled in the art to employ the present
invention in virtually any appropriately detailed system,
structure or manner.

Turning first to
FIG. 2 there is shown a perspective cutaway view of a portion
of one embodiment of the present invention showing one of a
multitude of rotors that are axially magnetized (B). This
multitude mounted in parallel comprise the multi-rotor
homopolar machine in close contact with a ring shaped stator
that may be optionally magnetized in the direction opposite to
the magnetic fields of the rotors.

Each rotor 20 has
its own axle 21 which is circumferentially mounted vertically,
arranged and dynamically balanced around a central vertical
axis, on an electrically conductive but low permeability axle
rod 21 made of copper, brass or bronze, that may penetrate the
center of the entire magnetized rotor and rotatably attach to
top and bottom bearing 33 on circular endplates 31, 32 shown
in FIG. 3. In operation, the rotors orbit around the circular
stator ring, which may or may not also be magnetized.

The invention is
more completely shown in the elevational view of FIG. 3 with
several rotors 20 rotatably attached to the top circular
endplate 31 and bottom circular endplate 32 by electrically
conductive bearings 33. The top endplate 31 is rigidly
attached to the central axle 34 supporting the orbiting
multi-rotor homopolar generator assembly. The hollow circular
design of the stationary ring stator 23 is also visible in
FIG. 3, which can be optionally magnetized to increase
performance output.

The bottom circular
endplate 32 has a large hole in the center, more completely
seen in FIG. 4, that allows inner attachment to insulating
bearing 44 which optimally can be a non-contacting, low
friction magnetic bearing since the weight of the rotor
assembly is carried by the electrically conductive thrust
bearing 41. The bottom endplate 32 is thus isolated
electrically from the stationary Inner cylinder 43 that is the
inner core of the stator. Inner circular assembly plates 49 of
equal size and shape, that preferably are electrically
conductive, rigidly attach the inner cylinder 43 to the stator
ring 23. In accordance with the present invention, FIG. 4
shows the side cross sectional view edge on with a cutaway so
that the central axle 34 and hollow inner cylinder design 43
is visible.

The insulating
bearings 42 separate the central axle 34 from the inner
cylinder 43. Both bearings 42 and 44 electrically maintain the
separation of polarity of the electromotive force (emf)
voltage of each rotor. The positive or negative polarity of
the conductors depends of course on the rotation direction of
the rotor magnets. One conductor 45 is electrically emerging
from the stator assembly and ultimately emanates from the
outer edge of each rotor 20 with the homopolar effect
conducting the generated electricity through the rolling means
47 and 48. The opposite polarity conductor 46 is electrically
emanating from the center axle 21 of each rotor 20 is
connected to the electrically conductive thrust bearing 41.

In accordance with
an important function of the present invention, there is shown
in FIG. 4 one embodiment of an intimately contacting and
engaging nonslip rolling means 47 and 48. As is well-known in
the industry where good traction with a high coefficient of
friction (1.6 or better) but sufficiently low electrical
resistance is desired between two surfaces, an adherent
coating of copper can be used on both facing surfaces of the
stator 23 and rotor 20. For the copper coating,
electro-deposition can be used or flame spraying of copper on
the rotor and stator outer surfaces.

Another embodiment
of rolling means 47 and 48 utilizes a geared electromechanical
rotary joint developed by NASA Goddard Space Center (NASA Tech
Briefs, December, 1994) which offers the advantage of a
springy, low noise planetary gear contacting a stator ring
gear. It was designed by NASA to overcome the disadvantages of
sliding contacts and to ensure high traction desired for
rolling electrical contacts.

The springy gears
are made from beryllium copper which is a self-cleaning
material with, in one embodiment, an average diameter of 6.35
mm with any reasonable number of teeth. Another concept to
creating a rolling contact utilizes a magnetic sprocket design
with small rare earth (samarium cobalt for example) magnets
embedded perpendicularly in the surfaces of the stator ring
and rotor magnets. The magnetic sprocket thus utilizes equally
spaced magnets mounted normal to the axes of the stator and
rotor.

To demonstrate an
important feature of the invention, there is shown in FIG. 5 a
plan view from the top of the balanced distribution of the
rotors 20 around the stator assembly 43 with the outer stator
ring 23 that are equally spaced and preferably dynamically
balanced so the centrifugal forces are equal and opposite.

*Theory of
Operation ~*

The main principle
of operation is based on the fact that rotating cylindrical
magnets creates a homopolar emf generation from Faraday's Law
and the Lorentz Force. Physically, a rotating, non-inertial
reference frame configuration can only be analyzed correctly
with Einstein's general theory of relativity, utilizing a
Thirring metric.

Particularly, where
rotating cylindrical magnets and disk are synchronized and
made co-rotational, such a co-rotational configuration makes
the generator one piece like the earth's magnetic field
itself. As the inventors explored this correspondence more
closely, it was learned that the earth's molten, electrically
conductive iron core also includes not one but several
vortices in a coaxial circular arrangement. The inventors
stumbled upon this concept while investigating the field
rotation paradox and found that an orbiting, multi-rotor
homopolar generator assembly would be analogous to the earth's
electrically conductive, multi-vortex, magnetic, molten iron
core.

The field rotation
paradox can be easily resolved by an amateur DIY (Do It
Yourself ) scientist by comparing the interception of a linear
magnetic field vs. a rotating magnetic field. In the former
configuration the meter gives the same reading whether the
magnet is moved with respect to a pickup coil of wire or vice
versa but in the latter configuration the meter reading is
seen only when the disk is moved with respect to rotary
magnetic field of cylindrical magnet but not when the magnet
is moved with respect to the disk. The former is consistent
with special relativity while the latter is relying on general
relativity. Both are loosely termed "relativistic."

*Assembly and Use
~*

The manufacturing,
assembly and use of this invention is very simple even
intuitive. The system of this invention can be readily
assembled from the teaching provided in this disclosure by
state of the art techniques and materials by a person of
average skill in the art.

The applicant has
described the essence of this invention. While this invention
has been described with reference to an illustrative
embodiment, this description is not intended to be construed
in a limiting sense. Various modifications and combinations of
the illustrative embodiments as well as other embodiments of
the invention will be apparent to a person of average skill in
the art upon reference to this description.

*Variations ~*

Due to the
simplicity and elegance of the design of this invention
designing around it is very difficult if not impossible.
Nonetheless many changes may be made to this design without
deviating from the spirit of this invention. Examples of such
contemplated variations include the following:

1. The shape and
size, colors etc of the device or the packaging thereof may be
modified.

2. Additional
complimentary and complementary functions and features may be
added.

3. The system of
this invention may be adapted for other related uses.

4. Instead of
cylindrical magnets, other types of magnets and mode of
mounting on the disk may be employed to create the orbiting,
rotational magnetic field.

5. The invention may
be scaled up and down by several orders of magnitude

7. An experimental
science toy version may be developed for education and
entertainment of little young scientists of the future.

8. Homopolar
generator may be employed in reverse as a motor to convert
electrical energy into mechanical energy.

9. A homopolar servo
motor version may be crafted based on this co-rotational
magnet and disk concept.

10. Permanent
cylindrical magnets may be replaced by equivalent
configuration of electromagnets.

11. A portion of the
emf generated may be fed back to cylindrical electromagnets to
explore the possibility of a self-excited generator without
violating any laws of nature.

Other changes such
as aesthetics and substitution of newer materials as they
become available, which substantially perform the same
function in substantially the same manner with substantially
the same result without deviating from the spirit of the
invention may be made.

Following is a
listing of the components used in the best mode preferred
embodiment and the alternate embodiments for use with OEM as
well as retrofit markets. For the ready reference of the
reader the reference numerals have been arranged in ascending
numerical order.

10 = Prior art
generally

20 = Rotor(s)

21 = Axle, rod

23 = Stationary Ring
Stator (Optionally Magnetized)

31 = Top circular
end plate

32 = Bottom circular
end plate

33 = Bearing

34 = Central Axle

41 = Electrically
Conductive Thrust Bearing

42 = Insulating
Bearing

43 = Stationary
Hollow Inner Cylinder

44 = Insulating
Bearing

45 = Opposite
Polarity Conductor

46 = Opposite
Polarity Conductor

47 = Non-Slip
Rolling Means

48 = Non-Slip
Rolling Means

49 = Inner Circular
Assembly Plates

Definitions and
Acronyms

A great care has
been taken to use words with their conventional dictionary
definitions. Following definitions are included here for
clarification.

3D = Three
Dimensional

Acyclic =
Non-cyclic, non rotational or linear

DC = Direct Current
as contrasted from alternating current electricity

DIY = Do It Yourself

DYNAMO = A device
for converting mechanical energy into electrical energy (&
Vice versa)

EMF =
Electromagnetic Force

Homopolar = Same as
unipolar

Integrated =
Combination of two entities to act like one

Interface = Junction
between two dissimilar entities

N = Magnetic North
(Permanent or electro-magnet)

N-Machine = One
Piece Faraday generator

OEM = Original
Equipment Manufacturer

S = Magnetic South
(Permanent or electro-magnet)

Unipolar = Same as
homopolar

Note: It should be
noted that the prior art uses unipolar, homopolar, acyclic and
Faraday Disk Dynamo interchangeably.

While this invention
has been described with reference to illustrative embodiments,
this description is not intended to be construed in a limiting
sense. Various modifications and combinations of the
illustrative embodiments as well as other embodiments of the
invention will be apparent to a person of average skill in the
art upon reference to this description. It is therefore
contemplated that the appended claim(s) cover any such
modifications, embodiments as fall within the true scope of
this invention as defined by the appended claims.

***Claims ~***

What is claimed is:

1. An orbiting
multi-rotor homopolar machine comprising:

a plurality of
axially parallel, equally spaced, cylindrical, magnet rotors
arranged circumferentially around the periphery of a central
stator ring whose axis is parallel to each magnet rotor axis;

rolling means
attached separately to the magnet rotors and to the stator
ring for intimately contacting and enabling high friction
non-slip rolling between magnet rotors and stator ring;

means for starting
and sustaining orbiting rolling of the magnet rotors around
stator ring as required;

bearing means
rotatably securing the top and bottom ends of each magnet
rotor to a corresponding circular endplate;

axle means located
in the center of the stator ring rigidly attached to the top
circular endplate;

electrically
insulating bearing means rotatably securing the center of the
bottom circular endplate to a coaxial inner cylinder located
between the axle and stator ring; and

circular assembly
means for rigidly attaching the inner cylinder to the stator
ring.

2. The homopolar
machine of claim 1 wherein the inner cylinder, circular
assembly means, magnet rotors, axle means, circular endplate,
and stator ring are made at least partially from electrically
conductive material.

3. The homopolar
machine of claim 1 wherein the rolling means comprises an
electrically conductive geared electromechanical rotary joint.

4. The homopolar
machine of claim 1 wherein the rolling means comprises an
electrically conductive copper coating on the stator ring and
magnet rotors.

5. The homopolar
machine of claim 1 wherein the stator ring comprises
electrically conductive magnetic material.

6. A method for
starting and sustaining the orbiting of rolling cylindrical
magnets arranged parallel to and circumferentially around the
vertical axis of a central stator ring, while intimately
contacting and engaging non-slip rolling means between rotor
magnets and the stator ring, rotatably securing the top and
bottom ends of each rotor magnet by means of a bearing to a
corresponding circular endplate, rigidly attaching to the top
circular endplate a vertical axle coaxial with and in the
stator ring, securing the center of the bottom circular
endplate to a coaxial inner cylinder located between the axle
and the stator ring by means of an electrically insulating
bearing, and rigidly attaching the inner cylinder to the
stator ring by means of a circular assembly.

7. An orbiting
multi-rotor homopolar machine comprising:

a plurality of
axially parallel, equally spaced, cylindrical, magnet rotors
arranged circumferentially around the periphery of a central
stator ring whose axis is parallel to each magnet rotor axis;

rolling means
attached separately to the magnet rotors and to the stator
ring for intimately contacting and enabling high friction
non-slip rolling between the magnet rotors and stator ring;

means for starting
and sustaining orbiting rolling of the magnet rotors around
the stator ring as required;

bearing means
rotatably securing the top and bottom ends of each magnet
rotor to a corresponding circular endplate;

axle means located
in the center of the stator ring rigidly attached to the top
circular endplate;

electrically
insulating bearing means rotatably securing the center of the
bottom circular endplate to a coaxial inner cylinder located
between the axle and stator ring; and

circular assembly
means for rigidly attaching the inner cylinder to the stator
ring; wherein said inner cylinder, said circular assembly
means, said magnet rotors, said axle means, said circular
endplate, and said stator ring are made at least partially
from electrically conductive material.

8. The homopolar
machine of claim 7 wherein the rolling means comprises an
electrically conductive geared electromechanical rotary joint.

9. The homopolar
machine of claim 7 wherein the rolling means comprises an
electrically conductive copper coating on the stator ring and
magnet rotors.

10. The homopolar
machine of claim 7 wherein the stator ring comprises
electrically conductive magnetic material.

---

**P.
Murad, et al. : The Morningstar Energy Box**  
 **[ [PDF](http://rexresearch.com/roschin/murad-mebox.pdf)
]**

**Replication of
Roschin-Godin-Searl Generator**

![](meb1.jpg)

  


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 [**http://www.youtube.com/watch?v=OGZ61sQ8t-o**](http://www.youtube.com/watch?v=OGZ61sQ8t-o)  
   

**SEG-MEC
-16C .mp4**

  
There is another machine called "Morningstar Energy Box" ,they
duplicated the large Russian MEC,it shows ...  
   


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 [**http://searlsolution.com/media2.html**](http://searlsolution.com/media2.html)

**Russian
Temperature & Magnetic Anomaly Confirmed in Homopolar
System.**

  
The Morningstar Energy Box (Tuesday, March 15, 4:30 PM)
SPESIF-COFE4 Presentation. 2011  
   
SPESIF-COFE 4 Abstract. The Morningstar Energy Box is a
derivative of a Searl device modified in a similar fashion used
by the Russian Scientists Godin and Roschin. These devices use
laminated rollers and a main ring made of different materials
used to enhance electrical and magnetic properties. Where the
Searl device uses rollers to move around a main ring, the
Russian device kinematically constrains these rollers within a
mechanical cage. The operational theory for the Energy Box uses
rotating electromagnetic fields to create gravitational effects
and is different from those theories outlined by either Searl or
the Russians. A prototype device is currently under test and
unfortunately self-accelerated motion has yet to be obtained.
The Russians have made several serious claims that their device
produced self-acceleration to generate electricity, created a
relatively large weight loss, generated discrete walls of
magnetism far from the device and that a temperature drop exists
when the device loses weight. To date, no one has validated
these outrageous claims. However, we have found similar
phenomenon regarding temperature loss and the discrete magnetic
walls to occur during tests of the Energy Box and have
correlated the temperature drop that the Godin & Roschin
device produces as being a consequence of the Unruh effect.
Where they claimed to lose as much as 35% of the weight of a 375
kg armature, the Energy Box only loses as much as 2% of its 490
pounds at this stage of the test cycle. Additional tests and
modifications are underway to hopefully increase the weight
loss.  
   


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