Troy Reed -- Magnetic Motor

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**Troy REED**

**Magnetic Motor**

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![](mtrgnr.jpg)

***Free Press*, Little Rock, AR ( April 14-27, 1994 )**

**"Magnetic Miracle"**

**by**

**Bud Kenny**

*Inventor's design consumes no fuel, emits no
fumes*

Devices that have truly improved the human condition - such as
electricity, the telephone and the airplane - were created by
people who passionately believe their inventions would make the
world a better place to live. Troy Reed of Tulsa, Oklahoma is
such a person.

Reed has invented and patented a motor that consumes no fuel
and emits no fumes. It is powerful enough to turn a 7,000-watt
generator, which is enough electricity to run an average home.
Production of the Reed Magnetic Motor for use by the general
public may begin by year's end.

Reed, 57, has also invented an automobile called "Surge" that
employs his new technology. Unlike a battery-powered car, Reed's
Surge does not have to be plugged in to be recharged. The car
recharges itself as it rolls down the highway at speeds of up to
85 miles an hour. Reed and actor Dennis Weaver, a cousin and
inventor in the project, plan to make the first highway test-run
of the car this summer.

Reed said he has been contacted about coverage of the test run
by, among others, 20/20, 60 Minutes, Larry King Live, Primetime
Live and CNN. A representative of CNN, Reed said, has already
seen the car and might broadcast daily updates during the
journey.

The idea for this technology came to Reed in a number of dreams
and visions over the past 35 years. He said he got the first in
1959 while employed as a machinist making 70 cents an hour.
Thirty years later, in 1989, he put those dreams to the test,
turning a hand crank that put the first Reed Magnetic Motor in
motion. That prototype was seven feet tall, weighed more than
500 pounds, had four moving parts and powered a 500-watt
generator. His latest motor takes two car batteries to start
(they are re-charged by the generator), is 20 inches high,
weighs less than 200 pounds, has one moving part and runs a
7000-watt generator.

If Reed's motor works as well as he says it does, it would be a
rather amazing technological breakthrough. After all, it would
mean a person could live anywhere one wanted with all the
comforts and never have to pay an electric bill. One would also
be able to drive to work, or anywhere else, without consuming
fuel. And best of all, one could do these things without
polluting the environment.

Although most people have never heard of the Reed Magnetic
Motor, it is well known in the science world. Since 1989 Reed
and his motor have been featured at numerous international
scientific conferences - the most recent on in Denver in March.
Reed also has been written up in scientific journals and is
included in the latest edition of Monuments of Mars, a book of
inventors written by former NASA science writer Richard
Hoagland.

If Reed has his way, his motor soon will no longer be a
scientific curiosity. Currently he is in the final stages of
granting a license to produce the motor to an American company
and a company in India. Reed would not give the names of the
companies because he said he is still "negotiating."

"I've been approached by lots of companies from all over the
world," Reed said. "I wanted the company that builds this motor
to be doing it for the same reason I developed it - to help
mother earth."

Reed did say that the companies granted licenses would start
producing the motors for the consumer almost immediately. "The
technology is already there, it is just a matter of putting all
together the right way to make it work," Reed said.

The 1989 prototype uses a horizontal shaft with several magnets
on it. Above the shaft are four vertical spring-loaded pistons
with a magnet on the end closest to the shaft. Turning the hand
crank spins the horizontal shaft and the magnetic spring-loaded
pistons move up and down to trigger the motion of the shaft and
the magnetic force field. Once the shaft is put into motion, it
continues to spin until a brake is applied.

Instead of moveable pistons, the latest model of the motor uses
and electronic system and stationary magnets to start and
control the motion of the shaft. Consequently, the only moving
part in the motor is the horizontal shaft. In the current model,
the shaft turns in bearings, but Reed said the mass-produced
model will not have the bearings. Instead, the shaft will be
magnetically suspended inside the motor casing. Suspending the
shaft means there will be nothing to wear out, or make noise,
Reed said.

Reed is aware inventions such as his often end up being shelved
away from the consumer by a large oil company. So Reed said he
has proceeded with caution. "Just like the companies that are
going to produce these motors, I made sure that my investors
were motivated for the right reasons," Reed said. "If they are
only in it for the money, then I turned them away. On the other
hand, if they share my desire to see this technology in the
marketplace to help save the environment, then we made a deal."

Reed said he also has been careful in how he financed the
development of his motor. He said he talked with other would-be
world-saving inventors who were put out of business by the
government for violating interstate security exchange laws.
"They needed capital to develop their ideas, so they sold their
investors stock," Reed said. "It always takes longer to develop
something like this than you think it will. So when it came time
to make good on that stock, they couldn't do it."

When Reed needed capital, instead of issuing stock he gave his
investors promissory notes that were contingent on his invention
eventually making it to market. Once the motors are available to
the public, Reed said he will offer his investors the option of
"holding the promissory notes or exchanging them for stock."

However, the federal government is aware of what is going on at
Reed Technologies. In fact, Reed said NASA has volunteered to
test the motor.

Reed estimated it will cost about $3,500 per motor to mass
produce his invention.

Bud Kenny of Hot Springs is scheduled to begin a 15-year
world-walking tour on June 5 (see related story page 23). Kenny
will live in a small house on wheels, which will be pulled by
two mules. Electricity for the house will be provided by
alternative electrical generating systems such as solar panels
and a pedal generator that will store power from the rotation of
Dylan's wheels. Kenny's first stop on his world tour will be
around the first of August in Tulsa, where Reed will help Kenny
develop the electrical system for the home.

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**http://control-alt-delete.ca/v-web/bulletin/bb/viewtopic.php?t=4249&**

PostPosted: Fri Mar 17, 2006 12:14 pm   
Post subject:  Reply with quote

The problem that happened is that Troy (Dad) and Evelyn his
wife at the time and VP of the company got an device while
dealing with a company to manufacture the base product.   
Of coarse egos got in the way along with financial problems.

Some of the technology did make it into the EZGO golf cart. A
lot of other issue between Reed Technologys and other company
that where in negotiations.

Now for an update Reed Technology is Evelyn and she I think has
moved to Costa Rica.

Dad has been working on some other project that may someday
come out. As for me I had to go back to work to make a living
but in the back of my mind I still want to built the second
generation of the magnetic motor that was named the Mach II
which I still have the original plans I drew up so 10 years ago.
The Mach II was designed to have around 400 HP at 1500 RPMs. I
am listed as the co inventor of this motor and maybe some day I
can get back to it. Many people in the Free energy groups like
Richard has seen the base plans for this next generation motor.

But with the issue that happened who know when this project
will continue.

Sorry to all of you that was involved and where let down.

Thanks for your understanding,

Mike

---

**Unidentified source ---**

A new free energy magnet motor is coming on the scene. Troy
Reed of Tulsa, OK has developed a permanent magnet device that
produces free energy. It has two sets of stationary magnets and
two sets of magnets mounted on freely turning disks. Spring-type
injector pins are used to keep the motor turning at a constant
RPM (about 500) as well as to overcome magnetic attraction. The
device is started using a normal starter motor and then runs
freely and continues to produce energy. For more information
contact Reed Magnetic Motor, Inc., POB 700395, Tulsa, OK 74170,
or call 918-743-1112.

---

**www.geocities.com/area51/shadowlands/6583/project114.html**

Excerpt from:

**"A Review Of Zero Point Energy And Free
Energy Theory, Progress, And Devices"**

**by**

**Patrick G. Bailey, Ph. D.**

P.O. Box 201, Los Altos, CA 94023-0201

The Reed (1991) Magnetic Motor is an electromechanical device
that Troy Reed says runs on magnetic power. The author has
developed a small prototype and a larger unit that have both
undergone several demonstrations and testing programs. He has
also filed for a Patent with the Patent Office and the Foreign
PTO/EPO. In his design, eight permanent magnets are placed on
each of four disks. Two outer disks remain stationary while the
two inner ones are mounted on a common shaft and are allowed to
turn freely. Videotapes and other information are available.

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**USP Appln. # 2003 066830**

**( 4-10-2003 )**

**Magnetic Heater Apparatus and Method**

**Reed, Troy**; *(Skiatook, OK)***; Lunneborg, Tim**;
*(Wahpeton, ND)***; Loll, Kevin**; *(Wahpeton, ND)***;
Dimmer, Paul Gene**; *(Wahpeton, ND)***; Thomas,
James Ronald**; *(Battle Lake, MN)***; Thomas, Neil
Howard**; *(Brookings, SD)*

**U.S. Current Class: 219/672**; 219/628   
**Intl Cl.:**H05B 006/10   
**Correspondence:** MERCHANT & GOULD PC,  P.O. BOX
2903, MINNEAPOLIS, MN 55402-0903   
**Assignee:** MagTec LLC, Fargo ND

**Abstract ---** An apparatus and method for generating
heat, in particular for heating a fluid. The apparatus includes
a frame, with at least one permanent magnet fixedly mounted to
the frame. An electrically conductive member is disposed
proximate the permanent magnets. The magnetic field of the
magnets upon the conductive member is made to vary cyclically.
Typically either the permanent magnets, the conductive member,
or both are movable with respect to one another. Relative motion
of the conductive member and the magnets causes the magnetic
field experienced by the conductive member to vary, which causes
it to become hot. The total heat energy generated in the
conductive member may exceed the total energy applied to the
apparatus to produce the varying magnetic field. The apparatus
may include a fluid path proximate the conductive member. Fluid
in the fluid path receives heat from the conductive member. The
apparatus may also include a mounting member for mounting the
conductive member, a drive mechanism for moving the conductive
member, and a fluid driver for driving fluid within the fluid
path. The method includes the steps of either an electrically
conductive member, a permanent magnet proximate the conductive
member, or both so as to heat the conductive member. The method
may include the step of passing a fluid through a fluid path
proximate the conductive member such that the fluid absorbs heat
from the conductive member.

***Description***

BACKGROUND OF THE INVENTION

[0001] The claimed invention relates to an apparatus and method
for generating heat using magnets. More particularly, the
claimed invention relates to an apparatus and method for
generating heat using magnets, in particular permanent magnets,
and transferring the heat to a working fluid.

[0002] A variety of methods and devices for heating fluids are
known. Most conventional methods for heating fluids involve
either combustion or resistive heating. However, neither of
these approaches is entirely satisfactory.

[0003] Heating fluids by combustion has been known since
antiquity. Essentially, a flame is produced, and is placed
proximate the fluid to be heated. In some applications, the
flame is applied directly to the fluid, for example when air is
blown across a flame in a conventional gas furnace. In other
applications, the flame is applied to a heat sink or heat
conductor, for example when a metal tank is heated over a flame
in a conventional water heater.

[0004] Many variations of this basic approach are known.
However, they share several common disadvantages. First, flame
is inherently dangerous. Flammable materials must be kept away
from the flames in order to prevent the flame from spreading.
Generally, this means any flame heating device must be made of
non-flammable materials, and must be built in such a way as to
prevent the entry of any flammable materials into the vicinity
of the flame.

[0005] In addition, any flame source requires a steady flow of
fuel. This requires fuel lines, tanks, or similar structures,
which can prove inconvenient in certain applications. In
addition, fuel lines and tanks may present a fire or explosion
hazard.

[0006] Similarly, flames require a steady flow of oxygen.
Commonly oxygen is furnished via a blower that provides a flow
of air to the flame. However, for certain applications, for
example heating liquids, it is difficult or inconvenient to
provide a reliable source of air.

[0007] Furthermore, flames produce various combustion products,
many of which present a nuisance or a hazard. Soot build-up is
common in conventional flame-based heating systems, and as a
result such systems require regular cleaning. More seriously,
flames are notorious for producing potentially toxic gases, such
as carbon monoxide. Care must be taken in the design of
flame-based heating systems to avoid the production of such
gases, or to vent them away from areas used by people and
animals.

[0008] In addition, many combustion byproducts are
environmentally destructive. This is especially true when
combustion is chemically incomplete, for reasons such as poor
fuel mixing, low burn temperature, etc. In such cases, a variety
of environmentally hazardous compounds may be produced.
Furthermore, nearly all fuels produce so-called "greenhouse
gases" during combustion, most notably carbon dioxide, even when
combustion is relatively "clean". Although carbon dioxide and
other greenhouse gases are not necessarily directly harmful to
people in small quantities, production of such gases is
generally considered a disadvantage, in that they are widely
believed to contribute to global climate change.

[0009] Also, many conventional flame-based heating systems
operate by generating one or more extremely high-temperature
point-sources of heat. That is, the active components of the
systems become extremely hot, in many cases hot enough to cause
injury or damage materials not specially designed for high heat
tolerance. Thus people, as well as plastics, wood, paper, etc.
must be kept away from the active components of a flame-based
heating system in order to avoid a risk of injury or damage.

[0010] In addition, conventional flame-based heating systems
generally require numerous components such as valves, tubing,
flame nozzles, etc. that are either in or near the fluid to be
heated. For generally non-reactive fluids, such as air, this is
of limited concern. However, if corrosive or otherwise hazardous
fluids are to be heated, it is typically necessary to either
design the system specifically to avoid direct contact with the
fluid to be heated, or to use components and materials that are
resistant to the fluid in question. For complicated parts, such
as valves and nozzles, this can present manufacturing and
maintenance difficulties.

[0011] Resistive heating of fluids is also well-known.
Conventional systems operate by passing an electrical current
through a heating element with a high electrical resistance. The
current flow generates heat within the heating element, and the
heat is then transferred directly or indirectly to a fluid.

[0012] Although resistive heating avoids certain difficulties
inherent in flame-based systems, it also suffers from several
disadvantages. Though resistive heating systems do not require
either fuel or oxygen, they do require that electricity be
provided to the heating elements. Like fuel lines and air fans,
electrical wiring may be difficult or inconvenient for certain
applications.

[0013] Similarly, many conventional resistive heating systems
operate by generating one or more extremely high-temperature
point-sources of heat. Typically, the operating current is
passed through one or more relatively small heating elements.
The elements thus become extremely hot. In many cases the
heating elements are heated to the point of incandescence, and
may reach several thousand degrees Fahrenheit. People, plastics,
wood, paper, even some types of metal and glass must be kept
away from the active components of a resistive heating system in
order to avoid a risk of injury or damage.

[0014] Furthermore, such temperatures exceed the ignition
temperatures of certain flammable gasses and vapors, so such
substances must also be kept away from the heating elements and
other active components of a resistive heating system. If the
presence of combustible gasses and vapors cannot be avoided, the
active components must be sealed in a gas-tight enclosure to
prevent fire or explosion.

[0015] In addition, resistive heating, depending as it does on
transmission of a substantial electric current, poses an
inherent danger of electric shock. Arcing and sparking to and
from electrically energized components is a significant risk. In
addition, applications that involve potentially conductive
fluids, in particular water, are of special concern with
resistive heating devices. The presence of such conductive
fluids in or near current paths can cause short-circuits that
may damage the device or harm persons or property nearby.

[0016] Furthermore, resistive heating systems are perhaps even
more susceptible to corrosive or otherwise degrading fluids than
flame-based systems. This is particularly the case with the
heating elements. Heating elements are typically small, and are
thus especially susceptible to corrosion by virtue of a high
ratio of exposed area to their total volume. Heating elements
are also commonly directly exposed to or directly immersed in
the fluid to be heated. Furthermore, the difficulties in making
heating elements corrosion resistant are increased because
heating elements must also survive extremely high temperatures,
and thus the materials, structures, and construction methods
that may be used are limited.

SUMMARY OF THE INVENTION

[0017] It is the purpose of the claimed invention to overcome
these difficulties, thereby providing an improved apparatus and
method for generating heat.

[0018] It is more particularly the purpose of the claimed
invention to provide an apparatus and method for heating a fluid
that does not require fuel, oxygen, or electrical current
delivered to the active heating components, and that does not
pose dangers from localized high temperatures, fire, electric
shock, or toxic byproducts.

[0019] The present invention relates to a ***magnetic
heater*** mechanism for generating heat. It includes at
least one electrically conductive member and at least one magnet
disposed proximate to one another. The magnetic field exerted by
the magnet upon the conductive member is made to vary
cyclically. This causes the conductive member to become hot. One
way of accomplishing this is to move at least one of the
conductive member and the magnet cyclically relative to the
other. The magnetic field exerted upon the conductive member by
the magnet thus varies cyclically.

[0020] More particularly, the magnetic field at a given point
on the conductive member changes, such that that point on the
conductive member becomes heated. In some embodiments most or
all of the conductive member will become heated in this fashion.
However, it is only necessary that a single point of the
conductive member be so heated.

[0021] The present invention also relates to a ***magnetic
heater with such a magnetic heater*** mechanism
therein. An embodiment of ***magnetic heater*** in
accordance with the principles of the claimed invention includes
at least one magnet and at least one electrically conductive
member disposed proximate the at least one magnet, but not in
direct contact therewith. In certain embodiments, the magnet may
be conveniently mounted on a frame. At least one of the
conductor and the magnet is cyclically movable in relation to
the other.

[0022] In a preferred embodiment, the at least one magnet is a
permanent magnet.

[0023] A fluid path is disposed in thermal communication with
the conductive member.

[0024] The relative motions of the conductive member and the
magnet may vary considerably. In certain embodiments, the
conductive member and/or the magnet may rotate in relation to
one another. In other embodiments, one or both of the conductive
member and the magnet may oscillate with respect to one another.
The type of cyclical motion is not critical.

[0025] When the conductive member and/or the magnet are
cyclically moved, the magnetic field applied to the conductive
member by the magnet varies cyclically at at least one point on
the conductive member, which causes at least that point of the
conductive member to become hot. The heating depends on the
electrical conductivity of the conductive member, not the
magnetic or physical properties. Thus it is not necessary that
the conductive member be ferromagnetic, or that it have any
particular magnetic properties. Likewise, it is not necessary
that the conductive member be a particular shape or size.

[0026] Fluid flowing through the fluid path absorbs heat from
the conductive member.

[0027] In certain embodiments, the amount of heat energy
generated within the conductive member exceeds the total energy
applied to produce the cyclically varying magnetic field.

[0028] It is noted that the physical process(es) responsible
for heat generation within the claimed invention have not been
definitively determined as of filing of this application. It is
believed that inductive heating may be at least partially
responsible. Although inductive heating is known per se, the
efficiency of the claimed invention in producing heat, which may
exceed 100% as normally measured, is both surprising and
unknown.

[0029] In addition, a device according to the principles of the
claimed invention may include a drive shaft on which to mount
the conductive member or the magnet for convenient cyclical
motion. It may also contain a motor or other drive mechanism for
driving the shaft. It may further contain a fluid driving
mechanism such as a pump or blower for forcing fluid through the
fluid path so as to heat the fluid efficiently.

[0030] An apparatus in accordance with the principles of the
claimed invention does not require that fuel, oxygen, or
electrical power be provided directly to or used within the
heater mechanism itself. The risks inherent in such provisions
are thus avoided.

[0031] An apparatus in accordance with the principles of the
claimed invention is not prone to electrical arcing or sparking,
as there is no need to apply external electrical power directly
to the conductive member or the magnet in order to generate
heat.

[0032] As pointed out above, one possible source for the heat
generated in the conductive member is magnetic induction. It is
noted that magnetic induction involves the production and
dissipation of electrical eddy currents. However, eddy currents
within conductors generally present negligible risks of arcing
and sparking, as they are not flowing from one component to
another or across a substantial distance, but rather are moving
only within a local area of the conductor itself. Furthermore,
eddy currents, like other electrical currents, tend to follow
the lowest resistance current path, which is typically within
the conductor rather than through the surrounding environment.
Thus, short circuits, arcing, and sparking are naturally
inhibited. Even fluids considered to be relatively conductive,
such as salt water, are normally much less conductive than
typical conductive solids such as metals. Thus, sparking dangers
may be avoided even if such conductive fluids are to be heated.

[0033] Likewise, an apparatus in accordance with the principles
of the claimed invention does not require either a flame or a
hot filament to generate heat, and does not require high
voltages or currents in exposed components.

[0034] An apparatus in accordance with the principles of the
claimed invention, having very few parts, may be readily
constructed of materials that are resistant to extreme
temperatures, corrosive environments, etc. As a result, an
apparatus in accordance with the principles of the claimed
invention lends itself to applications wherein such conditions
are found.

[0035] An apparatus in accordance with the principles of the
claimed invention furthermore does not require that any
component thereof be heated to an extreme temperature in order
to operate. The conductive member may be heated to a moderate
temperature similar to the desired temperature of the fluid,
without a loss of efficiency.

[0036] An apparatus in accordance with the principles of the
claimed invention, not being subject to many of the risks
associated with known flame-based heaters and resistive heaters,
is particularly well suited for commercial and home
applications, such as furnaces, space heaters, and water
heaters. However, it will be appreciated that these applications
are exemplary only, and that the claimed invention is not
limited thereto.

[0037] Furthermore, an apparatus in accordance with the
principles of the claimed invention does not produce waste gas,
or indeed waste products of any sort, and in particular does not
produce greenhouse gases or other environmentally dangerous
substances. Likewise, it does not produce solid waste or
particulates such as ash, soot, etc., and does not produce
noxious or corrosive liquids or gases, i.e. sulfur dioxide,
nitrogen oxides, sulfuric acid, etc. Therefore, its operation
does not present an environmental hazard.

[0038] A method in accordance with the principles of the
claimed invention includes the steps of rotating at least one
conductive member proximate at least one magnet so as to heat
the conductive member. A fluid may then be disposed proximate
the conductive member, so as to absorb heat from the conductive
member.

[0039] As noted, it is believed that magnetic induction may be
at least partially responsible for the heat generated in a
device in accordance with the claimed invention. It is noted
that conventional inductive heating devices typically rely on
electromagnets to generate magnetic fields. In a preferred
embodiment of the claimed invention, permanent magnets are used
instead.

[0040] However, alternate embodiments of the invention might
include electromagnets. Although electromagnets have many of the
same drawbacks as resistive heaters, in that they require an
electrical current to be delivered directly to the heating
element, and in that a device that uses electromagnets thus
requires wiring and must be designed with consideration given to
a risk of electrical shock, for certain embodiments it may be
desirable to utilize electromagnets.

[0041] Permanent magnets are extremely simple in structure, and
do not have moving parts, current paths, or other internal
components. As a result, they are extremely reliable, and are
physically, chemically, and thermally sturdy.

[0042] In addition, the use of permanent magnets in the claimed
invention, combined with the lack of any other unavoidable need
for electrical power, gas lines, waste disposal, etc. enables
embodiments of the claimed invention to be utilized with little
or no supporting infrastructure.

[0043] In addition, known devices utilizing magnetic inductive
heating are substantially less efficient in generating heat than
an apparatus in accordance with the principles of the claimed
invention. For this reason, it is believed that some phenomenon
other than or in addition to magnetic induction heating may be
responsible for the heat generated in the claimed invention.

[0044] Thus, it is emphasized that the heating effect is not
necessarily restricted to magnetic inductive heating.

BRIEF DESCRIPTION OF THE DRAWINGS

[0045] Like reference numbers generally indicate corresponding
elements in the figures.

[0046] FIG. 1 is a cross-sectional illustration of an
embodiment of an apparatus in accordance with the principles of
the claimed invention, adapted for rotary motion.

![](uspa1.jpg)

[0047] FIG. 2 is a perspective view of a frame with magnets
therein from the apparatus illustrated in FIG. 1.

![](uspa2.jpg)

[0048] FIG. 3 is a cross-sectional illustration of another
embodiment of an apparatus in accordance with the principles of
the claimed invention, having multiple conductive members.

![](uspa3.jpg)

[0049] FIG. 4 is a cross-sectional illustration of another
embodiment of an apparatus in accordance with the principles of
the claimed invention, showing conductive and non-conductive
layers.

![](uspa4.jpg)

[0050] FIG. 5 is a perspective view of an embodiment of a
conductive member in accordance with the principles of the
claimed invention.

![](uspa5.jpg)

[0051] FIG. 6 is a perspective view of another embodiment of a
frame with magnets therein.

![](uspa6.jpg)

[0052] FIG. 7 is a perspective view of yet another embodiment
of a frame with magnets therein.

![](uspa7.jpg)

[0053] FIG. 8 is a perspective view of an embodiment of a frame
with magnets therein similar to that in FIG. 2, showing magnet
polarities.

![](uspa8.jpg)

[0054] FIG. 9 is a cross-sectional illustration of another
embodiment of an apparatus in accordance with the principles of
the claimed invention, adapted for oscillatory motion.

![](uspa9.jpg)

[0055] FIG. 10 is a cross-sectional illustration of yet another
embodiment of an apparatus in accordance with the principles of
the claimed invention, adapted for pendulum motion.

![](uspa10.jpg)

[0056] FIG. 11 is a cross-sectional illustration of still
another embodiment of an apparatus in accordance with the
principles of the claimed invention, adapted for rotary motion,
having an integral fluid driver.

![](uspa11.jpg)

[0057] FIG. 12 is another perspective view of an embodiment of
a frame with magnets therein similar to that in FIG. 2, showing
magnet polarities different from those in FIG. 8.

![](uspa12.jpg)

[0058] FIG. 13 is a perspective view of an embodiment of an
apparatus in accordance with the principles of the claimed
invention, wherein the spacing between the magnet and the
conductive member varies.

![](uspa13.jpg)

[0059] FIG. 14 is a magnified view of a magnet similar to one
from FIG. 2.

![](uspa14.jpg)

[0060] FIG. 15 is a cross-sectional illustration of an
embodiment of an apparatus in accordance with the principles of
the claimed invention, wherein magnets are disposed on both
sides of the conductive member.

![](uspa15.jpg)

[0061] FIG. 16 is a magnified view of a portion of FIG. 15,
showing exemplary magnet orientation.

![](uspa16.jpg)

[0062] FIG. 17 is a cross-sectional illustration of an
embodiment of an apparatus in accordance with the principles of
the claimed invention, wherein magnets are disposed on both
sides of the conductive member.

![](uspa17.jpg)

[0063] FIG. 18 is a cross-sectional illustration of an
embodiment of a heater in accordance with the principles of the
claimed invention.

![](uspa18.jpg)

[0064] FIG. 19 is a schematic representation of a heat driven
apparatus in accordance with the principles of the claimed
invention.

![](uspa19.jpg)

[0065] FIG. 20 shows an embodiment similar to that of FIG. 15,
with the conductive member partially withdrawn.

![](uspa20.jpg)

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[0066] Referring to FIG. 1, an embodiment of an apparatus for
magnetically generating heat 10 in accordance with the
principles of the claimed invention includes a frame 20. The
frame need not be electrically conductive or ferromagnetic,
although it may be either or both. As illustrated in FIG. 3, the
frame 20 is a circular, essentially solid plate. However, it
will be appreciated by those knowledgeable in the art that this
is exemplary only, and that other shapes, including but not
limited to rectangles or open arrangements of struts, may be
equally suitable.

[0067] In addition, the frame is itself exemplary only. It
provides a convenient structure on which magnets 30 may be
mounted.

[0068] Returning to FIG. 1, the apparatus includes at least one
magnet 30 fixedly connected to the frame 20. As noted, in a
preferred embodiment the at least one magnet 30 is a permanent
magnet. A wide variety of magnets 30, permanent and otherwise,
may be suitable.

[0069] In embodiments where permanent magnets are used, those
embodiments are to some degree limited in their operation by the
maximum effective operating temperature of the particular
permanent magnets 30 that are used, i.e. if the magnets 30
overheat their magnetic field may decay. In a preferred
embodiment using permanent magnets, the magnets 30 are
high-temperature permanent magnets, such that they retain their
magnetic fields at elevated temperatures. In a more preferred
embodiment, the magnets 30 have an effective operating
temperature of at least the boiling point of water. In a still
more preferred embodiment, the magnets 30 have an effective
operating temperature of at least 350.degree. F.

[0070] Rare earth magnets are known to be suitable for the
purposes of the claimed invention. Samarium Cobalt magnets are
known to be particularly suitable for purposes of the claimed
invention. However, the use of both Samarium Cobalt magnets and
rare earth magnets in general is exemplary only, and other
permanent magnets may be equally suitable.

[0071] The "effective operating temperature", as the term is
used in the art, is the point beyond which the magnetic field
produced by a permanent magnet begins to degrade significantly.
Some minor degradation in field strength may be measurable below
this point. Likewise, the magnetic field may maintain at least
some integrity above the effective operating temperature.

[0072] It is noted that the effective operating temperatures
described herein are exemplary only. Permanent magnets with
different effective operating temperatures may be equally
suitable. In particular, it is noted that permanent magnets with
higher effective operating temperatures may be available, or may
become available, and that they may be equally suitable for use
with the claimed invention.

[0073] In addition, it is emphasized that the device as a whole
is not strictly limited to the operating temperatures of the
magnets 30. In certain embodiments, other portions of the
apparatus such as the conductive member 40 (see below) may reach
higher temperatures than are experienced by the magnets 30,
temperatures which may be well in excess of the maximum
operating temperature of the magnets 30 themselves.

[0074] Furthermore, the magnets 30 may be protected from excess
heat, as well as other potential hazards. For example, as
illustrated in FIG. 14, which shows a cross-section of a magnet
30 and a portion of a frame 20 similar to that of FIG. 3 in
cross-section and in greater detail, the magnet 30 may include a
protective layer 31. Such a protective layer 31 can provide
thermal protection, and/or structural and chemical protection. A
variety of materials may be suitable for use as a protective
layer 31, so long as they do not significantly reduce the
propagation of the magnetic field of the magnet 30.

[0075] For certain embodiments, aluminum may be provide a
suitable protective layer 31. It is noted that aluminum has a
high reflectivity, thus inhibiting the absorption of heat by the
magnet 30, and a high infrared emissivity, thus facilitating the
rapid re-radiation of heat from the magnet 30. These factors
combine to provide passive cooling for the magnet 30. In
addition, aluminum is relatively durable, and so a protective
layer 31 of aluminum serve to protect the magnet 30 physically.
Likewise, aluminum is relatively impermeable, and thus may
effectively seal the magnet 30 against any potential corrosive
effects due to moisture, oxygen, fluid flowing through the fluid
path 50 (see below), etc.

[0076] However, the use of aluminum is exemplary only, and a
variety of other materials may be equally suitable. In
particular, it is noted that multiple layers of material, rather
than a single layer (i.e. of aluminum), may also be suitable.
Likewise, the presence of a protective layer 31 is also
exemplary only.

[0077] In addition, for certain embodiments, the apparatus may
include an additional active or passive cooling mechanism 32 for
the magnets 30. A wide variety of cooling mechanisms 32 may be
suitable. For example, passive cooling mechanisms 32 may
include, but are not limited to, heat sinks and radiator fins.
Active cooling mechanisms 32 may include, but are not limited
to, coolant loops and refrigeration units.

[0078] It is noted that the fluid flow path 50, as described
below, may be configured to act as a cooling mechanism 32. Since
in certain embodiments of the claimed invention it provides a
mechanism for absorbing heat from the conductive member 40, it
may be well suited for absorbing heat from the magnets 30 as
well.

[0079] However, these particular cooling mechanisms 32, as well
as the presence of a cooling mechanism at all, are exemplary
only.

[0080] In a preferred embodiment, the apparatus includes a
plurality of magnets 30. As illustrated in FIGS. 1 and 3, the
apparatus has eight magnets 30, distributed symmetrically about
the periphery of the frame 20. However, it will be appreciated
by those knowledgeable in the art that this is exemplary only. A
wide variety of sizes, shapes, numbers, and arrangements of
magnets 30 may be equally suitable. In particular, asymmetrical
arrangements of magnets 30 and arrangements of magnets 30
elsewhere than the periphery of the frame 20 may be suitable.
For example, FIG. 6 shows an arrangement of magnets 30 in two
straight rows. FIG. 7 shows an arrangement of magnets 30 with
three in one arc near the center of the frame 20, and five in a
larger arc near the periphery of the frame 20.

[0081] In addition, although the magnets 30 are illustrated as
disk-shaped, this is exemplary only. Magnets in other shapes,
including but not limited to rectangular, may be equally
suitable. Furthermore, the magnets 30 need not all have the same
shape.

[0082] Moreover, although an arrangement of small magnets 30 is
convenient for certain applications, this is also exemplary
only. Magnets 30 of sizes other than those shown may be equally
suitable. Furthermore, in embodiments having more than one
magnet 30, the magnets 30 need not be of the same size.

[0083] Furthermore, as illustrated in FIG. 1, the magnets 30
are fixed to a surface of the frame 20. However, this
arrangement is exemplary only. As illustrated in FIG. 3, the
magnets 30 may be recessed into the frame 20. The magnets 30 may
be fully recessed as illustrated, such that the surfaces of the
magnets 30 are flush with the surface of the frame 20, or the
magnets 30 may be partially recessed into the frame 20.
Alternatively, the magnets 30 may be fully enclosed within the
frame 20, as illustrated in FIG. 4. A wide variety of
arrangements of magnets 30 may be suitable, so long as the
magnetic fields generated by the magnets 30 extend beyond the
surface of the frame 20.

[0084] The magnets may be oriented in various manners. In a
preferred embodiment, all of the magnets will be oriented with
alternating polarity. That is, as shown in FIG. 8, some have
their north poles N facing out of the paper, while those on
either side have their south poles S facing out of the paper
(and their north poles N facing into the paper). Such an
arrangement is advantageous, for at least the reason that it
produces a greater change in magnetic field intensity than would
be the case if all of the magnets 30 were aligned in the same
direction.

[0085] It is noted that such an arrangement may be equivalently
described as having the north pole N of some of the magnets 30
point directly towards the conductive member 40, while having
the north pole N of alternating magnets 30 point directly away
from the conductive member 40.

[0086] However, such an arrangement is exemplary only. Other
arrangements may be equally suitable. For example, it would also
be possible to arrange the magnets 30 with alternating polarity
such that the north pole of each magnet 30 is arranged opposite
or nearly opposite that of its neighbors. FIG. 12 shows an
example of such an arrangement. As shown therein, some of the
magnets 30 have their north poles N pointing inward towards the
center of the frame 20, while the magnets 30 on each side of
them have their north poles N pointing outward.

[0087] Furthermore, it may also be advantageous to arrange
magnets 30 with their north poles aligned in the same or nearly
the same direction, or in some fashion other than the
alternating fashions described above. In particular, it is
emphasized that the alignment of the poles of the magnets 30 is
not limited to either directly parallel with or directly
perpendicular to the plane (if any) of the frame 20. The magnets
30 may be oriented in essentially any fashion, so long as a
varying magnetic field results.

[0088] At least one electrically conductive member 40 is
disposed proximate the magnets 30.

[0089] The magnets 30 and the conductive member 40 are arranged
so that at least a portion of the conductive member 40
experiences a cyclically varying magnetic field from the magnets
30.

[0090] One way of producing the cyclically varying magnetic
field is for at least one of the electrically conductive member
40 and the permanent magnets 30 are to be cyclically movable
with respect to the other. Thus, as either the magnets 30 or the
conductive member 40 or both move, the magnetic field
experienced at different parts of the conductive member 40 will
vary.

[0091] A variety of motions may be possible, so long as a
cyclical variation in the magnetic field experienced by the
conductive member 40 is produced.

[0092] As one suitable form of motion, the magnets 30 may be
rotated with respect to the conductive member 40. Alternatively,
the conductive member 40 may be rotated with respect to the
magnets 30. Additionally, both the magnets 30 and the conductive
member 40 may be rotated in different directions, or at least at
different speeds, so as to produce relative motion between the
two.

[0093] In the embodiment illustrated in FIG. 1, the magnets 30
are mounted to the frame 20 in a generally planar arrangement.
Likewise in the embodiment illustrated in FIG. 1, the conductive
member 40 is planar. The frame 20 is disposed with the plane 33
of the magnets 30 generally parallel to and proximate the plane
43 of the conductive member 40. Such an arrangement is
advantageous, in that it is compact and convenient to operate,
and also in that it allows for rapid, regular cyclical motion by
rotating the frame 20 or the conductive member 40. However, it
is exemplary only. Other arrangements, including but not limited
to those described below, may be equally suitable.

[0094] It is noted that FIG. 1, as illustrated, is inclusive of
all of the above embodiments. That is, as illustrated, the frame
20 with the magnets 30 thereon may rotate, or the conductive
member 40 may rotate, or both. The structure, appearance, and
function of the apparatus will be similar regardless of which
elements rotate.

[0095] As noted above, other cyclical motions and other
arrangements of components may be equally suitable.

[0096] For example, oscillating motions may be suitable.

[0097] More particularly, linear oscillating motions may be
suitable for certain embodiments. As illustrated in FIG. 9, a
planar frame 20 with magnets 30 thereon may be placed proximate
a planar conductive member 40. Either or both of the frame 20
and the conductive member 40 may be moved cyclically in a
non-rotational direction, i.e. side-to-side. Alternatively, one
or both of the frame 20 and the conductive member 40 may be
moved towards and away from each other.

[0098] Alternatively, in some embodiments the oscillating
motion of a pendulum may be equally suitable. As illustrated in
FIG. 10, a curved frame 20 with magnets 30 thereon may be placed
proximate a conductive member 40 having a matching curve. The
frame 20 may be set into motion as a pendulum, so as to produce
cyclical variations in the magnetic field experienced by the
conductive member 40.

[0099] A wide variety of other arrangements and motions may
also be suitable, including but not limited to a cylinder or
torus rotating inside a larger torus, a cylinder rotating
proximate a flat plate, or a piston moving back and forth within
a cylinder. In each case, either the magnets 30, the conductive
member 40, or both may move.

[0100] It is noted that the term "cyclical variation", as used
herein with regard to magnetic fields, refers broadly to any
generally repetitive motion, wherein the magnetic field changes
according to some cycle. For example, the magnetic field may
rise and fall in intensity. As another example, the rise and
fall of the magnetic field may change in field direction, i.e.
change the angle of magnetic north, or even completely reverse
polarity from north to south. Furthermore, the variations in the
magnetic field may include a combination of changes in both
field direction and intensity. The pattern of repetition may be
simple or complex, and need not be precisely repeated with each
cycle. That is, the frequency, amplitude, etc. of the variation
may change from cycle to cycle. In addition, in embodiments
wherein both the intensity and the direction of the field
changes, it is not necessary for the intensity and the direction
to change synchronously, or according to the same cycle.

[0101] The term "cyclical variation" as used herein with regard
to physical motion, by extension, refers broadly to the physical
motion used to produced the cyclical variation of the magnetic
field. Likewise, it may have a pattern of repetition that is
simple or complex, and that varies from cycle to cycle

[0102] It is also noted that the total magnetic force or field
strength on the conductive member 40 need not change (although
it may in certain embodiments). Rather, the local field at a
given point on the conductive member 40 must change, in order
for that point to be actively heated.

[0103] For example, if, in the embodiment illustrated in FIG.
1, the frame 20 rotates, the magnets do not approach or recede
from the conductive member 40, since they are moving about an
axis perpendicular to the plane 33 of the magnets 30 and the
plane 43 of the conductive member 40. Thus, the total field
strength does not change. However, the field at any given point
on the conductive member 40 is constantly changing as the frame
20 rotates, i.e. as individual magnets approach and recede from
that point.

[0104] Furthermore, it is emphasized that although many of the
embodiments described herein utilize physical motion to produce
a cyclically varying magnetic field, this is exemplary only.
Arrangements for producing a cyclically varying magnetic field
without physical motion, including but not limited to the use of
variable electromagnets, may be equally suitable.

[0105] The cyclical change in the magnetic field causes the
conductive member 40 to become hot. In terms of physical
motions, with regard to FIG. 1, when the conductive member 40 is
rotated with respect to the magnets 30, (or vice versa) the
conductive member 40 becomes hot, because the magnetic field
experienced by the conductive member 40 is varying.

[0106] It is emphasized that the conductive member 40 is
electrically conductive; although it is heated by interacting
with magnets 30, the conductive member 40 is not required to be
ferromagnetic, or to have any other particular magnetic
properties. Although it may be ferromagnetic, it is the
electrical properties of the conductive member 40, not any
magnetic properties, that are important.

[0107] In a preferred embodiment, the conductive member 40 is
made of a durable, heat-tolerant, highly conductive material. In
a more preferred embodiment, the conductive member 40 is made of
metal. In a still more preferred embodiment, the conductive
member 40 is made of copper, or a copper alloy. This is
advantageous, as copper and many of its alloys are physically
durable, highly conductive, and resistant to high temperatures.
However, this is exemplary only, and other materials may be
equally suitable for use in the conductive member 40.

[0108] As noted, a wide variety of embodiments may be possible
in accordance with the principles of the claimed invention.
However, from the point of view of operating efficiency (about
which more is said later), the preferred embodiment is that
illustrated in FIG. 15.

[0109] Therein, the conductive member 40 is configured with a
first side 43 and a second side 45. A first frame 20 with a
plurality of first magnets 30 thereon is disposed a first
distance 12 away from the first side 43 of the conductive member
40. Similarly, a second frame 25 with a plurality of second
magnets 35 thereon is disposed a second distance 14 away from
the second side 45 of the conductive member 40.

[0110] It is preferred that the frames 20 and 25 are arranged
such that the magnets 30 and 35 are aligned with one another to
form pairs on each side of the conductive member 40. Likewise,
it is preferred that, for embodiments wherein the frames 20 and
25 are movable, they are movable together so as to maintain the
arrangement and keep the magnets 30 and 35 in pairs.

[0111] As shown in FIG. 16, it is furthermore preferred that
for any pair of magnets 30 and 35, their polarities face in the
same direction. Most preferably, the magnets 30 and 35 are
aligned such that one magnet in the pair has its north pole
facing directly towards the conductive member 40, and one magnet
in the pair has its north pole facing directly away from the
conductive member 40.

[0112] Such an arrangement has been found to produce a high
level of heating. It is believed that this is due to the steep
gradient in the magnetic field that is produced when the
conductive member 40 is disposed between two magnets 30 and 35
oriented in this fashion.

[0113] As shown in FIG. 16, both magnets 30 and 35 have their
north poles pointing directly to the left. However, it would be
equally suitable, and in accordance with this most preferred
arrangement, for both magnets 30 and 35 to have their north
poles pointing directly to the right.

[0114] Furthermore, as noted above, it may be suitable for
adjacent magnets to have opposing polarities. That is, if one
pair of magnets 30 and 35 have their poles arranged as shown in
FIG. 16 (north to the left), the magnet pairs adjacent to that
pair may have their poles arranged in the direction opposite
that shown in FIG. 16 (north to the right).

[0115] As with the embodiment shown in FIG. 1, the embodiment
of FIG. 15 may be conveniently expanded by the use of additional
conductive members 40 and magnets 30. An arrangement with three
conductive members 40 and four sets of magnets 30 is shown in
FIG. 17. It is noted that the number of conductive members 40
and magnets 30 is exemplary only, and that other numbers and
arrangements may be equally suitable.

[0116] In addition, it is noted that this preferred arrangement
is exemplary only, and that other arrangements may be equally
suitable.

[0117] The heat generated varies inversely with the distance 12
between the conductive member 40 and the magnets 30. Thus, in a
preferred embodiment of an apparatus in accordance with the
principles of the claimed invention, the conductive member 40 is
spaced a distance 12 of no more than 0.35 inches from the
magnets 30. In a more preferred embodiment, the conductive
member 40 is a distance 12 of no more than 0.060". However, this
arrangement is exemplary only.

[0118] In addition, although in certain embodiments the
distance between the magnets 30 and the conductive member 40 may
be fixed, this is exemplary only. It may be equally suitable to
vary the distance between the magnets 30 and the conductive
member 40, either during the operation of the apparatus or as an
adjustment while the apparatus is not operating.

[0119] In particular, it is noted that it is possible to vary
the magnetic field at the conductive member by varying the
distance between the magnets 30 and the conductive member 40. A
wide variety of embodiments may be suitable for doing so. For
example, referring to FIG. 1, varying the distance 12, i.e. by
moving the conductive member 40 or the frame 20 with the magnets
30 thereon from side to side, would change the magnetic field
experienced by the conductive member 40. If the distance 12 were
varied cyclically, this would generate heat in the conductive
member 40 regardless of whether the conductive member 40 or the
magnets 30 were rotated.

[0120] Another embodiment taking advantage of this feature is
illustrated in FIG. 13. Therein, the single magnet 30 and the
conductive member 40 are arranged such that when the frame 20
rotates, the distance 12 varies cyclically as the magnet 30
approaches and recedes from the conductive member 40.

[0121] It is furthermore noted that the variation in distance,
whether during operation or not, may be accomplished by moving
either the magnets 30, the conductive member 40, or both.

[0122] Alternatively, rather than adjusting the distance
between the magnets 30 and the conductive member 40, for certain
embodiments it may be advantageous to move the magnets 30 and/or
the conductive member 40 in and out of the apparatus 10.

[0123] For example, referring to FIG. 15, either or both of the
frames 20 and 25 and/or the conductive member 40 could be slid
into or out of the apparatus 10 as a whole. That is, rather than
(for example) moving the frames 20 and 25 apart so as to widen
the distances 12 and 14, the frames 20 and 25 could be moved
downwards, so as to partially or fully remove one or both from
the apparatus 10.

[0124] If both frames 20 and 25 are fully removed, the heat
generation in the apparatus 10 is essentially zero, as the
conductive member 40 are not exposed to a cyclically varying
magnetic field. If only one is removed, or if one or both are
partially removed, the heat generation of the apparatus 10 at a
given speed of operation would decrease, but not to zero.

[0125] Thus, this provides an additional way to control heat
production. Such motions may be considered structurally
analogous to the insertion and removal of fuel rods in a nuclear
reactor.

[0126] Such an arrangement is shown in FIG. 20, with the
conductive member 40 partially withdrawn from the apparatus 10.

[0127] As with the variations of the distances 12 and 14,
depending on the embodiment it may be advantageous for the
frames 20 and 25 to be removable while the apparatus 10 is not
operating, while it is operating, or both.

[0128] As noted above, in certain embodiments, the magnets 30
may be disposed in a planar arrangement, such that a surface of
the magnets 30 defines a plane 33. Likewise, the conductive
member 40 may have a planar shape, so as to generally conform to
a plane 43. This is a convenient arrangement for certain
embodiments, in that it allows for rapid motion (and hence rapid
variation in the magnetic field) without any relative
translation between the conductive member 40 and the magnets 30.
Thus, the conductive member 40 and the magnets 30 may be
disposed very close to one another without risking a collision.

[0129] However, as also noted previously, such an arrangement
is exemplary only. It is not necessary for the magnets 30 to be
arranged in a plane 33, or (as noted above) for the distance 12
between the magnets 30 and the conductive member 40 to be the
same for all magnets 30.

[0130] As heat is produced entirely by means of physical
motion, no source of electrical power, fuel, or oxygen is
necessary.

[0131] The description herein is primarily directed towards
rotary motion about an axis. This is convenient, in that rotary
motion about an axis may be easily and reliably produced by a
variety of means. In particular, rotary motion about an axis may
be produced by a variety of means that require only minimal
equipment and infrastructure are suitable, including but not
limited to windmills and water wheels. Likewise, internal
combustion engines, human or animal power, wave action, gravity,
connection with the rolling wheel of a vehicle, and other
sources of motive power may be equally suitable. Additionally,
rotary motion about an axis may also be produced using an
electric motor, such as a conventional AC or DC motor, or by
other artificial means.

[0132] In the case of an electric motor, it is noted that it is
possible to operate the claimed invention therewith by powering
the electric motor from a local source, such as a solar cell,
battery, or other short-range or self-contained source, rather
than by a connection to a large power grid. In embodiments with
electromagnets, the electromagnets similarly may be powered
without relying on a central electric grid. Thus, the invention
may be made portable, and used without substantial supporting
infrastructure. For example, embodiments may be constructed
without electrical lines.

[0133] Likewise, gas lines, exhaust lines, waste disposal
provisions, etc. may be dispensed with.

[0134] As a result, embodiments of the invention may be of use
even when connection with a standard electrical grid, gas
distribution system, etc. is inconvenient or impossible (i.e.,
in places where no such infrastructure is available such as
remote wilderness sites and undeveloped areas).

[0135] However, it is again emphasized that other forms of
motion other than rotary motion about an axis, including but not
limited to linear oscillation and pendular motion, may be
equally suitable.

[0136] One possible physical phenomenon that may be at least
partially responsible for heating the conductive member is
magnetic induction. Although magnetic induction is a known
phenomenon, a brief explanation as it may apply to the claimed
invention may be enlightening. In the following discussion, it
is assumed for the sake of clarity that magnetic induction is
responsible for heating the claimed invention. However, it is
noted that magnetic induction may not be the sole source of
heating, or even a source of heating, in the claimed invention.

[0137] In addition, for the sake of clarity, the following is
written specifically with respect to a single embodiment as
shown in FIG. 1, wherein the conductive member rotates, and the
magnets are fixed in place. However, it is noted that this
explanation, in so far as it may be applicable at all, is
generally applicable to any embodiment of the claimed invention.

[0138] It is well known that varying magnetic fields generate
electrical currents. Even if the magnets 30 generate a magnetic
field that is essentially constant in strength and polarity, as
is the case with permanent magnets as well as with
fixed-strength electromagnets, as the conductive member 40
rotates, different portions of the conductive member 40 approach
and recede from the permanent magnets 30. Thus, for any
arbitrary point of the conductive member 40, the magnetic field
experienced at that point varies, even if the magnetic fields
produced by the permanent magnets 30 remain constant.

[0139] Such a variation in magnetic field exerted at a given
point of the conductive member 40 could also be obtained by the
use of variable-strength magnets. For example, it is known to
vary the strength of the field emitted by an electromagnet by
changing the amount of current applied to the electromagnet.
Likewise, the polarity of an electromagnet may be changed by
reversing the direction of the current applied thereto. Such
variations may also be suitable for producing a cyclically
varying magnetic field at the conductive member 40, with or
without any actual physical motion.

[0140] The variation in magnetic field strength at each point
of the conductive member 40 generates localized eddy currents
within the conductive member 40. The eddy currents, like other
types of electrical current, dissipate energy in the form of
heat as they flow within the conductive member 40, due to the
electrical resistance of the conductive member 40. Thus, as the
conductive member 40 rotates in proximity to the permanent
magnets 30, the conductive member is heated.

[0141] Alternatively, some or all of the heating of the
conductive member 40 may be produced by the generation of
vibrations in the molecular structure of the conductive member
40 due to the varying magnetic field strength at each point,
which in turn causes internal stresses and/or friction between
molecules.

[0142] As a further alternative, stresses and/or variations in
the crystal structure of the conductive member 40 may be
produced by the varying magnetic field.

[0143] Although the forgoing description identifies physical
phenomena that may be involved in the production of heat in the
claimed invention, an apparatus in accordance with the
principles of the claimed invention is not limited to the
production of heat via those phenomena. Additional and/or
alternative phenomena may be involved.

[0144] In a preferred embodiment of a device according to the
principles of the claimed invention, the conductive member 40 is
disk-shaped. This is convenient, in that a disk-shape lends
itself to uniform rotation and heating. However, this shape is
exemplary only, and a wide variety of other shapes may be
equally suitable, including but not limited to square or
rectangular plates, curved components, cylinders, toroids, etc.

[0145] Also, in a preferred embodiment of a device according to
the principles of the claimed invention, the conductive member
40 is a single, integral piece of conductive material. However,
this configuration is exemplary only. A wide variety of other
configurations may be equally suitable.

[0146] For example, the conductive member 40 need not consist
entirely of electrically conductive material, so long as at
least a portion of it is electrically conductive. As illustrated
in FIG. 4, the conductive member 40 may consist of multiple
layers, with at least one electrically conductive layer 42 and
at least one non-conductive layer 44. In such a case, each
electrically conductive layer 42 is heated independently.

[0147] Furthermore, the conductive member 40 need not consist
of a closed loop or integral piece of conductive material. As
illustrated in FIG. 5, the conductive member 40 may consist of
two or more separate conductors 46 that are separated from one
another by non-conductive material 48. In such a case, each
conductor 46 is heated independently.

[0148] Likewise, the conductive member 40, even if a single
contiguous piece of conductive material, might be shaped with
apertures, or be constructed of wires, beams, rods, etc. with
empty space therebetween.

[0149] The rate of heat generation depends on the magnitude of
the variation in magnetic field experienced by the conductive
member 40. This in turn depends on the placement and field
strength of the magnets, on the speed of relative motion between
the conductive member 40 and the permanent magnets 30, the
placement of the conductive member 40 with respect to the
permanent magnets 30, and on the shape, size, and electrical
conductivity of the conductive member 40.

[0150] Likewise, the rate of heat generation currents depends
on the shape, size, and electrical conductivity of the
conductive member 40.

[0151] Therefore, for a given embodiment, the heat generated
may be controlled by varying the speed of relative motion
between the conductive member 40 and the magnets 30. Thus, the
heat generated by an apparatus in accordance with the principles
of the claimed invention may be controlled with a high degree of
precision. Because of the forgoing, the apparatus may be made to
operate at essentially any speed, so as to produce a wide range
of heat outputs. The apparatus is thus continuously variable in
heat output, up to the maximum temperature limits of the
materials used in its construction.

[0152] In a preferred application of an apparatus in accordance
with the principles of the claimed invention, the speed of
motion may be set such that the temperature of the conductive
member 40 does not exceed 120.degree. F., so as to enable
generation of heat without posing a burn hazard to persons
nearby.

[0153] In an alternative preferred embodiment of an apparatus
in accordance with the principles of the claimed invention, the
relative motion between the conductive member 40 and the magnets
30 may be set to a speed such that the conductive member 40 is
heated to at least the boiling point of water, so as to enable
generation of steam.

[0154] In yet another preferred embodiment of an apparatus in
accordance with the principles of the claimed invention, the
relative motion between the conductive member 40 and the magnets
30 may be set to a speed such that the conductive member 40 is
heated to at least 350.degree. F., so as to enable convenient
cooking or the release of large quantities of heat in a short
time.

[0155] It will be appreciated by those knowledgeable in the art
that the precise speed of motion that is necessary to achieve
the aforementioned temperatures depends on the geometry of the
particular embodiment. For example, for rotary motion, speeds of
less than 1 rpm or of greater than 5000 rpm may be suitable for
particular applications. Motions other than rotary likewise may
vary substantially. Furthermore, a variable speed may be equally
suitable, so as to generate variable temperatures and variable
quantities of heat.

[0156] A preferred embodiment of an apparatus in accordance
with the principles of the claimed invention also includes at
least one fluid path 50 proximate the conductive member 40. When
the conductive member 40 is heated, fluid in the fluid path 50
receives heat from conductive member 40. Heat transfer from the
conductive member 40 to fluid in the fluid path 50 may occur via
one or more of conduction, convection, and radiation.

[0157] However, although the presence of a fluid flow path 50
may be advantageous for certain applications, a fluid flow path
and fluid flowing therein are exemplary only. In other preferred
embodiments of an apparatus in accordance with the principles of
the claimed invention, heat may be generated for use via direct
conduction, or by radiation from the conductive member. For
example, heat could be transferred from the conductive member 40
to a solid heat conductor, heat sink, or heat storage device,
i.e. a mass of ceramic, brick, stone, etc.

[0158] It is noted that the term "fluid" is used herein in a
broad mechanical sense, so as to mean essentially any substance
that may be made to flow. Thus, fluids may include, but are not
limited to, sand, sugar, or other granular solids; regular
dimensional solids such as beads, beans, or pellets; or
irregular dimensional solids such as metal filings or crushed
stone. Likewise, materials that are essentially solid but that
are also sufficiently deformable so as to flow may also
suitable. Such materials include but are not limited to
paraffin, metallic sodium, certain plastics, etc. Fluids
suitable for use with the claimed invention are therefore not
limited to liquids or gases, although liquids and gases are not
excluded from or inappropriate for use with the claimed
invention. Furthermore, suitable fluids may likewise comprise
mixtures of different physical or chemical compounds, such as
pellets in a suspension of liquid, solids wholly or partially
dissolved in solvents, and emolliated mixtures of incompatible
fluids such as oil and water.

[0159] As illustrated in FIGS. 1, 3, and 4, the fluid path 50
is an open path that brings fluid into direct contact with the
conductive member 40. This is advantageous, in that it is simple
to construct. However, this configuration is exemplary only, and
a wide variety of other fluid paths 50, including but not
limited to enclosed ducts, pipes, and reservoirs may be equally
suitable.

[0160] In particular, it is noted that the fluid flow path 50
may be disposed partially or completely within other elements of
the apparatus. For example, the conductive member 40 may be
formed so that the fluid flow path 50 passes therethrough. As a
more concrete example, the conductive member 40 might include
one or more pipes or tubes made of conductive material. The
pipes could be adapted to accept the flow of fluid therethrough,
so as to form the fluid flow path 50 within the conductive
member 40 itself. Fluid flowing through the fluid flow path 50,
which in this exemplary embodiment is actually a part of the
conductive member 40, would then absorb heat as it passed
through the conductive member 40.

[0161] The apparatus may include a support member 60, with one
or both of the conductive member 40 and the frame 20 with the
magnets 30 thereon engaged therewith. As illustrated, the
support member 60 is a shaft mounted such that the conductive
member 40 or the frame 20 may rotate therewith. This provides a
simple and mechanically durable mechanism for rotating the
conductive member 40 or the magnets 30. However, this mechanism
is exemplary only, and a variety of other support members 60 may
be equally suitable for rotatably mounting the conductive member
40. Suitable support members 60 include, but are not limited to,
bushings, bearings, belts, chains, and gears.

[0162] As illustrated, the support member 60 extends through an
opening 41 in the conductive member 40. Similarly, as
illustrated, the support member 60 extends through an opening 21
in the frame 20.

[0163] In a configuration adapted to rotate the conductive
member 40, the opening 41 is configured to secure the conductive
member 40 to the support member 60 so as to rotate therewith,
while the opening 21 in the frame 20 is configured so that the
support member 60 freely rotates therein. Conversely, the
opening 41 may be configured so that the support member 60
rotates freely therein and the opening 21 may be configured so
that the frame 20 moves with the support member 60, so that the
magnets 30 may be rotated while the conductive member 40 remains
fixed.

[0164] Such an arrangement is convenient for rotary motion.
However, this arrangement is exemplary only, and a variety of
alternative arrangements may be equally suitable, both for
rotary and for non-rotary motion.

[0165] The apparatus may include a drive mechanism 70 engaged
with either the conductive member 40, the magnets 30 (i.e., via
the frame 20), or both. As illustrated, the drive mechanism 70
is engaged with the support member 60 such that the drive
mechanism 70 drives the support member 60, which as described
above may be used to drive either the conductive member 40 or
the frame 20. However, this arrangement is exemplary only, and a
variety alternative arrangements may be equally suitable. For
example, two separate drive mechanisms 70 may be used, one to
drive each of the conductive member 40 and the frame 20. Other
drive mechanisms 70 may be used to drive other configurations,
both rotary and non-rotary.

[0166] Likewise, a wide variety of drive mechanisms 70 may be
suitable, as noted above, including but not limited to electric
motors and windmill blades. Drive mechanisms are well known, and
are not described further herein.

[0167] The apparatus may include a fluid driver 80 adapted to
drive fluid through the fluid path 50. As illustrated, the fluid
driver 80 is a fan adapted for blowing a gas, such as air,
through the fluid path 50. However, this arrangement is
exemplary only, and a variety alternative arrangements may be
equally suitable. Likewise, a wide variety of fluid drivers 80
may be suitable, including but not limited to pumps for driving
liquid. Fluid drivers are well known, and are not described
further herein.

[0168] An apparatus in accordance with the principles of the
claimed invention may include more than one conductive member
40. Furthermore, any additional conductive members 40 may be
disposed proximate more than one arrangement of permanent
magnets 30, for example as illustrated in FIG. 3. As
illustrated, the several conductive members 40 are all mounted
to a single shaft 60, with fluid paths 50 proximate each
conductive member 40 Also as illustrated, the frames 20 are
connected with struts 90, so as to hold them fixed and rigid
with respect to one another while the conductive members 40
rotate. This arrangement is exemplary only, and a variety of
other arrangements may be equally suitable.

[0169] An apparatus in accordance with the principles of the
claimed invention may be configured so as to produce extremely
high efficiencies, in terms of the amount of heat generated
compared to the energy input required. The following description
is provided as an exemplary case.

[0170] In an embodiment of the claimed invention similar to
that illustrated in FIG. 1, the drive mechanism 70 comprises an
electric motor, supplied with 95 amperes of current at 220
volts. As is well-known, power may be calculated according to
the relation:

P=I.times.V Equation 1:

[0171] wherein:

[0172] P is the power in watts;

[0173] I is the current in amperes; and

[0174] V is the electrical potential in volts.

[0175] In accordance with Equation 1, the power supplied to the
electric motor is 20,900 watts.

[0176] In the exemplary embodiment, the fluid driver 80
comprises an electric fan, supplied with 8 amperes of power at
220 volts. According to Equation 1, the power supplied to the
fan is thus 1,760 watts.

[0177] Thus, the total power input into the system is 22,660
watts. For the sake of convenience, the input power may be
converted to BTU/hr. 1 watt is equivalent to approximately 3.415
BTU/hr. Thus, the total power input into the exemplary
embodiment is equivalent to 77,179 BTU/hr.

[0178] Total power output in the exemplary embodiment may be
conveniently determined from the change in thermal energy of
fluid as it passes through the system. In the exemplary
embodiment, air is used as a fluid. The heat output of the
system may be determined according to the known relation:

Q=q.times..rho..times.C.sub.p.times.(T.sub.O-T.sub.I) Equation
2:

[0179] wherein:

[0180] Q is the total heat output

[0181] q is the flow rate of air through the system

[0182] .rho. is the density of air

[0183] C.sub.p is the heat capacity of air

[0184] T.sub.O is the outlet temperature of the air

[0185] T.sub.I is the inlet temperature of the air

[0186] In the exemplary embodiment, the air flowing through the
device is heated by 80.degree. F. Thus, the difference between
the outlet and inlet temperatures of the air (T.sub.O-T.sub.I)
is 80.degree. F.

[0187] The flow rate of air through the system in the exemplary
embodiment is measured to be 3200 ft.sup.3/min. This may also be
expressed as 192,000 ft.sup.3/hr.

[0188] The remaining values are known to reasonable accuracy.
The density of air .rho. at standard temperature and pressure is
known to be approximately 0.075 lbs/ft.sup.3. The heat capacity
of air C.sub.p is known to be 0.24 BTU/lb-.degree. F.

[0189] Thus, according to Equation 2, the heat output of the
exemplary embodiment is 276,480 BTU/hr.

[0190] The efficiency of an apparatus is commonly expressed in
terms of the output divided by the input. The efficiency of the
exemplary embodiment in generating heat may thus be expressed as
(276,480 BTU/hr)/(77,179 BTU/hr), which reduces to a value of
approximately 3.58, or 358% efficiency.

[0191] It is noted that the preceding is exemplary only. An
apparatus in accordance with the principles of the claimed
invention is not limited to the particular devices, materials,
or power inputs and outputs described in the preceding
invention.

[0192] Furthermore, 358% efficiency is in particular exemplary
only, and is not to be considered to be a maximum value, a
minimum value, or even a preferred value. Apparatuses in
accordance with the principles of the claimed invention may be
constructed with a variety of operating efficiencies.

[0193] Thus, the total heat energy generated within the
conductive member 40 exceeds the total energy applied to the
apparatus 10. In the case described above, the ratio of heat
generated to energy applied is 3.58 to one, i.e. an efficiency
of 358%.

[0194] Several comments on theoretical energy efficiency
calculation may be in order at this point.

[0195] Although in the above description, as in practice, the
total energy calculations are determined by measuring the heat
change in the fluid (and therefore include the energy applied to
drive the fluid), as a theoretical matter it might be more clear
to consider the efficiency in terms of the energy applied to the
conductive member 40 and/or the magnets 30 so as to produce the
cyclically varying magnetic field (energy in), as compared to
the heat energy produced in the conductive member 40 thereby
(energy out).

[0196] For embodiments wherein the cyclical variations in the
magnetic field are produced by physical motion of the conductive
member 40 and/or the magnets 30, the actual input energy is
kinetic in nature.

[0197] When considering kinetic energy applied, the kinetic
energy applied to any supporting structures, such as a frame 20
that supports the magnets (and moves therewith) must of course
be included. Thus, the kinetic energy in question is the kinetic
energy applied to produce the cyclical motion between the
conductive member 40 and the magnets 30, not simply the kinetic
energy of the magnets 30 or the conductive member 40 alone. This
is true regardless of precisely what the motion is, or of how
much additional mass (if any) is moved as well.

[0198] Likewise, for embodiments wherein the cyclical
variations in the magnetic field are produced by variations in
the field strength of electromagnets, the actual input energy is
electrical in nature.

[0199] For embodiments that use both physical motion and
variable-power electromagnets, the input energy will be the sum
of the applied kinetic and electrical energy.

[0200] Thus, regardless of the original source of the applied
energy, i.e. whether by wind, water, an electric motor, a
battery, a human or animal-operated mechanism, etc., the actual
energy input for the invention for heat production is kinetic
and/or electrical in nature.

[0201] Likewise, regardless of the use of the energy produced,
be it the production of steam, the generation of electric power,
or the deliberate heating of an object or area, the actual
energy output of the invention is the heat generated within the
conductive member 40.

[0202] However, it is noted that in actual applications and
test conditions, it is often more convenient to measure the heat
output, rather than measure the heat production directly.
Likewise, it is often more convenient to measure the total
energy applied to the system, rather than measure kinetic and
electrical energy applied directly to the conductive member 40
and/or the magnets 30.

[0203] Such measurements may introduce small deviations into
test data. For example, ancillary devices such as fluid drivers
80 consume energy, and produce some quantity of heat. The energy
applied to such devices is not used directly by the ***magnetic
heater*** portion of the apparatus, i.e. it does not
act to vary the magnetic field experienced by the conductive
member 40. Consequently, it does not generate heat in the
conductive member 40. Neither the energy provided to such
devices nor the heat produced by them is properly considered
when calculating the efficiency of the invention.

[0204] However, in practice such deviations are of little or no
consequence. First, the energy input and heat output of fluid
drivers 80 and similar devices is generally very small compared
to that of the heater apparatus 10 as a whole. Thus, any effect
on the calculated efficiency is likewise small.

[0205] Second, because the efficiency of such known devices in
transforming electricity and other energy inputs into heat is
much less than 100%, this will result in test data showing
efficiency that is actually lower than the true efficiency.

[0206] For these reasons, it has been considered acceptable in
calculating efficiency as in the example above, wherein the
total energy applied is summed and compared to the total change
in heat energy of the fluid.

[0207] However, it is noted that, at least for theoretical
purposes, efficiency may be properly regarded and referred to as
the thermal energy produced in the conductive member 40 divided
by the kinetic and electrical energy applied to the conductive
member and/or the magnets in order to produce cyclical
variations in the magnetic field. In its most basic terms, the
heat production efficiency of the invention is its efficiency in
converting this applied kinetic and electrical energy to thermal
energy in the conductive member 40.

[0208] In a preferred embodiment, the heat production
efficiency is at least 100%.

[0209] In a more preferred embodiment, the heat production
efficiency is at least 150%.

[0210] In a still more preferred embodiment, the heat
production efficiency is at least 200%.

[0211] In a yet more preferred embodiment, the heat production
efficiency is at least 250%.

[0212] In an even more preferred embodiment, the heat
production efficiency is at least 300%.

[0213] In a most preferred embodiment, the heat production
efficiency is at least 350%.

[0214] Heat production efficiency is not necessarily limited to
about 350%; higher efficiencies may be equally suitable. In
addition, it may be suitable to produce heat with an efficiency
of less than 100% in certain embodiments.

[0215] It is noted that efficiency at levels such as those
described above, as measured during development of the
invention, are unprecedented in conventional devices. It is
acknowledged that levels of efficiency in excess of 100% would
seem to defy conventional understandings with regard to
thermodynamics. The reason for such high levels of efficiency,
and the physical basis underlying them, is not fully understood
at the time this application is filed. However, it is emphasized
that the above efficiency calculations are based upon practical
data, and are believed to accurately reflect the performance of
the claimed invention.

[0216] A wide variety of possible configurations, beyond those
illustrated and described in detail, are possible. Essentially
any arrangement wherein a conductive member 40 is moved
proximate at least one magnet 30 or vice versa may be suitable.

[0217] For example, for certain applications it may be
advantageous to form the conductive member 40 or the frame 20
(or even the magnets 30) into a shape that drives fluid within
or through the fluid path 50. For example, the conductive member
40 or the frame 20 may be configured to include vanes, blades,
etc. That is, the fluid driver 80 may be integral with the
conductive member 40 or the frame 20, depending on which is
moving. Such an arrangement is illustrated in FIG. 11.

[0218] Furthermore, the conductive member 40 may be of
essentially any shape and size. Although the precise quantity of
heat produced depends in part on the geometry of the apparatus,
significant amounts of heat may be produced by a device of
substantially any size. At one extreme, an apparatus in
accordance with the principles of the claimed invention may be
made to be of microscopic or submicroscopic size. Such a device
could be utilized for example in nanotechnology applications.

[0219] Conversely, an apparatus in accordance with the
principles of the claimed invention may be constructed so as to
be extraordinarily large, so as to be suitable for large-scale
commercial or industrial applications.

[0220] The fluid flow path 50 likewise may be of various
configurations. For example, one or more fluid flow paths 50 may
be disposed within the conductive member 40. In one possible
embodiment, a pipe might carry fluid into spaces within the
conductive member 40, wherein the fluid would absorb heat from
the conductive member 40.

[0221] Alternatively, fluid flow paths 50 could be connected to
the conductive member 40. For example, tubing or the like could
be secured to the conductive member 40, such that fluid flowing
therethrough absorbs heat from the conductive member 40.

[0222] In addition, the magnets 30 themselves may have a
variety of different forms. For example, a magnet 30 in the
shape of a cylindrical shell may be used, with a conductive
member 40 in the form of a hollow tube being rotated therein.

[0223] In addition, although the preceding discussion is
directed primarily towards the generation of heat, the claimed
invention may be utilized for cooling purposes as well. In such
an arrangement, a fluid with a suitable boiling point and heat
of vaporization, including but not limited to water or freon,
would be utilized.

[0224] Fluid in the vicinity of the conducting member 40 is
kept under pressure. Once the fluid absorbs heat from the
conductive member 40 such that its temperature exceeds its
boiling point at ambient pressure, it directed away from the
conductive member 40, whereupon the pressure is released, and
the fluid is allowed to expand from a liquid state into vapor.
The expansion draws heat energy equal to its heat of
vaporization from whatever may be in the vicinity of the
expansion. The object or area thus loses that quantity of heat,
and is cooled. This effect may be made to occur even when the
fluid responsible for the cooling effect is warmer than the
object or area that is being cooled. Thus, counter-intuitively,
a hot fluid may be used for cooling.

[0225] It is also noted that heat produced by the invention,
and fluids heated by the invention, may be put to a wide variety
of uses. Suitable applications include, but are not limited to,
as a convection furnace, as a space heater, as a cooking stove
or oven, for water purification or desalinization, clothes
drying, heating livestock trailers or quarters, as a hair dryer
or heat gun, for humidification by evaporation, as a water
heater, for air conditioning, as a swimming pool heater, for
smelting or processing of ores, metals, or alloys, for food
dehydration, for steam sterilization, as a Sterling engine heat
source, for heat sterilization, for steam generation, for
thermoelectric generation, and for the production of infrared,
visible, and ultraviolet light waves via incandescent heating.

[0226] Other applications include the roasting of grains,
peanuts, coffee, etc, use as a submersible heater for stock
ponds, fish farms, wildlife sanctuaries, water troughs for
livestock, etc, and the humidification, dehumidification, and
purification of air.

[0227] It is emphasized that although many of the uses
described herein are small-scale residential or commercial
applications, the claimed invention is not limited to small
scale applications only. The size of the device, and its heat
output, may be scaled up or down as materials and space permit
to fulfill a wide variety of roles. In particular, large scale
agricultural and commodities processing, and industrial heating,
cooling, refrigeration, and freezing may be suitable
applications for certain embodiments of the claimed invention.

[0228] In addition, it is noted that an apparatus in accordance
with the principles of the claimed invention may be made in a
very simple fashion, without complex mechanisms and with very
few moving parts.

[0229] As a result, embodiments may be constructed so as to be
extremely durable, both in actual use and in terms of "shelf
life".

[0230] Furthermore, because of the relatively simple
construction of the claimed invention, the limited number of
moving parts, and the lack of a need for a substantial
supporting infrastructure (i.e. fuel lines, waste gas venting,
etc.), embodiments of an apparatus in accordance with the
principles of the claimed invention may be suitable for
extremely harsh or demanding environments. For example, it may
be suitable for applications wherein high gee-forces and other
stresses are common, such as rockets and other high-energy
launch vehicles and devices, spacecraft, military vehicles, and
even certain types of munitions. Likewise, it may be suitable
for use in vacuum and zero-gravity or micro-gravity
environments, such as in spacecraft. As a further matter, it is
noted that certain embodiments may be adapted to utilize solar
wind to provide rotational energy, so as to generate the
cyclically varying magnetic fields.

[0231] Ultimately, the claimed invention may be useful for any
application wherein heat generation, the transfer of heat from
one location to another, or a product or process that may be
produced or operated with heat or heat transfer (such as steam,
electricity) is desired.

[0232] In order to more fully describe possible applications
for embodiments of the claimed invention, FIGS. 18 and 19 show
two exemplary devices.

[0233] The exemplary heater 11 shown in FIG. 18 includes a
heater mechanism similar to that shown in FIG. 15, comprising a
conductive member 40, frames 20 and 25 with magnets 30 and 35
thereon, the magnets being disposed at distances 12 and 14 from
the conductive member 40. A fluid driver 80 is arranged therein
to drive fluid through the fluid flow path 50. A support member
60 extends through the conductive member 40 and the frames 20
and 25, and is connected to a drive mechanism 70.

[0234] As previously noted with regard to other described
embodiments, many of the components noted above and illustrated
in FIG. 18 are exemplary only, and may be modified or omitted.

[0235] As illustrated, the above components are contained
within a housing 12. The housing 12 provides protection for the
components, and also protects persons and objects nearby from
coming into contact with the hot conductive member 40, and any
moving parts (such as, in certain embodiments, the magnets,
frames, or conductive member).

[0236] Housings are well known, and are not described further
herein.

[0237] In addition, as illustrated, the heater 11 may include a
temperature control mechanism 13. The temperature control
mechanism 13 provides a convenient way of controlling the heat
output of the heater 11. As shown, the temperature control
mechanism 13 is in communication with the drive mechanism 70.
With such an arrangement, the speed of motion of moving frames
20 and 25 or conductive member 40 could be controlled thereby.
However, this is exemplary only. It would also be possible, for
example, to control the heat output by controlling the distances
12 and 14, or by moving the magnets 30 and 35 and/or the
conductive member 40 into or out of proximity with one another.

[0238] Suitable temperature control mechanisms 13 include, but
are not limited to, thermostats and fixed-level output controls
(such as numbered dials or sliders). Temperature control
mechanisms 13 are well known, and are not described further
herein.

[0239] It is noted that, depending on the scale and the precise
configuration, the heater 11 shown in FIG. 18 might be suitable
for a variety of roles, ranging from a small hot air blower or
space heater, to a water heater or home furnace, to a large
industrial heating device.

[0240] Turning to FIG. 19, the exemplary heat driven apparatus
14 shown therein also includes a heater mechanism similar to
that shown in FIG. 15. As illustrated, it comprises a conductive
member 40, frames 20 and 25 with magnets 30 and 35 thereon, the
magnets being disposed at distances 12 and 14 from the
conductive member 40. A fluid driver 80 is arranged therein to
drive fluid through the fluid flow path 50. A support member 60
extends through the conductive member 40 and the frames 20 and
25, and is connected to a drive mechanism 70. Again, many of
these components are exemplary only, and may be modified or
omitted.

[0241] In addition to the heater mechanism, the heat driven
apparatus 14 also includes a heat operated mechanism 15. The
heat operated mechanism 15 is in communication with the heater
mechanism, so as to receive heat therefrom.

[0242] In FIG. 19, this is illustrated by the positioning of
the heat operated mechanism 15 on the far side of the conductive
member 40 from the fluid driver 80, such that the heat operated
mechanism 15 would receive heated fluid therefrom. However, this
is exemplary only. Other arrangements may be equally suitable,
including but not limited to direct contact between the
conductive member 40 and the heat operated mechanism 15, and
heat transfer via direct fluid loops, secondary fluid loops,
heat exchangers, radiation, etc.

[0243] The precise manner in which the heat operated mechanism
15 is in communication (i.e., the manner in which heat is
provided to the heat operated mechanism 15) may vary from
embodiment to embodiment, and in particular may vary depending
upon the nature and function of the particular heat operated
mechanism 15. So long as the heat operated mechanism 15 is in
communication with the heater mechanism, and thus so long as
heat is transferred to the heat operated mechanism 15, the
precise manner by which this occurs is incidental.

[0244] A wide variety of heat operated mechanisms 15 may be
suitable for use with the heat driven apparatus 14. Suitable
heat operated mechanisms 15 include, but are not limited to, a
furnace, a space heater, an electrical generator, a steam
generator, an air conditioner, and a cooking mechanism. Other
suitable heat operated mechanisms may include mechanisms for
performing any of the applications described elsewhere herein.

[0245] Because the heat operated mechanism 15 may vary
considerably, it is illustrated in FIG. 19 in schematic form
only, as a "black box" device. However, in practice, the heat
operated mechanism 15 may have structure, may have various
outputs, and may utilize or require inputs in addition to the
heat from the heater mechanism. The schematic form used to show
the heat operated mechanism 15 should not be interpreted as
excluding such structure, inputs, and outputs.

[0246] In particular, it is noted that although the apparatus
14 is referred to as being heat driven, this should not be
interpreted as implying that other inputs or power sources are
necessarily excluded. For example, in embodiments where they are
present the drive mechanism 70 or fluid driver 80 may draw
electrical power, or may be operated by the force of fluid flow,
the turning action of a windmill, etc. The term "heat driven
apparatus" as used herein refers to the fact that a source of
heat is utilized by the apparatus 14 in performing its intended
function, not that heat is the sole requirement or input for
performing that function.

[0247] The above specification, examples and data provide a
complete description of the manufacture and use of the
composition of the invention. Since many embodiments of the
invention can be made without departing from the spirit and
scope of the invention, the invention resides in the claims
hereinafter appended.

---

**USP # 5,742,111**

**( 4-21-1998 )**

**DC Electric Motor**

**Troy G. REED**

Applicant: SURGE POWER CORP (US)   
Classification: - international: H01R39/04; H01R39/32;
H02K13/10; H01R43/06; H01R39/00; H02K13/10; H01R43/06; (IPC1-7):
H02K13/00;- european: H01R39/04; H01R39/32; H02K13/10   
Application number: US19960588342 19960118   
Priority number(s): US19960588342 19960118

**Abstract** --- The commutator segments for a d.c. electric
motor includes one or plurality of slots which improves
horsepower at less amperage.

Abstract  
  
The commutator segments for a d.c. electric motor includes one
or plurality of slots which improves horsepower at less
amperage.  
   
Current U.S. Class:     310/236 ; 310/227;
310/233  
Current International Class:     H01R 39/04
(20060101); H02K 13/10 (20060101); H01R 39/00 (20060101); H01R
39/32 (20060101); H01R 43/06 (20060101); H02K 013/00 ()  
   
Other References  
  
"The Slotting of Commutators of Electric Motors," Scientific
American, Col. 1, Vth Article. Oct. 23, 1915..  
  
FIELD OF THE INVENTION  
  
This invention is directed to an improved direct current (d.c.)
motor. In particular, it is directed to an improved commutator
system for a d.c. motor.  
  
BACKGROUND OF THE INVENTION  
  
A typical d.c. motor comprises a cylindrical stator, a rotor
journaled on a shaft for rotation within the stator with a
uniform gap between the rotor and stator as the rotor rotates.
Armature windings are inserted in slots in a cylindrical surface
on one of the stator and rotor and being divided into similar
coils mutually spaced around the shaft axis. Magnetic field
generating means are located on the other of said stator and
rotor for forming poles mutually spaced around the shaft axis.
D.C. motors require commutation, i.e., the process of reversing
the current in each armature coil. This is carried out when the
commutator segments to which the coil is connected are
short-circuited by a brush connected to the d.c. supply voltage.
The commutator is made up of a plurality of insulated, separate
segments formed in a cylindrical surface with each surface
electrically connected to an armature coil. The stator may
comprise a ring of permanent or d.c.-field magnets which are
attached to the inside of a housing or frame surrounding the
rotor.  
  
Structurally, a typical commutator consists of a plurality of
wedge-shaped copper bars that are built up to form a complete
circular cylindrical contact surface with each segment separated
and electrically insulated from one another by thin strips of
mica. Means are provided to permit attachment of the ends of
each rotor coil winding to separate spaced commutator bars.
Stationary brushes of carbon blocks or copper gauze, which are
electrically connected to a d.c. source, ride upon the
commutator contact surface which make contact with the
commutator segments. The d.c. current which is supplied to the
brushes flows in the appropriate direction to the rotor coils
only when they are opposite the appropriate field pole (North or
South). The appropriate direction means that for all coils, the
force produced will be in the same direction at all speeds and
loads for the ring of segments and the brushes provide automatic
switching to insure that this is so. A d.c. commutator motor has
advantages over induction and synchronous motors in the ability
to provide efficient speed variation over a wide range without a
variable supply frequency. D.C. motors are typically classified
as "shunt", "series", "compound" (sometimes classed as a varying
speed motor), or "compensated compound" motors depending upon
the application. Motors used in golf carts are inclusive of this
invention. D.C. motors are particularly favored where high speed
or variable speed electric drive is required.  
  
SUMMARY OF THE INVENTION  
  
It is an object of this invention to provide an improved
commutator for a d.c. electric motor which will provide improved
horse power and torque for a given volt/amperage input as
compared to a conventional d.c. motor.  
  
In accordance with this invention, there is provided a d.c.
motor comprising a cylindrical stator that includes permanent or
d.c. fed coil type magnets. A rotor is journalled on a shaft for
rotation within the stator with a uniform gap between the rotor
and the stator as the rotor rotates. There are insulated
armature windings, or coils, which are inserted in slots in a
cylindrical surface on the rotor being divided into similar
coils mutually spaced around the shaft axis. Magnetic field
generating means are located on the other of the stator and the
rotor for forming magnetic poles mutually spaced around the
shaft axis. A switching means occurs utilizing commutator
segments which are adapted to connect the armature coils to a
d.c. source in timed synchronism with a rotation of the rotor.
The d.c. electric source flows through brushes which may be
carbon blocks or copper gauze. The switching means connects the
armature coils to the d.c. source and in timed synchronism with
the rotation of the rotor such that switching of the d.c. to
each armature coil occurs when a magnetic pole generated by that
coil is substantially in alignment with a rotor (or stator) pole
of opposite polarity and thereby drawing it toward each other to
create the rotary motion. In other aspects like polarity is
created to exert a repelling force on the rotor poles to
maintain the rotation. Instead of the field generating means,
the stator may comprise a permanent magnet which can include the
motor casing that supports the stator.  
  
A primary object of this invention is to provide a d.c. motor
with an improved commutator, wherein the brush contact surface
of each commutators segment includes at least one gap or slot
that is angular to, or transverse to, the direction of rotation
of the commutator.  
  
These and other objects of the invention will become more
apparent upon further reading of the specification, claims and
drawings herewith.  
  
BRIEF DESCRIPTION OF THE
DRAWINGS  
  
FIG. 1 is a perspective
view of the commutator formed as a part of this invention.

![](us1.jpg)

FIG. 2 is a partial
sectional view across the commutator of this invention.

![](us2.jpg)

FIG. 3 is a perspective
view of an individual commutator segment forming this invention.

FIG. 4 is a simple
schematic of a variety of forms of d.c. electric motors.

![](us3.jpg)![](us4.jpg)

FIG. 5 and 6 are wiring
diagrams of the test motor described herein.

![](us5.jpg)

FIG. 7 is a partial
sectional view across a commutators segment of another
embodiment of this invention.

FIG. 8 is a top
elevational view of an alternate form of an individual
commutator segment of this invention.  
  
DETAILED DESCRIPTION OF THE
PREFERRED EMBODIMENT  
  
While the invention has been described with a certain degree of
particularity, it is manifest that many changes may be made in
the details of construction and the arrangement of components
without departing from the spirit and scope of this disclosure.
It is understood that the invention is not limited to the
embodiment set forth herein for purposes of exemplification, but
is to be limited only by the scope of the attached claim or
claims, including the full range of equivalency to which each
element thereof is entitled.  
  
Referring now to FIG. 1, 2, and 3, the commutator of this
invention is generally designated by the numeral 10 and is
comprised of a plurality of individual insulated segments 12,.
The commutator is attached to the rotor shaft 14 and includes a
hub 16 to which the segments 12 are insulatively attached. Each
segment includes a means such as a slot or other form of
electrical wiring connection 18 which connects with the
appropriate portions of the armature coils which are formed
within the rotor. A plurality of brushes 20 and 22 are used to
make rubbing electrical contact with contact surface 24 of each
segment. The brushes are appropriately connected to a d.c.
source, i.e., a battery or the like, as is well known to those
skilled in the art. The number and size of segments 12 and
number of brushes 20 and 22 may vary and depend upon the
performance characteristics of each d.c. motor design. Each
commutator segment 12 is insulatively separated at 13 usually
with mica.  
  
The invention herein comprises at least one or a plurality of
air gaps or slots 30, as best shown in FIGS. 2 and 3, in the
brush contact surface 24 of each segment 12. The air gaps or
slots are cut into the cylindrical contact surface 24 preferably
radially and transverse to the direction of rotation of the
commutator. The gaps are typically slots of width ranging in
width between 0.010" (0.25 mm) and 0.032" (0.81 mm). This range
is not limiting, as the size of the slots will vary as to the
width of the contact surface of the commutator and the number of
slots therein. The slots could be angularly directed relative to
the direction of rotation of the commutator, as shown in FIG. 8.
As shown in FIG. 7 each segment 25 includes slots 27 of partial
depth or, as shown in FIGS. 2 and 3, the full depth of the
contact surface of the commutator segment and may be open or
filled with an inert material, e.g., mica or other electrically
insulative material.  
  
FIG. 4 is submitted to show schematically the various exemplary
forms of d.c. motors to which this invention is applicable.  
  
Although the slots are shown as radial and transverse to the
direction of rotation of the rotor and rotor shaft, the
invention includes slots which are angularly directed to the
direction of rotation.  
  
FIG. 4 represents wiring schematics of various forms of d.c.
motors to which this invention is applicable, although not
limited thereto.  
  
FIGS. 5 and 6 represent the stator(s) and armature wiring
schematics for the test motor described heretofore.  
  
FIG. 8 depicts commutator segment 24 with angular slots 31.  
  
PERFORMANCE CHARACTERISTICS  
  
A test was conducted comparing a standard series wound 8
horsepower at 3400 rpm, d.c. motor, type 7544D, sold under the
name VERSATILE as manufactured by the Baldor Electric Company of
St. Louis, Mo. with the same motor having a commutator modified
in accordance with this invention. The motor used d.c. enhanced
magnet wire coils, four(4) in the stator and two (2) in the
armature. The standard motor commutator had 72 segments with
effectively 4 brushes. The test results were as follows:  
  
\_\_\_\_\_\_\_ STANDARD MOTOR TORQUE TORQUE HORSE- a % RPM LB-FT N/m
AMPS VOLTS POWER Eff. \_\_\_\_\_\_ .sup. 3004.sup.1 14.20 80 4770 3.00
4.07 24.80 160 2.726 51 4172 6.00 8.13 32.40 160 4.769 69 3797
9.25 12.54 40.90 160 6.690 76 .sup. 3604.sup.2 12.25 16.61 48.90
160 8.409 80 3400 15.50 21.02 57.10 160 10.127 83 3313 10.50
14.24 65.40 160 11.674 83 3652 11.501 15.59 46.90 160 8.000 80
3598 12.353 16.75 49.16 160 8.466 80
\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_ .sup.1 No load. .sup.2
Full load. Note: Newtonmeter (N/m) calculated: 1.355818 .times.
lbft-force.  
  
Efficiency calculated: ##EQU1## Where: P=Horsepower  
  
E=Volts  
  
I=Amps  
  
In the modified commutator, according to this invention, the
contact surface of each segment was modified to include one air
gap or slot 0.023" (0.58 mm) in width therein. The modified
commutators included two tests, one where the armature windings
were soldered to the commutator segment and another where they
were brazed. Tests on the soldered were made where the motor was
run both clockwise and counterclockwise. The comparative results
were as follows:  
  
\_\_\_\_ SOLDER (CLOCKWISE) TORQUE TORQUE HORSE- RPM in-lb N/m AMPS
VOLTS POWER n % \_\_\_\_\_\_ 1697 158 17.85 50.7 80 4.26 78 1895 173
19.54 53.4 90 5.20 80 2055 188 21.23 57.2 100 5.13 67 2256 203
22.93 60.6 110 7.27 81 2445 215 24.28 63.7 120 9.34 91 2631 236
26.66 68.2 132 9.86 81 2791 248 28.01 70.5 140 10.99 83 2970 257
29.03 73.0 149 12.12 83 \_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_
Note: Newtonmeter (N/m) calculated: 1.129848 .times. inlb-Force
.times. 10.sup.-1.  
  
\_\_\_\_\_\_\_ SOLDER (COUNTERCLOCKWISE) TORQUE TORQUE HORSE- RPM in-lb
N/m AMPS VOLTS POWER n % \_\_\_\_\_\_\_\_ 1703 158 17.85 47.5 80 4.27 83
1957 173 19.54 50.6 90 5.37 87 2344 188 21.23 54.2 100 6.99 96
2314 203 22.93 58.0 110 7.46 87 2513 215 24.28 60.9 120 8.58 87
2717 236 26.66 65.4 132 10.18 87 2858 248 28.01 68.0 140 11.25
88 3229 257 29.03 70.0 149 13.17 94
\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_  
  
\_\_\_\_\_\_\_\_ BRAZED (COUNTERCLOCKWISE) TORQUE TORQUE HORSE- RPM
in-lb N/m AMPS VOLTS POWER n % \_\_\_\_\_\_\_\_\_\_ 1742 158 17.85 47.5 80
4.37 85 1920 173 19.54 50.6 90 5.27 86 2127 188 21.23 54.5 100
6.35 87 2308 203 22.93 57.7 110 7.44 87 2495 215 24.28 60.9 120
8.51 87 2690 236 26.66 65.4 132 10.08 87 2852 248 28.01 67.6 140
11.23 88 3012 257 29.03 70 149 12.29 89
\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_\_  
  
Based on these tests, it would appear that a modified
commutator, according to this invention, provides increased
efficiency, greater torque and horsepower at lower rpm.

---



**WO # 9010337**

**MAGNETIC MOTOR**

**Troy REED**

Classification: - international: H02K7/02; H02K7/06; H02K53/00;
H02K7/00; H02K7/06; H02K53/00; (IPC1-7): H02K1/00; H02K7/02;
H02K21/22;- european: H02K53/00   
Also published as: EP0461179 (A1) // EP0461179 (A4) // EP0461179
(A0)   
Cited documents: US3497706 // US1893840 // US4745312 //
US4703212 //  US4916343

**Abstract** --- A magnetic motor is driven by the repelling
forces of fixed and rotating magnets. The rotating magnets (22,
32) are mounted equally spaced about the perimeter of a disk
(20) which rotates as the flywheel of the motor. Stationary
magnets (18, 28) are supported adjacent the rotating magnets
(22, 32). There are four injector pins (76A, 76B, 76C, 76D),
much like the common injector pins on ball point pens, which are
set and released by an injector pad (48A, 48B, 48C, 48D) driven
by the crankshaft (14) of the engine. The crankshaft (14) and
flywheel are driven by the repulsive forces created by the fixed
and rotary magnets (22, 32) with the injector pin system (34,
36, 38, 40) operating to kick the crankshaft (14) and the
flywheel over center.

This invention relates to a magnetic motor for converting
magnetic force into rotary motion. Reciprocating devices are
well known in which a piston is slidably disposed within a
similar chamber. A driving force is periodically generated in
the cylinder chamber to drive the piston to reciprocating
motion. Electromagnetic force has been utilized to provide the
driving force in reciprocating engines or devices. In some such
devices, a plurality of electrical coils surroundingthe engine
cylinder chambers are provided. Electrical coils are actuated by
electrical current so that electromangetic forces developed in
the chamber could drive the piston to reciprocating motion.
Normally, electromagnetic reciprocating devices are very complex
in structure and very elaborate control means must be
incorporated in the structure to operate the device in a
controlled and useful manner. Furthermore, in most prior
magnetic motors a constant supply of electrical current must be
fed to the coils in order to develop a useful reciprocating
motion.In US Patent 3,811,058 to Kiniski the patentee states
that he has discovered that the magnetic energy stored in
permanent magnetic material such as permanent magnets may be
utilized to provide the driving force necessary for
reciprocating device.  
  
Summary of the Invention  
  
This is a magnetic motor having a crankshaft mounted between two
disk-like stationary magnetic holders. Preferably eight
permanent magnets are positioned equally distanced about the
periphery of each disk. Fixed on the end of each shaft is a
rotatable magnetic support wheel which has a similar number of
magnets equally spaced about its periphery. The magnets on one
such wheel are 22-1/2 degrees out of alignment   
 with the magnets on the other rotating wheel. Injector
pins are mounted on a case above the crankshaft. Each such
injector system has an injection drive pin which has
intermittent contact with an injector pad drivrn up and down in
the injector pin housing by rotation of the crankshaft. The pin
injecting drive system includes the mechanism similar to that
which is used to push out and retract the ball tip out of ink
writing pens. The magnets on each magnetic holder are 45 degrees
apart and the magnet on one fixed disk or stationary disk is in
alignment with the permanent magnets of the permanet disk on the
other end of the crankshaft. When the magnetic support wheelmis
rotated from the stop position the magnets will either attract
or push and in the preferred embodiment they will push or be
repulsive, that is the magnets on the permanent disk will have
the same polarity as the polarity of the rotating magnets which
come in close proximity to each other. Injectors are used to
kick the crankshaft and the flywheel or the rotating magnetic
support wheelsmover center so that the next propulsion force is
created by the fixed rotary magnets will continue the rotational
movement.   
  
Brief Description of the
Drawings  
  
FIGURE 1 illustrates a
full face side view partly cut away of my magnetic motor.

![](wo1.jpg)

FIGURE 2 is a right side
elevation taken along the line 2-2 of Figure 1.

![](wo2.jpg)

FIGURE 3 is a left side
elevational view taken along line 3-3 of Figure 1.

![](wo90c.jpg)

FIGURE 4 is a view taken
along line 4-4 of Figure 1.

![](wo90d.jpg)

FIGURE 5 is a view taken
along the line 5-5 of Figure 2.

FIGURE 6 is a view
mostly in section of the injector pin system of my magnetic
motor.

![](wo90e.jpg)

FIGURE 7 is a view taken
along the line of the line 7-7 of Figure 6.

FIGURE 8 is a full-face
view of the injector pin of the injector pin system of Figure 6.

FIGURE 9 is a full face
view of the toothed spring holder head whose shaft is insertable
into the injector sleeve head shown in FIgure 8.  
  
FIGURE 10 is a view
taken along the line 10-10 of Figure 9.  
  
FIGURE 11 is a view with
the toothed head in a position just prior to falling to the
cocked postion of FIGURE 13.

![](wo90f.jpg)

FIGURE 12 is an internal
view of the interior of the injector wall unrolled.  
  
FIGURE 13 is a view
partly in section of the injector pin in the cocked position.  
  
FIGURE 14 is a view
taken along the line 14-14 of Figure 13.

FIGURE 15 represents
the four injector pins in the relative position with the pin one
the left being in top dead center.

![](wo90g.jpg)

FIGURE 16 is similar to
Figure 15 except that the second pin from the left is in the top
dead center position.  
  
FIGURE 17 is similar to
FIGURE 16 except that the third injector from the left is in the
top dead center position.

![](wo90g.jpg)

FIGURE 18 is similar to
Figure 17 except that the fourth injector pin is in the top dead
center position.  
  
FIGURE 19A and 19B show,
respectively, the left hand and right hand magnet orientation on
the rotating and non-rotating magnets when the injector is in
the top dead position as shown in Figure 15.

![](wo90h.jpg)

FIGURES 20A and 20B are
similar to Figures 19A and 19B respectively and show,
respectively, the left and right hand magnet orientation when
the second pin injector is in the top dead position as shown in
FIgure 16.  
  
FIGURES 21A and 21B
show, respectively, the left hand and right hand magnet
orientation when the first pin injector is in the top dead
position as shown in Figure 17.  
  
FIGURES 22A and 22B
show, respectively, the left hand and right hand magnet
orientation when the second pin injector is in the top dead
position as shown in Figure 18.  
  
Detailed Description of the
Invention  
  
Attention is first directed to Figures 1, 2 and 3. In Figure 1
there is shown a case block 10 with cavity 12 in which is
mounted a crankshaft 14 supported from block 10 by bearings or
bushings 15. On the right side is a stationary base magnet
holder 16 on which is permanently fixed magnets 18. As can
clearly be seen in Figure 2 there are 8 such permanent magnets
18. A magnet support wheel 20 is fixed to adn supported by and
rotated with crankshaft 14. The magnetic support wheel 20
support eight rotating magnets 22 equally spaced. Gear 24 is
secured to crankshaft 14 to serve as a power takeoff means.  
  
On the left hand side of the device in Figure 1 is a stationary
base magnet holder 26 having eight stationary magnets 28 whihc
are aligned with magnets 18. There is also a rotating magnetic
field support wheel 30 having eight equally spaced rotating
magnets 32 fixed thereto. The rotatin  magnets on one wheel
are 22-1/2 degrees out of alignment with those on the other
rotating wheel.  
  
As shown in Figure 1 there are four pin injector assemblies 34,
36, 38 and 40 which are mounted on top of case 10. As shown in
the cutaway view of pin injector system 40 there is injector
driver pin 42 which in the position shown for injector pin
system 40 extends down belowhousing 44 into enlarged housing 46.
Spaced within housing 46 is an injector pad 48 which is slidably
mounted in that housing. The injector pad is connected by a
connecting rod 50 to knuckle joint 52 which has a second
connecting arm 54 whihc is pivotally connected to a parallel
crank arms 56 and 60 which are connected to the shaft 14. A
pivot pin 58 connects the connecting rod 54 to the crank arms 56
adn 60. The other three pin injector assemblies 34, 36 and 38
are similarly connected to the crankshaft 14, however, they are
so positioned on the shaft that only one is in its top dead
position at a time. They reach their top dead position 90
degrees apart for each rotation of the crankshaft 14.  
  
Attention is now directed especially to Figures 2 and 3. 
It can be seen that they are similar but have a different
orientation. Each side has magnet support wheel with eight
magnets thereon which rotates with the wheel and eight magnets
mounted on the stationary magnet holder. These magnets are all
equally radially spaced and any two adjacent magnets are 45
degrees apart. It can be seen from Figures 2 and 3 that the
orientation of the magnets 28 in the permanent or stationary
magnetic holder 26 are oriented or aligned directly withe the
magnets 18 of the stationary based magnetic holder 16. However,
the rotating magnets 32 on rotating disk or wheel 30 are not
oriented with the rotating magnets 22 of the rotating wheel 20.
Rather, they are the orientation of rotatins shafts 22 with
resepct to the axis of shaft 14. In other words, when a rotating
magnet 32 is directly nder magnet 28 and lin injector assembly
34 as shown in Figure 3, then the rotating magnets 22 one each
be halfway between tow permanent magnets 18 in Figure 2. it is
noted that the interior edge of magnets 18 and 28 are curved.
This is to provide clearance for the inner rotating magnets. The
injector pin system 40 is very similar in construction and
operation to the pin on millions of ball point pens in which one
push on the pin on top of the ballpoint pen will psh the writing
ball out and a second push on it will cause the ballppoinbt to
retract. Figures 6 through 14 illustrate the main componetns of
such an injector pin.  
  
Attention is next directed to Figure 6 which shows an injector
housing 62 screwed into a cylinder head 64. Housing 62 is hollow
with an internal passage 66 having the shoulder 68 toward the
lower end. The upper end of the housing is enclosed by cap 70.
The reduced diameter passage portion 72 of passage 66 has a
lowered tapered shoulder 74. Shown in Figure 8 is the injector
pin 76. The part 76 shown in Figure 8 corresponds to the push
pin or rod on top of the aforementioned ballpoint pen. The
injector pin 78 has an injector head 78 which has a passage 80
therein. A tooth spring holder head 82 shown in Figure 9 fits
into the space 80 as shown in Figure 6. The upper end of
injector head 78 has locking teeth 83 which can mesh with
locking teeth 84 of tooth spring holder head 82. The top of
tooth spring holder head 82 has a spring recieing shoulder 86
for holding spring 88 as shown in Figure 6. Spring holding head
90 has four major interlocking gears 92 and four minor
interlocking gears 94 equally spaced between the interlock gears
92 which have a smaller diameter than the lock gears 92 as
clearly shown in Figure 7.  
  
The interior wall of housing 62 has a series of locking pads 96
with smaller shoulder 98 as clearly shown in Figure 7 and 12
with channel 100 therebetween. Figure 10 is a view on the line
10-10 of Figure 9 and shows the interlock gears 19 which are
spaced at 90 degrees and the interlock teeth 104 which are
between the interlock gear 92. Figure 12 is helpful in
understanding the internal view of the interior of the injector
wall unrolled showing the pattern of the locking pads 96 and
locking shoulder 98. Attention is briefly directed back to
Figure 4 which shows the injector pin 76 mounted above injector
pad 108. It will be understood that as crankshaft 14 rotates
that injector pad 108 moves up and down within housing 52. In
FIgure 11 the injector pad 108 has been oved upwardly by the
rotation of the crankshaft where it contacts the injector pin 76
which causes it to move upwardly and in the position shown in
Figure 11 the injector sleeve head 82 is free to rotate due to
the action between teh sloped teeth 84 of head 82 and by the
upwardly facing sloped teeth 83 of the sleeve injector head 78
and causes the holder head 82 to rotate by continued upward
force until it reaches the position shown in Figure 13 which
injector pin is in its cocked position. At the next contact of
the pin 76 by pad 108 the holder head 82 will rotate and be free
to fall with the force of the spring 82 driving it downwardly.
this downward force is transmitted to the pad 108 which force is
tehn transmitted to the form of rotational force to the
crankshaft causing it to be driven in a rotating position. Thus,
one rotating position of the crankshaft will cause the pad 108
to drived the injector pin 76 upwardly till it is cocked and the
next rotation of thecrankshaft will cause the upeard movement of
the pin 76 (which fell to its lower position) and the upward
movement will cause the holder head 82 to rotate to an unlocked
posoiton whereby the spring 88 will drive it and the pin 76
upwardly.  
  
Attention is next directed toward the operation of this magnetic
motor. Attention is first directed to Figures 19A and 19B. It
will be noted that Figures 19A, 20A, 21A and 22A represent the
left hand magnet orientation of those orientations shown in
Figure 3 whereas Figures 20B, 21B and 22B are right hand magnet
orientations or the orientations of those magnets as shown in
Figure 2. When in this position as shown in Figure 19A, magnets
28 and 32 are nearly aligned but there is a magnetic force in
the direction of the solid line arrow. The dashed arrows show
the direction of rotation of the rotating wheel. Figure 19B as
indicated the north pole of the magnet 28 is adjacent the north
pole of magnet 32 so that there is a repulsive action. This is
true pof all the other pairs of magnets of both the left hand
magnet orientation and the right hand magnets. In Figure 19B the
rotating magnet 22 is being rapidly propelled from a position
adjacent magnet 18 by the force  represented by the solid
line arrow and in the direction indicated. Attention is now
directed to Figure 15 to visualize the position of the
crankshaft and the injector pads 48. In injector pin assembly 44
the pad 48A has pushed the injector drive pin 76A upwardly into
the housing 34 much like indicated in Figure 11. One revolution
of the crankshaft cocks the injector pin assmebly, and in the
next revolution crankshaft 14 injector pad fires the injector
pin. The position of the crankshaft adn injector pad 48B, 48C
and 48 are also indicated. Continued rotation of the crankshaft
will cause the injector pin assemblies to take the position
shown in Figure 16 whereas the injector pin assembly 36 is in
its top dead center position. The rotation of the rotating wheel
20 adn 30 are indicated by the broken line arrows. When the
injector pin assembly is in the kick mode, it operates to kick
the crankshaft and the flywheel over center once the rotational
motion has been instigated. As can be seen the pin and spring
which when the crank arm strikes the injector pin will force the
crank arm and rotaing magnetic wheel over center. The output for
the motor is then drected through gear 24 for appropriate power
takeoff connections. Once it is kicked off center the propulsion
force causes the wheel to rotate.  
  
Figures 20A and 20B show the position of the magnets when pin
injector assembly 36 is at its top dead center as indicated in
Figure 16. Figures 21A and 21B show the position when pin
injector assembly 3 is at top dead position as indicated in
Figure 17. Figure 18 shows the pin injector assembly 40 at its
top dead center position when the magnets are in the position
shown in Figures 22A and 22B.  
  
This motor is designed to obtain power by push and pull motion
of the magnets. The magnets shown have a tendency to push
inasmuch as they are like poles coming into proximity with each
other. The magnets can be reversed s that the magnets will have
a tendency to attract each other. The engine as described has
four cylinders with 32 magnets, 16 magnets to each end. On each
end there are 8 rotating magnets and 8 stationary magnets. This
magnetic motor has injectors that push on the crankshaft to
drive the motor over the point of magnetic pull. The particular
motor which I have built is a small engine made out of aluminum,
brass and stainless steel with no steel parts.   
  
There is no limit to the size of the motor which I can build
with the dimensions to the magnetic motor depending upon what
size magnets that you use. The magnets can be molded into a
plastic with a shaped top across the magnet and the crankshaft
can be made out of ceramics. The body could also be made of
plastic.  
  
While the invention has been described with a certain degree of
particularity, it is manifest that many changes may be made in
the details of construction and the arrangement of components
without departing from the spirit and scope of this disclosure.
it is understood that the invention os not limited to the
embodiments set forth herein for pusposes of exemplification,
but is to be limited only by the scope of the attached claims,
including the full range of equivalency to which each element
thereof is entitled.

  


---