Motionless Electromagnetic Generator (MEG) ~ US Patent #
6,362,718 and explanatory papers & links ~ Stephen Patrick,
Thomas Bearden, James Hayes, Kenneth Moore, and James Kenny



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---

**Stephen PATRICK // Thomas BEARDEN, *et
al.***

**Motionless
Electromagnetic
Generator
(MEG)**

---

![](1jlnmeg.jpg)  
(Graphic by J. L. Naudin)

In March 2002,
Stephen L. Patrick, Thomas E. Bearden, James C. Hayes, Kenneth
D. Moore, and James L. Kenny received **[US
Patent # 6,362,718](#usp)** for the Motionless
Electromagnetic Generator (MEG), a scalar energy device that
produces over-unity (AKA "Free Energy"); in conventional terms,
the device has a Coefficient of Performance (COP) of 5.0.

In an update published on
http://www.cheniere.org --- Tom Bearden's website --- he
states:

"...We have now secured an
agreement with the National Materials Science Laboratory of
the National Academy of Science in a friendly foreign country,
to do the necessary advanced research to finish the MEG for
scale-up and commercial production. The first commercial units
should be rolling off the production lines in about one year,
and we expect them to be closed-loop self-powering systems of
about 2.5 KW output, but modular...

"A marvelous and very
rigorous review by Myron W. Evans, who has some 600 papers in
the hard literature, will be in the forthcoming second edition
of *Modern Nonlinear Optics*, Wiley, 2001.  I also
have a paper on the MEG in one of the three volumes, and a
second paper on the principles for extracting EM energy from
the vacuum...

"In Magnetic Energy Limited,
all business discussions and arrangements are taken care of by
Dr. Lee Kenny, Managing Partner.  There are five of us
who are co-inventors of the MEG, and two of the others are
really the principal inventors.

"Lee Kenny can be reached by
E-mail at:jlkenny@ingr.com."

The MEG has been replicated
by J. L. Naudin and other experimenters worldwide. Some
experimenters (i.e., digi@digitoxin.dhs.org) claim that the
claims of over-unity made by Patrick, Bearden, Naudin, and
others are based on incorrect measurements. Naudin does not
acknowledge negative feedback. Their opinions are online at:
www.phact.org/e/z/bearden and 

![](2jlnmeg.jpg)

A paper on the subject has
been published in *Foundations of Physics Letters* 14
(1) 88-94 (2001); "Explanation of the Motionless
Electromagnetic Generator with O(3) Electrodynamics", by P. K.
Anastasovski, *et al*. The paper is online at:
http://cheniere.nii.net/references/found%20phys%20letters/no%201%202001/p01.htm

J.. Naudin's MEG
Project is: http://jnaudin.free.fr/html/meg.htm

An explanation of the MEG
with Sach's O(3) Electrodynamics:
http://www.cheniere.org/references/sachsO3.pdf

Bearden, *et al*.,
have published an explanatory paper, "The Motionless
Electromagnetic Generator: Extracting Energy from a Permanent
Magnet with Energy-Replenishing from the Active Vacuum", which
was posted for a while on the Dept. of Energy website. It can
be found on http://www.cheniere.org, Bearden's website.

This email letter from
Bearden appeared on the internet in May 2005 (Source:
http://cheniere.org/correspondence/051605.htm )

Date: Mon, 16 May 2005
12:11:01 -0500

Dear Gary,

The five inventors of the
MEG are as frustrated as anyone else! Weve sunk our money and
enormous time in this effort for some 10 to 12 years. So we
have our own money and sweat and work where our mouth is. It
hasnt been funded by selling stock to the naive public etc.

We are not out of
engineering development of the MEG yet, and to get through it
and into full production engineering would require about $10
to $12 million --- money we personally do not have. So far,
weve not obtained the necessary financing. We did sign one
financial deal, only to have our last working demonstrator
promptly destroyed by the new folks in three days, against all
our instructions. So we had to legally declare that agreement
null and void.

Engineering the MEG, it
should be clear, IS NOT JUST NORMAL ELECTRICAL ENGINEERING.
Weve made that point many times, and specified exactly how
the machine works. Yet the biggest problem is that almost all
of the venture capitalists are either EEs themselves, or
employ as their second or third in command an EE, often with a
Ph.D. in EE. And there the problem is that one cannot get
across to the EEs that the MEG is not just a transformer, and
that E-field radiations really do arise freely from the space
just outside the core, re-radiating back into the core with a
multitude of absorbed and reradiated signals of all sorts of
phases. Unless this dense signal environment and its phasing
is carefully adjusted so that the phases are generally
additive, COP > 1.0 is not possible, obviously, since it
means no effective *NET* energy input occurs from the
activated external environment, even though *LOTS* of
excess energy is being radiated back into the MEG. One doesnt
seek and cannot use just a "noise" energy input from that
external environment! One must have some coherence, so that
the external environment inputs some *usable* free EM
energy.

So to go from the business
of slow, painful hand adjustment of the phasing to automatic
optimization is certainly a "doable", but *it is not a
simple EE problem*. In aerospace, our team (who are all
aerospace engineers with substantial and lengthy experience in
nonlinear systems) has worked for several decades on such
problems, and we do know how to solve it and finish the
product so that its ready for full production engineering.
Bluntly, electrical engineers *do not* know how to solve
the problem and finish the unit, unless theyve studied and
worked well beyond electrical power engineering. The MEGs
operation cannot even be modeled in the standard CEM/EE model.

But the EEs with venture
capitalists (and some of our major national laboratories also,
by the way) dont seem to be able to comprehend something that
is already well-known in aerospace, in chaotic systems work,
and in dense signal environments work.

Let me speak very plainly.
That lack of understanding of such systems, and the use of a
horribly fouled old electrical engineering model in our power
engineering, is why nationally we have a horribly vulnerable
centralized electrical power distribution and "control" system
that violates almost every principle of multiloop
servomechanism control theory in the book. It isnt just an EE
problem; its a multiloop servomechanism control problem. Our
national centralized electrical power system is so fragile and
so vulnerable that even a small portable EMP weapon (a
"shooter", as commonly known in the trade), really good
hackers, and many other simple things can keep it surging out
of control and collapsing indefinitely with ridiculous ease.

If one wishes a more
accurate grasp of the energy situation, see Matt Simmons
presentations downloadable from the Simmons International
website. There you get the truth, not political fiction, and
by one of the firms that widely funds energy projects
worldwide. Further, a single scalar interferometer can lay the
entire system down at will, and keep it down forever. Since
even the Japanese Yakuza have such interferometers and have
been using them since early 1990 to engineer the weather over
our heads (see Scott Stevens website for a meteorologists
beautiful presentation of the resulting weather engineering
phenomena), obviously somewhere along the line they are going
to devote one of those interferometers to downing the entire
U.S. electrical power system and keeping it down. And when
that happens, there isnt going to be any functioning
centralized electric power in the U.S. from then on, period.
Easy to surmise the catastrophic economic collapse that then
will ensue, paralyzing and defeating the United States without
a single missile, nuclear bomber, nuclear submarine, etc.

Our fellows do know about
scalar interferometers, weather engineering, and the works ---
but they keep it so closely locked up that most of our
decision makers are not aware of it, even though Secretary of
Defense Cohen was briefed on it and publicly confirmed such
weapons in April 1997. Meanwhile, our present national power
system and national energy policy are just a great disaster
waiting to happen.

We do continue in our search
for the necessary funding, with a financial arrangement we can
tolerate, and with a financial partner who can understand that
he cannot just run in some good EEs and build a MEG and turn
them out like pretzels. Or in fact that cannot be done with
any other legitimate COP>1.0 system, without the proper
completion of Engineering Development and then Production
Engineering.

We think we are again
getting close to obtaining the necessary capitalization for
the MEG, but will just have to wait and see how it turns out
this time around.

Best wishes,

Tom Bearden

![](bearden.jpg)

**[ Photo by Marcia Stockton <aeditua@hughes.net> ,
2001; Used with Permission ]**

**Cheniere Press's store for books and DVDs is
at   
<http://cheniere.org/sales/online-store.htm>**

---

**US Patent # 6,362,718**

**Motionless
Electromagnetic Generator**

**Patrick , *et al*.**
  
(March 26, 2002)

**Abstract ~**

An electromagnetic generator
without moving parts includes a permanent magnet and a
magnetic core including first and second magnetic paths. A
first input coil and a first output coil extend around
portions of the first magnetic path, while a second input coil
and a second output coil extend around portions of the second
magnetic path. The input coils are alternatively pulsed to
provide induced current pulses in the output coils. Driving
electrical current through each of the input coils reduces a
level of flux from the permanent magnet within the magnet path
around which the input coil extends. In an alternative
embodiment of an electromagnetic generator, the magnetic core
includes annular spaced-apart plates, with posts and permanent
magnets extending in an alternating fashion between the
plates. An output coil extends around each of these posts.
Input coils extending around portions of the plates are pulsed
to cause the induction of current within the output coils.

Inventors:  **Patrick,
Stephen L.** (2511 Woodview Dr. SE., Huntsville, AL
35801); **Bearden, Thomas E.** (2211 Cove Rd., Huntsville,
AL 35801); **Hayes, James C.** (16026 Deaton Dr. SE.,
Huntsville, AL 35803); **Moore, Kenneth D.** (1704
Montdale Rd., Huntsville, FL 35801); **Kenny, James L.**
(925 Tascosa Dr., Huntsville, AL 35802)

Appl. No.:  656313 ~
Filed  September 6, 2000   
Current U.S. Class: 336/214 ~
Intern'l Class:  H01F 027/24   
Field of Search: 
363/16,24,25,26,56.06,56.08,133,134
336/15,110,155,177,180,213,214,221,222

**References Cited (U.S.
Patent Documents) ~**

2,153,378 (Apr., 1939),
Kramer (171/95) ~ 2,892,155 (Jun., 1959), Radus, et al.
(324/117) ~ 3,079,535 (Feb., 1963), Schultz (317/201) ~
3,165,723 (Jan., 1965), Radus (340/174) ~ 3,228,013 (Jan.,
1966), Olson, et al. (340/174) ~ 3,254,268 (May., 1966),
Radus, et al. (317/14) ~ 3,316,514 (Apr., 1967), Radus, et al.
(335/291) ~ 3,368,141 (Feb., 1968), Subieta-Garron (323/44) ~
3,391,358 (Jul., 1968), Bratkowski, et al. (335/21) ~
3,453,876 (Jul., 1969), Radus (73/141) ~ 3,517,300 (Jun.,
1970), McMurray. ~ 3,569,947 (Mar., 1971), Radus (340/174) ~
3,599,074 (Aug., 1971), Adams. ~ 4,006,401 (Feb., 1977), de
Rivas (323/92)   
4,077,001 (Feb., 1978),
Richardson (323/92) ~ 4,366,532 (Dec., 1982), Rosa, et al.
(363/69) ~ 4,482,945 (Nov., 1984), Wolf, et al. (363/129) ~
4,554,524 (Nov., 1985), Radus (337/3) ~ 4,853,668 (Aug.,
1989), Bloom (336/214) ~ 4,864,478 (Sep., 1989), Bloom
(363/16) ~  4,904,926 (Feb., 1990), Pasichinskyj
(323/362) ~ 5,011,821 (Apr., 1991), McCullough (505/1) ~
5,221,892 (Jun., 1993), Sullivan, et al. (323/362) ~ 5,245,521
(Sep., 1993), Spreen (363/37) ~ 5,327,015 (Jul., 1994), Hacket
(505/211) ~  5,335,163 (Aug., 1994), Seiersen (363/126) ~
5,694,030 (Dec., 1997), Sato, et al. (323/282)

**Other References ~**

Raymond J. Radus,
"Permanent-Magnet Circuit using a `Flux-Transfer` Principle,"
*Engineers' Digest*, 24(1-6) Jan.-Jun. 1963, p. 86.

Robert O'Handley, *Modern
Magnetic Materials, Principles and Applications*, John
Wiley & Sons, Inc., 2000, pp. 456-468.

Robert C. Weast, Editor, *CRC
Handbook
of
Chemistry and Physics*, 1978-1979, p. B-50.   
Honeywell.com web site,
"amorphous metals".

Primary Examiner: Nguyen;
Matthew   ~  Attorney, Agent or Firm:
Friedland; Norman

**Description ~**

**1. Field of Invention ~**

This invention relates to a
magnetic generator used to produce electrical power without
moving parts, and, more particularly, to such a device having
a capability, when operating, of producing electrical power
without an external application of input power through input
coils.

**2. Description of the
Related Art ~**

The patent literature
describes a number of magnetic generators, each of which
includes a permanent magnet, two magnetic paths external to
the permanent magnet, each of which extends between the
opposite poles of the permanent magnet, switching means for
causing magnetic flux to flow alternately along each of the
two magnetic paths, and one or more output coils in which
current is induced to flow by means of changes in the magnetic
field within the device. These devices operate in accordance
with an extension of Faraday's Law, indicating that an
electrical current is induced within a conductor within a
changing magnetic field, even if the source of the magnetic
field is stationary.

A method for switching
magnetic flux to flow predominantly along either of two
magnetic paths between opposite poles of a permanent magnet is
described as a "flux transfer" principle by R. J. Radus in
Engineer's Digest, Jul. 23, 1963. This principle is used to
exert a powerful magnetic force at one end of both the north
and south poles and a very low force at the other end, without
being used in the construction of a magnetic generator. This
effect can be caused mechanically, by keeper movement, or
electrically, by driving electrical current through one or
more control windings extending around elongated versions of
the pole pieces 14. Several devices using this effect are
described in U.S. Pat. Nos. 3,165,723, 3,228,013, and
3,316,514, which are incorporated herein by reference.

Another step toward the
development of a magnetic generator is described in U.S. Pat.
No. 3,368,141, which is incorporated herein by reference, as a
device including a permanent magnet in combination with a
transformer having first and second windings about a core,
with two paths for magnetic flux leading from each pole of the
permanent magnet to either end of the core, so that, when an
alternating current induces magnetic flux direction changes in
the core, the magnetic flux from the permanent magnet is
automatically directed through the path which corresponds with
the direction taken by the magnetic flux through the core due
to the current. In this way, the magnetic flux is intensified.
This device can be used to improve the power factor of a
typically inductively loaded alternating current circuit.

Other patents describe
magnetic generators in which electrical current from one or
more output coils is described as being made available to
drive a load, in the more conventional manner of a generator.
For example, U.S. Pat. No. 4,006,401, which is incorporated
herein by reference, describes an electromagnetic generator
including permanent magnet and a core member, in which the
magnetic flux flowing from the magnet in the core member is
rapidly alternated by switching to generate an alternating
current in a winding on the core member. The device includes a
permanent magnet and two separate magnetic flux circuit paths
between the north and south poles of the magnet. Each of the
circuit paths includes two switching means for alternately
opening and closing the circuit paths, generating an
alternating current in a winding on the core member. Each of
the switching means includes a switching magnetic circuit
intersecting the circuit path, with the switching magnetic
circuit having a coil through which current is driven to
induce magnetic flux to saturate the circuit path extending to
the permanent magnet. Power to drive these coils is derived
directly from the output of a continuously applied alternating
current source. What is needed is an electromagnetic generator
not requiring the application of such a current source.

U.S. Pat. No. 4,077,001,
which is incorporated herein by reference, describes a
magnetic generator, or dc/dc converter, comprising a permanent
magnet having spaced-apart poles and a permanent magnetic
field extending between the poles of the magnet. A
variable-reluctance core is disposed in the field in fixed
relation to the magnet and the reluctance of the core is
varied to cause the pattern of lines of force of the magnetic
field to shift. An output conductor is disposed in the field
in fixed relation to the magnet and is positioned to be cut by
the shifting lines of permanent magnetic force so that a
voltage is induced in the conductor. The magnetic flux is
switched between alternate paths by means of switching coils
extending around portions of the core, with the flow of
current being alternated between these switching coils by
means of a pair of transistors driven by the outputs of a
flip-flop. The input to the flip flop is driven by an
adjustable frequency oscillator. Power for this drive circuit
is supplied through an additional, separate power source. What
is needed is a magnetic generator not requiring the
application of such a power source.

U.S. Pat. No. 4,904,926,
which is incorporated herein by reference, describes another
magnetic generator using the motion of a magnetic field. The
device includes an electrical winding defining a magnetically
conductive zone having bases at each end, the winding
including elements for the removing of an induced current
therefrom. The generator further includes two pole magnets,
each having a first and a second pole, each first pole in
magnetic communication with one base of the magnetically
conductive zone. The generator further includes a third pole
magnet, the third pole magnet oriented intermediately of the
first poles of the two pole electromagnets, the third pole
magnet having a magnetic axis substantially transverse to an
axis of the magnetically conductive zone, the third magnet
having a pole nearest to the conductive zone and in magnetic
attractive relationship to the first poles of the two pole
electromagnets, in which the first poles thereof are like
poles. Also included in the generator are elements, in the
form of windings, for cyclically reversing the magnetic
polarities of the electromagnets. These reversing means,
through a cyclical change in the magnetic polarities of the
electromagnets, cause the magnetic flux lines associated with
the magnetic attractive relationship between the first poles
of the electromagnets and the nearest pole of the third magnet
to correspondingly reverse, causing a wiping effect across the
magnetically conductive zone, as lines of magnetic flux swing
between respective first poles of the two electromagnets,
thereby inducing electron movement within the output windings
and thus generating a flow of current within the output
windings.

U.S. Pat. No. 5,221,892,
which is incorporated herein by reference, describes a
magnetic generator in the form of a direct current flux
compression transformer including a magnetic envelope having
poles defining a magnetic axis and characterized by a pattern
of magnetic flux lines in polar symmetry about the axis. The
magnetic flux lines are spatially displaced relative to the
magnetic envelope using control elements which are
mechanically stationary relative to the core. Further provided
are inductive elements which are also mechanically stationary
relative to the magnetic envelope. Spatial displacement of the
flux relative to the inductive elements causes a flow of
electrical current. Further provided are magnetic flux valves
which provide for the varying of the magnetic reluctance to
create a time domain pattern of respectively enhanced and
decreased magnetic reluctance across the magnetic valves, and,
thereby, across the inductive elements.

Other patents describe
devices using superconductive elements to cause movement of
the magnetic flux. These devices operate in accordance with
the Meissner effect, which describes the expulsion of magnetic
flux from the interior of a superconducting structure as the
structure undergoes the transition to a superconducting phase.
For example, U.S. Pat. No. 5,011,821, which is incorporated
herein by reference, describes an electric power generating
device including a bundle of conductors which are placed in a
magnetic field generated by north and south pole pieces of a
permanent magnet. The magnetic field is shifted back and forth
through the bundle of conductors by a pair of thin films of
superconductive material. One of the thin films is placed in
the superconducting state while the other thin film is in a
non-superconducting state. As the states are cyclically
reversed between the two films, the magnetic field is
deflected back and forth through the bundle of conductors.

U.S. Pat. No. 5,327,015,
which is incorporated herein by reference, describes an
apparatus for producing an electrical impulse comprising a
tube made of superconducting material, a source of magnetic
flux mounted about one end of the tube, a means, such as a
coil, for intercepting the flux mounted along the tube, and a
means for changing the temperature of the superconductor
mounted about the tube. As the tube is progressively made
superconducting, the magnetic field is trapped within the
tube, creating an electrical impulse in the means for
intercepting. A reversal of the superconducting state produces
a second pulse.

None of the patented devices
described above use a portion of the electrical power
generated within the device to power the reversing means used
to change the path of magnetic flux. Thus, like conventional
rotary generators, these devices require a steady input of
power, which may be in the form of electrical power driving
the reversing means of one of these magnetic generators or the
torque driving the rotor of a conventional rotary generator.
Yet, the essential function of the magnetic portion of an
electrical generator is simply to switch magnetic fields in
accordance with precise timing. In most conventional
applications of magnetic generators, the voltage is switched
across coils, creating magnetic fields in the coils which are
used to override the fields of permanent magnets, so that a
substantial amount of power must be furnished to the generator
to power the switching means, reducing the efficiency of the
generator.

Recent advances in magnetic
material, which have particularly been described by Robert C.
O'Handley in Modern Magnetic Materials, Principles and
Applications, John Wiley & Sons, New York, pp. 456-468,
provide nanocrystalline magnetic alloys, which are
particularly well suited forth rapid switching of magnetic
flux. These alloys are primarily composed of crystalline
grains, or crystallites, each of which has at least one
dimension of a few nanometers. Nanocrystalline materials may
be made by heat-treating amorphous alloys which form
precursors for the nanocrystalline materials, to which
insoluble elements, such as copper, are added to promote
massive nucleation, and to which stable, refractory alloying
materials, such as niobium or tantalum carbide are added to
inhibit grain growth. Most of the volume of nanocrystalline
alloys is composed of randomly distributed crystallites having
dimensions of about 2-40 nm. These crystallites are nucleated
and grown from an amorphous phase, with insoluble elements
being rejected during the process of crystallite growth. In
magnetic terms, each crystallite is a single-domain particle.
The remaining volume of nanocrystalline alloys is made up of
an amorphous phase in the form of grain boundaries having a
thickness of about 1 nm.

Magnetic materials having
particularly useful properties are formed from an amorphous
Co--Nb--B (cobalt-niobium-boron) alloy having near-zero
magnetostriction and relatively strong magnetization, as well
as good mechanical strength and corrosion resistance. A
process of annealing this material can be varied to change the
size of crystallites formed in the material, with a resulting
strong effect on DC coercivity. The precipitation of
nanocrystallites also enhances AC performance of the otherwise
amorphous alloys.

Other magnetic materials are
formed using iron-rich amorphous and nanocrystalline alloys,
which generally show larger magnetization that the alloys
based on cobalt. Such materials are, for example,
Fe--B--Si--Nb--Cu (iron-boron-silicon-niobium-copper) alloys.
While the permeability of iron-rich amorphous alloys is
limited by their relatively large levels of magnetostriction,
the formation of a nanocrystalline material from such an
amorphous alloy dramatically reduces this level of
magnetostriction, favoring easy magnetization.

Advances have also been made
in the development of materials for permanent magnets,
particularly in the development of materials including rare
earth elements. Such materials include samarium cobalt,
SmCo.sub.5, which is used to form a permanent magnet material
having the highest resistance to demagnetization of any known
material. Other magnetic materials are made, for example,
using combinations of iron, neodymium, and boron.

**Summary of the Invention
~**

It is a first objective of
the present invention to provide a magnetic generator which a
need for an external power source during operation of the
generator is eliminated.

It is a second objective of
the present invention to provide a magnetic generator in which
a magnetic flux path is changed without a need to overpower a
magnetic field to change its direction.

It is a third objective of
the present invention to provide a magnetic generator in which
the generation of electricity is accomplished without moving
parts.

In the apparatus of the
present invention, the path of the magnetic flux from a
permanent magnet is switched in a manner not requiring the
overpowering of the magnetic fields. Furthermore, a process of
self-initiated iterative switching is used to switch the
magnetic flux from the permanent magnet between alternate
magnetic paths within the apparatus, with the power to operate
the iterative switching being provided through a control
circuit consisting of components known to use low levels of
power. With self-switching, a need for an external power
source during operation of the generator is eliminated, with a
separate power source, such as a battery, being used only for
a very short time during start-up of the generator.

According to a first aspect
of the present invention, an electromagnetic generator is
provided, including a permanent magnet, a magnetic core, first
and second input coils, first and second output coils, and a
switching circuit. The permanent magnet has magnetic poles at
opposite ends. The magnetic core includes a first magnetic
path, around which the first input and output coils extend,
and a second magnetic path, around which the second input and
output coils extend, between opposite ends of the permanent
magnet. The switching circuit drives electrical current
alternately through the first and second input coils. The
electrical current driven through the first input oil causes
the first input coil to produce a magnetic field opposing a
concentration of magnetic flux from the permanent magnet
within the first magnetic path. The electrical current driven
through the second input coil causes the second input coil to
produce a magnetic field opposing a concentration of magnetic
flux from the permanent magnet within the second magnetic
path.

According to another aspect
of the present invention, an electromagnetic generator is
provided, including a magnetic core, a plurality of permanent
magnets, first and second pluralities of input coils, a
plurality of output coils, and a switching circuit. The
magnetic core includes a pair of spaced-apart plates, each of
which has a central aperture, and first and second pluralities
of posts extending between the spaced-apart plates. The
permanent magnets each extend between the pair of spaced apart
plates. Each permanent magnet has magnetic poles at opposite
ends, with the magnetic fields of all the permanent magnets
being aligned to extend in a common direction. Each input coil
extends around a portion of a plate within the spaced-apart
plates, between a post and a permanent magnet. An output coil
extends around each post. The switching circuit drives
electrical current alternately through the first and second
pluralities of input coils. Electrical current driven through
each input coil in the first plurality of input coils causes
an increase in magnetic flux within each post within the first
plurality of posts from permanent magnets on each side of the
post and a decrease in magnetic flux within each post within
the second plurality of posts from permanent magnets on each
side of the post. Electrical current driven through each input
coil in the second plurality of input coils causes a decrease
in magnetic flux within each post within the first plurality
of posts from permanent magnets on each side of the post and
an increase in magnetic flux within each post within the
second plurality of posts from permanent magnets on each side
of the post.

**Brief Description of the
Drawings ~**

Figure 1 is a partly
schematic front elevation of a magnetic generator and
associated electrical circuits built in accordance with a
first version of the first embodiment of the present
invention;

![](1meg.jpg)

Figure 2 is a schematic view
of a first version of a switching and control circuit within
the associated electrical circuits of Figure 1;

![](2meg.jpg)

Figure 3 is a graphical view
of drive signals produced within the circuit of Figure 2;

![](3meg.jpg)

Figure 4 is a schematic view
of a second version of a switching and control circuit within
the associated electrical circuits of Figure 1;

![](4meg.jpg)

Figure 5 is a graphical view
of drive signals produced within the circuit of Figure 3;

![](5meg.jpg)

Figure 6A is a graphical
view of a first drive signal within the apparatus of Figure 1;

![](6ahmeg.jpg)

Figure 6B is a graphical
view of a second drive signal within the apparatus of Figure
1;

Figure 6C is a graphical
view of an input voltage signal within the apparatus of Figure
1;

Figure 6D is a graphical
view of an input current signal within the apparatus of Figure
1;

Figure 6E is a graphical
view of a first output voltage signal within the apparatus of
Figure 1;

Figure 6F is a graphical
view of a second output voltage signal within the apparatus of
Figure 1;

Figure 6G is a graphical
view of a first output current signal within the apparatus of
Figure 1;

Figure 6H is a graphical
view of a second output current signal within the apparatus of
Figure 1;

Figure 7 is a graphical view
of output power measured within the apparatus of Figure 1, as
a function of input voltage;

![](7meg.jpg)

Figure 8 is a graphical view
of a coefficient of performance, calculated from measurements
within the apparatus of Figure 1, as a function of input
voltage;

![](8meg.jpg)

Figure 9 is a
cross-sectional elevation of a second version of the first
embodiment of the present invention;

![](9meg.jpg)

Figure 10 is a top view of a
magnetic generator built in accordance with a first version of
a second embodiment of the present invention;

![](10meg.jpg)

Figure 11 is a front
elevation of the magnetic generator of Figure 10; and

![](11meg.jpg)

Figure 12 is a top view of a
magnetic generator built in accordance with a second version
of the second embodiment of the present invention.

![](12meg.jpg)

**Detailed Description of
the Invention ~**

[Figure 1](#fig1)
is a partly schematic front elevation of an electromagnetic
generator 10, built in accordance with a first embodiment of
the present invention to include a permanent magnet 12 to
supply input lines of magnetic flux moving from the north pole
14 of the magnet 12 outward into magnetic flux path core
material 16. The flux path core material 16 is configured to
form a right magnetic path 18 and a left magnetic path 20,
both of which extend externally between the north pole 14 and
the south pole 22 of the magnet 12. The electromagnetic
generator 10 is driven by means of a switching and control
circuit 24, which alternately drives electrical current
through a right input coil 26 and a left input coil 28. These
input coils 26, 28 each extend around a portion of the core
material 16, with the right input coil 26 surrounding a
portion of the right magnetic path 18 and with the left input
coil 28 surrounding a portion of the left magnetic path 20. A
right output coil 29 also surrounds a portion of the right
magnetic path 18, while a left output coil 30 surrounds a
portion of the left magnetic path 20.

In accordance with a
preferred version of the present invention, the switching and
control circuit 24 and the input coils 26, 28 are arranged so
that, when the right input coil 26 is energized, a north
magnetic pole is present at its left end 31, the end closest
to the north pole 14 of the permanent magnet 12, and so that,
when the left input coil 28 is energized, a north magnetic
pole is present at its right end 32, which is also the end
closest to the north pole 14 of the permanent magnet 12. Thus,
when the right input coil 26 is magnetized, magnetic flux from
the permanent magnet 12 is repelled from extending through the
right input coil 26. Similarly, when the left input coil 28 is
magnetized, magnetic flux from the permanent magnet 12 is
repelled from extending through the left input coil 28.

Thus, it is seen that
driving electrical current through the right input coil 26
opposes a concentration of flux from the permanent magnet 12
within the right magnetic path 18, causing at least some of
this flux to be transferred to the left magnetic path 20. On
the other hand, driving electrical current through the left
input coil 28 opposes a concentration of flux from the
permanent magnet 12 within the left magnetic path 20, causing
at least some of this flux to be transferred to the right
magnetic path 18.

While in the example of [Figure 1](#fig1), the input coils 26, 28 are placed
on either side of the north pole of the permanent magnet 12,
being arranged along a portion of the core 16 extending from
the north pole of the permanent magnet 12, it is understood
that the input coils 26, 28 could as easily be alternately
placed on either side of the south pole of the permanent
magnet 12, being arranged along a portion of the core 16
extending from the south pole of the permanent magnet 12, with
the input coils 26, 28 being wired to form, when energized,
magnetic fields having south poles directed toward the south
pole of the permanent magnet 12. In general, the input coils
26, 28 are arranged along the magnetic core on either side of
an end of the permanent magnet forming a first pole, such as a
north pole, with the input coils being arranged to produce
magnetic fields of the polarity of the first pole directed
toward the first pole of the permanent magnet.

Further in accordance with a
preferred version of the present invention, the input coils
26, 28 are never driven with so much current that the core
material 16 becomes saturated. Driving the core material 16 to
saturation means that subsequent increases in input current
can occur without effecting corresponding changes in magnetic
flux, and therefore that input power can be wasted. In this
way, the apparatus of the present invention is provided with
an advantage in terms of the efficient use of input power over
the apparatus of U.S. Pat. No. 4,000,401, in which a portion
both ends of each magnetic path is driven to saturation to
block flux flow. In the electromagnetic generator 10, the
switching of current flow within the input coils 26, 28 does
not need to be sufficient to stop the flow of flux in one of
the magnetic paths 18, 20 while promoting the flow of magnetic
flux in the other magnetic path. The electromagnetic generator
10 works by changing the flux pattern; it does not need to be
completely switched from one side to another.

Experiments have determined
that this configuration is superior, in terms of the
efficiency of using power within the input coils 26, 28 to
generate electrical power within the output coils 29, 30, to
the alternative of arranging input coils and the circuits
driving them so that flux from the permanent magnet is driven
through the input coils as they are energized. This
arrangement of the present invention provides a significant
advantage over the prior-art methods shown, for example, in
U.S. Pat. No. 4,077,001, in which the magnetic flux is driven
through the energized coils.

The configuration of the
present invention also has an advantage over the prior-art
configurations of U.S. Pat. Nos. 3,368,141 and 4,077,001 in
that the magnetic flux is switched between two alternate
magnetic paths 18, 20 with only a single input coil 26, 28
surrounding each of the alternate magnetic paths. The
configurations of U.S. Pat. Nos. 3,368,141 and 4,077,001 each
require two input coils on each of the magnetic paths. This
advantage of the present invention is significant both in the
simplification of hardware and in increasing the efficiency of
power conversion.

The right output coil 29 is
electrically connected to a rectifier and filter 33, having an
output driven through a regulator 34, which provides an output
voltage adjustable through the use of a potentiometer 35. The
output of the linear regulator 34 is in turn provided as an
input to a sensing and switching circuit 36. Under start up
conditions, the sensing and switching circuit 36 connects the
switching and control circuit 24 to an external power source
38, which is, for example, a starting battery. After the
electromagnetic generator 10 is properly started, the sensing
and switching circuit 36 senses that the voltage available
from regulator 34 has reached a predetermined level, so that
the power input to the switching and control circuit 24 is
switched from the external power source 38 to the output of
regulator 34. After this switching occurs, the electromagnetic
generator 10 continues to operate without an application of
external power.

The left output coil 30 is
electrically connected to a rectifier and filter 40, the
output of which is connected to a regulator 42, the output
voltage of which is adjusted by means of a potentiometer 43.
The output of the regulator 42 is in turn connected to an
external load 44.

[Figure 2](#fig2)
is a schematic view of a first version of the switching and
control circuit 24. An oscillator 50 drives the clock input of
a flip-flop 54, with the Q and Q' outputs of the flip-flop 54
being connected through driver circuits 56, 58 to power FETS
60, 62 so that the input coils 26, 28 are alternately driven.
In accordance with a preferred version of the present
invention, the voltage V applied to the coils 26, 28 through
the FETS 60, 62 is derived from the output of the sensing and
switching circuit 36.

[Figure 3](#fig3)
is a graphical view of the signals driving the gates of FETS
60, 62 of [Figure 2](#fig2), with the voltage of
the signal driving the gate of FET 60 being represented by
line 64, and with the voltage of the signal driving FET 62
being represented by line 66. Both of the coils 26, 28 are
driven with positive voltages.

[Figure 4](#fig4)
is a schematic view of a second version of the switching and
control circuit 24. In this version, an oscillator 70 drives
the clock input of a flip-flop 72, with the Q and Q' outputs
of the flip-flop 72 being connected to serve as triggers for
one-shots 74, 76. The outputs of the one-shots 74, 76 are in
turn connected through driver circuits 78, 80 to drive FETS
82, 84, so that the input coils 26, 28 are alternately driven
with pulses shorter in duration than the Q and Q' outputs of
the flip flop 72.

[Figure 5](#fig5)
is a graphical view of the signals driving the gates of FETS
82, 84 of FIG. 4, with the voltage of the signal driving the
gate of FET 82 being represented by line 86, and with the
voltage of the signal driving the gate of FET 84 being
represented by line 88.

Referring again to [Figure 1](#fig1), power is generated in the right
output coil 29 only when the level of magnetic flux is
changing in the right magnetic path 18, and in the left output
coil 30 only when the level of magnetic flux is changing in
the left magnetic path 20. It is therefore desirable to
determine, for a specific magnetic generator configuration,
the width of a pulse providing the most rapid practical change
in magnetic flux, and then to provide this pulse width either
by varying the frequency of the oscillator 50 of the apparatus
of [Figure 2](#fig2), so that this pulse width is
provided with the signals shown in [Figure 3](#fig3),
or by varying the time constant of the one-shots 74, 76 of [Figure 4](#fig4), so that this pulse width is
provided by the signals of [Figure 5](#fig5) at a
lower oscillator frequency. In this way, the input coils are
not left on longer than necessary. When either of the input
coils is left on for a period of time longer than that
necessary to produce the change in flux direction, power is
being wasted through heating within the input coil without
additional generation of power in the corresponding output
coil.

A number of experiments have
been conducted to determine the adequacy of an electromagnetic
generator built as the generator 10 in [Figure
1](#fig1) to produce power both to drive the switching and
control logic, providing power to the input coils 26, 28, and
to drive an external load 44. In the configuration used in
this experiment, the input coils 26, 28 had 40 turns of
18-gauge copper wire, and the output coils 29, 30 had 450
turns of 18-gauge copper wire. The permanent magnet 12 had a
height of 40 mm (1.575 in. between its north and south poles,
in the direction of arrow 89, a width of 25.4 mm (1.00 in.),
in the direction of arrow 90, and in the other direction, a
depth of 38.1 mm (1.50 in.). The core 16 had a height, in the
direction of arrow 89, of 90 mm (3.542 in.), a width, in the
direction of arrow 90, of 135 mm (5.315 in.) and a depth of 70
mm (2.756 in.). The core 16 had a central hole with a height,
in the direction of arrow 89, of 40 mm (1.575 mm) to
accommodate the magnet 12, and a width, in the direction of
arrow 90, of 85 mm (3.346 in.). The core 16 was fabricated of
two "C"-shaped halves, joined at lines 92, to accommodate the
winding of output coils 29, 30 and input coils 26, 28 over the
core material.

The core material was a
laminated iron-based magnetic alloy sold by Honeywell as
METGLAS Magnetic Alloy 2605SA1. The magnet material was a
combination of iron, neodymium, and boron.

The input coils 26, 28 were
driven at an oscillator frequency of 87.5 KHz, which was
determined to produce optimum efficiency using a switching
control circuit configured as shown in [Figure
2](#fig2). This frequency has a period of 11.45 microseconds.
The flip flop 54 is arranged, for example, to be set and reset
on rising edges of the clock signal input from the oscillator,
so that each pulse driving one of the FETS 60, 62 has a
duration of 11.45 microseconds, and so that sequential pulses
are also separated to each FET are also separated by 11.45
microseconds.

[Figure 6A-6H](#fig6)
are graphical views of signals which simultaneously occurred
within the apparatus of [Figures 1](#fig1) and 2
during operation with an applied input voltage of 75 volts.
Figure 6A shows a first drive signal 100 driving FET 60, which
conducts to drive the right input coil 26. Figure 6B is shows
a second drive signal 102 driving FET 62, which conducts to
drive the left input coil 28.

[Figures 6C](#fig6)
and 6D show voltage and current signals associated with
current driving both the FETS 60, 62 from a battery source.
Figure 6C shows the level 104 of voltage V. While the nominal
voltage of the battery was 75 volts, a decaying transient
signal 106 is superimposed on this voltage each time one of
the FETS 60, 62 is switched on to conduct. The specific
pattern of this transient signal depends on the internal
resistance of the battery, as well as on a number of
characteristics of the magnetic generator 10. Similarly,
Figure 6D shows the current 106 flowing into both FETS 60, 62
from the battery source. Since the signals 104, 106 show the
effects of current flowing into both FETS 60, 62 the transient
spikes are 11.45 microseconds apart.

[Figure 6E-6H](#fig6)
show voltage and current levels measured at the output coils
29, 30. [Figure 6E](#fig6) shows a voltage output
signal 108 of the right output coil 29, while Figure 6F shows
a voltage output signal 110 of the left output coil 30. For
example, the output current signal 116 of the right output
coil 29 includes a first transient spike 112 caused when the a
current pulse in the left input coil 28 is turned on to direct
magnetic flux through the right magnetic path 18, and a second
transient spike 114 caused when the left input coil 28 is
turned off with the right input coil 26 being turned on.
Figure 6G shows a current output signal 116 of the right
output coil 29, while Figure 6H shows a current output signal
118 of the left output coil 30.

[Figure 7](#fig7)
is a graphical view of output power measured using the
electromagnetic generator 10 and eight levels of input
voltage, varying from 10v to 75v. The oscillator frequency was
retained at 87.5 KHz. The measurement points are represented
by indicia 120, while the curve 122 is generated by polynomial
regression analysis using a least squares fit.

[Figure 8](#fig8)
is a graphical view of a coefficient of performance, defined
as the ratio of the output power to the input power, for each
of the measurement points shown in [Figure 7](#fig7).
At each measurement point, the output power was substantially
higher than the input power. Real power measurements were
computed at each data point using measured voltage and current
levels, with the results being averaged over the period of the
signal. These measurements agree with RMS power measured using
a Textronic THS730 digital oscilloscope.

While the electromagnetic
generator 10 was capable of operation at much higher voltages
and currents without saturation, the input voltage was limited
to 75 volts because of voltage limitations of the switching
circuits being used. Those skilled in the relevant art will
understand that components for switching circuits capable of
handling higher voltages in this application are readily
available. The experimentally-measured data was extrapolated
to describe operation at an input voltage of 100 volts, with
the input current being 140 ma, the input power being 14
watts, and with a resulting output power being 48 watts for
each of the two output coils 29, 30, at an average output
current of 12 ma and an average output voltage of 4000 volts.
This means that for each of the output coils 29, 30, the
coefficient of performance would be 3.44.

While an output voltage of
4000 volts may be needed for some applications, the output
voltage can also be varied through a simple change in the
configuration of the electromagnetic generator 10. The output
voltage is readily reduced by reducing the number of turns in
the output windings. If this number of turns is decreased from
450 to 12, the output voltage is dropped to 106.7, with a
resulting increase in output current to 0.5 amps for each
output coil 29, 30. In this way, the output current and
voltage of the electromagnetic generator can be varied by
varying the number of turns of the output coils 29, 30,
without making a substantial change in the output power, which
is instead determined by the input current, which determines
the amount of magnetic flux shuttled during the switching
process.

The coefficients of
performance, all of which were significantly greater than 1,
plotted in [Figure 8](#fig8) indicate that the
output power levels measured in each of the output coils 29,
30 were substantially greater than the corresponding input
power levels driving both of the input coils 26, 28.
Therefore, it is apparent that the electromagnetic generator
10 can be built in a self-actuating form, as discussed above
in reference to [Figure 1](#fig1). In the example
of [Figure 1](#fig1), except for a brief
application of power from the external power source 38, to
start the process of power generation, the power required to
drive the input coils 26, 28 is derived entirely from power
developed within the right output coil 29. If the power
generated in a single output coil 29, 30 is more than
sufficient to drive the input coils 26, 28, an additional load
126 may be added to be driven with power generated in the
output coil 29 used to generate power to drive the input coils
26, 28. On the other hand, each of the output coils 29, 30 may
be used to drive a portion of the input coil power
requirements, for example with one of the output coils 26, 28
providing the voltage V for the FET 60 (shown in [Figure 2](#fig2)), while the other output coil
provides this voltage for the FET 62.

Regarding thermodynamic
considerations, it is noted that, when the electromagnetic
generator 10 is operating, it is an open system not in
thermodynamic equilibrium. The system receives static energy
from the magnetic flux of the permanent magnet. Because the
electromagnetic generator 10 is self-switched without an
additional energy input, the thermodynamic operation of the
system is an open dissipative system, receiving, collecting,
and dissipating energy from its environment; in this case,
from the magnetic flux stored within the permanent magnet.
Continued operation of the electromagnetic generator 10 causes
demagnetization of the permanent magnet. The use of a magnetic
material including rare earth elements, such as a samarium
cobalt material or a material including iron, neodymium, and
boron is preferable within the present invention, since such a
magnetic material has a relatively long life in this
application.

Thus, an electromagnetic
generator operating in accordance with the present invention
should be considered not as a perpetual motion machine, but
rather as a system in which flux radiated from a permanent
magnet is converted into electricity, which is used both to
power the apparatus and to power an external load. This is
analogous to a system including a nuclear reactor, in which a
number of fuel rods radiate energy which is used to keep the
chain reaction going and to heat water for the generation of
electricity to drive external loads.

[Figure 9](#fig9)
is a cross-sectional elevation of an electromagnetic generator
130 built in accordance with a second version of the first
embodiment of the present invention. This electromagnetic
generator 130 is generally similar in construction and
operation to the electromagnetic generator 10 built in
accordance with the first version of this embodiment, except
that the magnetic core 132 of the electromagnetic generator 10
is built in two halves joined along lines 134, allowing each
of the output coils 135 to be wound on a plastic bobbin 136
before the bobbin 136 is placed over the legs 137 of the core
132. [Figure 9](#fig9) also shows an alternate
placement of an input coil 138. In the example of [Figure 1](#fig1), both input coils 26, 28 were
placed on the upper portion of the magnetic core 16, with
these coils 26, 28 being configured to establish magnetic
fields having north magnetic poles at the inner ends 31, 32 of
the coils 26, 28, with these north magnetic poles thus being
closest to the end 14 of the permanent magnet 12 having its
north magnetic pole. In the example of [Figure
9](#fig9), a first input coil 26 is as described above in
reference to [Figure 1](#fig1), but the second
input coil 138 is placed adjacent the south pole 140 of the
permanent magnet 12. This input coil 138 is configured to
establish a south magnetic pole at its inner end 142, so that,
when input coil 138 is turned on, flux from the permanent
magnet 12 is directed away from the left magnetic path 20 into
the right magnetic path 18.

[Figure 10](#fig10)
and [Figure 11](#fig11) show an electromagnetic
generator 150 built in accordance with a first version of a
second embodiment of the present invention, with [Figure 10](#fig10) being a top view thereof, and
with [Figure 11](#fig11) being a front elevation
thereof. This electromagnetic generator 150 includes an output
coil 152, 153 at each corner, and a permanent magnet 154
extending along each side between output coils. The magnetic
core 156 includes an upper plate 158, a lower plate 160, and a
square post 162 extending within each output coil 152, 153.
Both the upper plate 158 and the lower plate 160 include
central apertures 164.

Each of the permanent
magnets 154 is oriented with a like pole, such as a north
pole, against the upper plate 158. Eight input coils 166, 168
are placed in positions around the upper plate 158 between an
output coil 152, 153 and a permanent magnet 154. Each input
coil 166, 168 is arranged to form a magnetic pole at its end
nearest to the adjacent permanent magnet 154 of a like
polarity to the magnetic poles of the magnets 154 adjacent the
upper plate 158. Thus, the input coils 166 are switched on to
divert magnetic flux of the permanent magnets 154 from the
adjacent output coils 152, with this flux being diverted into
magnetic paths through the output coils 153. Then, the input
coils 168 are switched on to divert magnetic flux of the
permanent magnets 154 from the adjacent output coils 153, with
this flux being diverted into magnetic paths through the
output coils 152. Thus, the input coils form a first group of
input coils 166 and a second group of input coils 168, with
these first and second groups of input coils being alternately
energized in the manner described above in reference to [Figure 1](#fig1) for the single input coils 26, 28.
The output coils produce current in a first train of pulses
occurring simultaneously within coils 152 and in a second
train of pulses occurring simultaneously within coils 153.

Thus, driving current
through input coils 166 causes an increase in flux from the
permanent magnets 154 within the posts 162 extending through
output coils 153 and a decrease in flux from the permanent
magnets 154 within the posts 162 extending through output
coils 152. On the other hand, driving current through input
coils 168 causes a decrease in flux from the permanent magnets
154 within the posts 162 extending through output coils 153
and an increase in flux from the permanent magnets 154 within
the posts 162 extending through output coils 152.

While the example of [Figure 10](#fig10) and [Figure 11](#fig11)
shows all of the input coils 166,168 deployed along the upper
plate 158, it is understood that certain of these input coils
166, 168 could alternately be deployed around the lower plate
160, in the manner generally shown in [Figure
9](#fig9), with one input coil 166, 168 being within each
magnetic circuit between a permanent magnet 154 and an
adjacent post 162 extending within an output coil 152, 153,
and with each input coil 166, 168 being arranged to produce a
magnetic field having a magnetic pole like the closest pole of
the adjacent permanent magnet 154.

[Figure 12](#fig12)
is a top view of a second version 170 of the second embodiment
of the present invention, which is similar to the first
version thereof, which has been discussed in reference to [Figure 10](#fig10) and [Figure 11](#fig11),
except that an upper plate 172 and a similar lower plate (not
shown) are annular in shape, while the permanent magnets 174
and posts 176 extending through the output coils 178 are
cylindrical. The input coils 180 are oriented and switched as
described above in reference to [Figure 9](#fig9)
and [Figure 10](#fig10).

While the example of [Figure 12](#fig12) shows four permanent magnets,
four output coils and eight input coils it is understood that
the principles described above can be applied to
electromagnetic generators having different numbers of
elements. For example, such a device can be built to have two
permanent magnets, two output coils, and four input coils, or
to have six permanent magnets, six output coils, and twelve
input coils.

In accordance with the
present invention, material used for magnetic cores is
preferably a nanocrystalline alloy, and alternately an
amorphous alloy. The material is preferably in a laminated
form. For example, the core material is a cobalt-niobium-boron
alloy or an iron based magnetic alloy.

Also in accordance with the
present invention, the permanent magnet material preferably
includes a rare earth element. For example, the permanent
magnet material is a samarium cobalt material or a combination
of iron, neodymium, and boron.

While the invention has been
described in its preferred versions and embodiments with some
degree of particularity, it is understood that this
description has been given only by way of example and that
numerous changes in the details of construction, fabrication,
and use, including the combination and arrangement of parts,
may be made without departing from the spirit and scope of the
invention.

**Claims** [ Not
included here ]

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[In Disdain of Garbage Physics](meg-debunked.pdf) ( PDF )

by Shawn Bishop

June 2002

Debunks the MEG ...  
  


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