Henry Wallace: Kinemassic Force Field

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**Henry WALLACE**

**Kinemassic
Force Field**

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Counter-rotating masses of half-integral spin nuclei
material (i.e., copper, zinc, lead, tin, nickel, vanadium,
arsenic, gallium, &c) generate a "kinemassic force
field" that can be used to work against ambient gravity.
Wallace received 3 patents for his discovery.

**[*New Scientist* ( 14 February 1980 ) :
"Anti-Gravity Not So Crazy After All"](#nsci)**   
 **[Henry W. Wallace : "Concerning Mass Dynamic
Interactions" ( 31 January 1983 )](#wallace)**   
 **[US Patent # 3,626,605 : Method &
Apparatus for Generating a Secondary Gravitational Force
Field](#3626605)**   
 **[US Patent # 3,626,606 : Method &
Apparatus for Generating a Dynamic Force Field](#3626606)**
  
 **[US Patent # 3,823,570 : Heat Pump](#3823570)**

**[R. Stirniman
: The Wallace Inventions](wallaceinventions.pdf) ( PDF )**

---

  
***New Scientist* (14 February 1980)**


**"Antigravity Not So Crazy After All"**

It is now nearly 10 years since Henry Wallace was granted a
pair of US Patents (# 3,636,605 and 606) on what was initially
written off as a crazy science fiction notion --- a machine to
generate an anti-gravity field. But in the interim, Professor
Eric Laithwaite of Imperial College, London, has achieved both
fame and notoriety by arriving independently at a similar
theory.

According to Wallaces patents, bodies made of carefully chosen
materials generate an energy field when placed in rapid relative
motion. This field is not electromagnetic and was christened by
the inventor as a Kinemassic Forcefield. If this kinemassic
field is made to undulate, a secondary gravitational field is
produced which can neutralize gravity.

In one kinemassic machine a pair of wheels of brass alloy, like
gyroscopes, are mounted in close-fitting air gaps between
massive structural supports formed from steel. The wheels are
driven to a high speed of rotation by jets of compressed air or
nitrogen. The inventor claims that, at speeds of about 20,000
rpm, polarization of the spin nuclei of the alloyed metal
occurs. If one wheel is balanced on a knife edge, it will start
to oscillate under the influence of the other. If the spinning
wheels are rotated abut another axis, a secondary gravitational
field is created which reduces the wheels weight. If a
sufficiently strong field is created, it can generate localized
areas of gravitational shielding and thus provide an effective
propulsion force.

Although the Wallace patents were initially ignored as cranky,
observers believe that his invention is now under serious but
secret investigation by the military authorities in the USA. The
military may now regret that the patents have already been
granted and so are available for anyone to read.

---

  
  
**Henry W. Wallace:**

**"Concerning Mass Dynamic Interactions"**

**(31 January 1983)**

Based on the assumption of your interest, following are
descriptive explanations of two of the many facets of the
kinemassic field force (KF) energy: one micro, the second, macro
in form. Acquainting you with just the first (micro) of these
facets, I believe, will establish the reality of the KF to you
although other facets --- in addition to these two ---
convincingly exist not the least of which are the quantitative
test data associated with, for example, the KF permeability
experiments.

Einstein believed that a force field could be generated from
the mass dynamic interaction of bodies in relative motion.
Quoting from the *Encyclopedia Britannica* (15th Ed.,
Macropedia, Vol. 8, p. 289): "Field theories of gravity,
Einsteins general relativity being an important example, also
predict specific corrections to the Newtonian force law, the
corrections being of two basic forms: (1) When matter is in
motion, additional gravitational fields (analogous to the
magnetic fields produced by moving electric charges) are
produced; also, moving bodies interact with gravitational fields
in a motion-dependent way...". Sometime after Einsteins death,
this predicted field --- a mathematical expression --- was
posthumously termed "protational". Einstein was said to have
been distressed that, experimentally, this predicted force field
energy apparently could never be realized --- and therefore
verified --- since calculations indicated that the maximum mass
densities of available hardware, needed for "matter in motion"
(mass dynamic interactions), would hypothetically generate field
forces so infinitesimal as to be many orders of magnitude below
measurable levels. Platinum (Pt) --- with a density of p = 21.45
gm/cm3 --- was thought to be the most viable hardware
candidate.

The KF reasoning is quite clearly believed to have stolen a
march upon the existing field theories of gravity; a march of
utmost importance regarding concepts of experimental hardware.
This preceding statement especially applies to the maximal
attainable density needed for the measurable interaction of
"matter in motion"; the neutron possesses, for example, a
density of close to 3.5 x 10^14 gm/cm^3.

Quoting again from the *Ency. Brit.* (Special Suppl. 1976
Brit. Book of the Year, p. 62) as regards awarding of the 1975
Nobel Prizes, L. James Rainwater, one of three Nobel laureates
for Physics that year, wrote a paper associated therewith of
which the following excerpt applies: "...observed that the
greater potion of nuclear particles form an inner nucleus while
other particles, which are all in constant motion at tremendous
velocities, affect the other set of particles...". For reasoning
which is not included here but which is set forth in US Patents
# 3,626, 605 and # 3,626,606, the KF moment of the odd-A
nuclides unpaired nuclear particle (either proton or neutron)
possesses its salient KF force energy moment --- the same energy
interaction ongoing between the nuclear, shell-configured
particles just quoted from L. J. Rainwater --- available for
experimental measurement by means of, for example, the various
apparatus described in these two basic patents.

Consider the magnitudes of density enhancement between the
nucleon (N) --- e.g., neutron (n) --- and platinum (Pt):

3.5 x 1014 / 2.145 x 101 = 1.6 x 1013

In order to more emphatically portray this thirteen orders of
magnitude increase in density, one may compare 30 million years
with one minute of time. The unpaired N, collectively, of the
odd-A nuclide is the viable hardware available for
experimentally measuring the interaction of... matter in
motion... as regards the KF force energy.

Although it is an extreme example, a 100-pound bar of beryllium
(Be) possesses 11.1 pounds of unpaired nuclear particles
interacting, in part, with an additional 11.1 pounds of paired
nuclear particles --- via mass imagery. Consequently, 22.2
pounds of spinning, orbiting, vibrating particles --- "all in
constant (relative) motions at tremendous velocities..." and
with particles densities in the order of 3.5 x 1014
gm/cm3 --- are available in laboratory apparatus
where 100 pounds of Be are utilized. It is noted that Be should
preferably be utilized within the apparatus of USP # 3,636,605
since Bes nuclear relaxation time --- from its polarized state
--- may be of several days duration; Be may well have valuable
future application comparable to certain metallic elements, and
their alloys, utilized for permanent magnet structures within
the realm of electromagnetism.

Because these unpaired nucleons, of the odd-A nuclides, possess
external angular momenta (the respective momenta of paired
nucleons internally cancel), it has experimentally been
determined that the imposing of an applied axis of rotation to
odd-A nuclide matter causes spin polarization such as occurs
with the Barnett Effect concerning the spins of unpaired
electrons within ferromagnetic matter. The means, therefore, are
at hand for generating a KF force as the Barnett Effect
apparatus has been available for generating a magnetomotive
force (mmf).

The KF force moment, by itself, has not yet proven sufficiently
energetic, however, to be capable of generating, en masse, a
measurable KF field by this imposed axis of rotation technique.
Unlike the concept and apparatus, utilized in the Barnett
Effect, the field enhancement method of adding the parameter of
KF permeability --- by means of field circuit structure
fabricated of odd-A nuclide matter --- created a KF intensity of
sufficient magnitude for unpaired N polarization and, hence, for
measuring with a resulting accuracy, as determined by
probability standards (where any ratio achieving a value of 20:1
is not a result of false test readings) of one billion to one.

Regarding field permeability, a KF structure which is composed
of odd-A nuclide matter --- for example, of aluminum, copper,
vanadium, cobalt, etc. --- bears a parallel with ferromagnetic
field circuit structures, as respects electromagnetism, in that
the former structure is, in part, of unpaired electrons. No
doubt that the relatively few people, knowledgeable in the area
of nuclear physics, would judge the KF moment, associated with
an unpaired nucleon of an odd-A nuclide, too weak (if indeed
they accepted the moments existence --- it constitutes a
salient rupture (as defined by KF reasoning) of the atomic
nucleus and is believed composed of a component of the nuclear
binding force --- to interact with the ambient and near-ambient
unpaired nucleons of the adjacent atomic structure. This
judgment would be based on the energy-interaction distance
capabilities of the strong interaction filed; it is thought to
be of the order of 10-13 cm. However, this energy
---composed of both the pairing and longer-range binding forces
--- has only been measured in the MeV energy range; only 15 KeV
is believed necessary --- via KF reasoning --- for interatomic
KF moment interaction. This KF moment consists of a modified
pairing (short-range) force energy. The binding force, holding
this unpaired nucleon within its nucleus, essentially consists
of the longer-range force energy.

Whereas the magnitude of the magnetic field --- for a given
magnetomotive force (mmf) --- can be increased many
thousand-fold by the application of a magnetically-permeable
field structure --- ferrites exhibit increases exceeding a
factor of 80,000 --- it is presently unknown what the KF
increase in magnitude is due to the KF permeability present
within various matter for a given KF mmf equivalent. However,
this KF magnitude increase has been shown to be manifold from
the results of KF permeability tests and KF circuit shunt tests.
KF ambient air-gap tests have also demonstrated the preference
of the KF for odd-A nuclide matter in contrast to vacuum, air
and even-even nuclide matter; a KF probe has measured
diminishing KF energy, up to 11.5 cm away from an experimental
apparatuss field circuit air-gap, in proportion to distance
from the air-gap, during Qualitative Testing.

The preceding paragraphs, then, provide a descriptive
explanation of those experimental techniques which make it
possible to incorporate and utilize matter in laboratory
apparatus --- for generating mass dynamic interactions --- with
densities some 1.6 x 1013 times greater than thought
possible by Einstein and others.

As this KF explanation evolves from the micro to the macro
condition, it is appropriate to note that matter possesses two
properties germane to this writing. There are two mass
properties related to all matter: the quiescent property of
weight and the dynamic property of inertia. The weight property
relates to the gravitational mass since the mass of a body is
regarded as the generator of the gravitational field. The
inertial property is that property of a body by which the body
will remain at rest, or in the same straight line or direction,
unless acted upon by some external force. When that external
force action is applied, an equal and opposite force reaction
concomitantly occurs, as conceived by Newton. According to KF
reasoning, this inertial property exists because of the KF
presence, and this force reaction is the force reaction of the
secondary, time-variant gravitational field induced by the
kinemassic field made time-variant.

The macro presence of the KF, in contrast to the micro presence
--- the latter as taught in the two US Patent publications
referred to above --- has its awareness emerge from the
following quotations found in the 4th edition of *Van
Nostrands Scientific Encyclopedia*, as follows: "Mach
Principle --- The inertial property of matter is a measure of
the total matter in the universe and its total relative motion,
the kinemassic field being the universal field stress medium
required for the communicating of, and for the inherent presence
of, this inertial property. Accordingly, when in its inertial
state, a bodys kinemassic field is unvarying with time but, in
its accelerative state, a bodys kinemassic field is
time-variant, and so gives rise to an induced, time-variant,
secondary gravitational field which exhibits its presence as a
vector force in opposition to the bodys acceleration as defined
by Newtons Laws of Motion".

Consider the following example of the macro KF in which it
would seem --- per the Mach Criterion --- to be contrary to the
methodicalness of Nature for the KF not to be present: Release a
one-pound hardened steel ball which is suspended 10 feet above a
hardened steel plate --- the two bodies having a mutual
Coefficient of Restitution of 90% --- thus the steel ball
rebounds to a height of 9 feet above the plate. Our present
acceptance of physics recognizes the following statements to be
true: While statically suspended, the ball possesses 10
foot-pounds of energy because of the gravitational field; when
released, the ball is in a state of acceleration and, because of
this, is in the process of transforming it gravitational
potential energy into kinetic energy; at the precise moment of
impact between ball and plate, the ball has completed this
energy transformation with almost 100% efficiency; after impact,
elastic deformations of ball and plate occur; because of the 90%
Coefficient of Restitution, there exists 0.9 x 10 ft lb, or 9
foot-pounds, of conservative potential energy stored within the
maximally deformed ball-plate system; this potential energy
storage is possible because of the stressing of the
electromagnetic fields responsible for the crystalline
structural integrity of solid matter; as the ball, in its
rebound state, just clears the plate surface, the
electromagnetic field potential energy storage is mostly
transformed to kinetic energy (the total non-conservative energy
transformation of one foot-pound appears as thermal energy loss
which results in a temperature increase within ball and plate);
immediately, the kinetic energy begins an energy transformation
back into 9 foot-pounds of gravitational field potential energy,
the cycle completing itself only when the ball and plate
separate to a 9-foot distance.

The point that is made here concerns the relationship between
energy states and the energy fields associated wth these energy
states during this cycle of energy transformations. Kindly note:
of all these energy states, only the kinetic energy state has no
inherent, essential field associated with it, according to the
current teachings of physics. This unrecognized field, this
missing link, this source of an empty niche, the filling of
which is required for energy/field symmetry, a field needed for
both rational and linear kinetic energies --- if Natures
orderliness is to be kept --- is the kinemassic field.

In accordance, then, with that KF statement --- in part,
similar to the Mach Principle noted above --- when a body is in
its inertial sate, only the kinemassic field is present:
however, when a body is in an accelerative state --- including
linear acceleration, angular velocity (radial acceleration), and
angular acceleration --- the kinemassic field becomes
time-variant thereby inducing an associated, secondary,
time-variant gravitational field as well.

Although straight-line motions and linear velocities are taught
as acceptable states of matter, these concepts may prove to be a
handicap in truly understanding Nature since the earth
continually accelerates towards the sun which, in turn, is in a
continuing state of acceleration towards the center of our
nebula which, in turn, is in a state of deceleration with
respect to the expanding universe. A path or ray of light could
be considered not to represent a straight line due to the
gravitational field gradients filling space. No orbit is truly
circular. The warped deviations of the near-ellipsoidal orbits
of earth satellites tells us much about the earths pear-shaped
configuration. And so it may be reasoned that so-called straight
lines, or curved displacements, are, in reality, extreme
examples of curved lines, or curved displacements, possessing
near-infinitely long, and curvy, radii; correspondingly, bodies
traveling at extremely miniscule accelerations respectively. A
geodesic line is the path followed by a particle upon which only
gravitational and inertial forces act. An example of such a path
is that traveled by a spacecraft towards the outer regions of
out planetary system. Such a path is te straightest path
possible in a 4-dimensional space-time continuum.

Before reviewing the main thoughts expressed in this writing,
it seems that further clarification should be given regarding
acceleration of matter by various means.

A distinction is made as to the several modes available for the
accelerating of mass according to gravitational field theories
and hypotheses. The equivalence Principle is stated in several
ways but its essence teaches that the greater the weight
property, of one body to another, the proportionately greater is
the inertial property of the first body to the other. Hence all
bodies, great and small, accelerate equally within the same
gravitational field gradient. Qetvos first demonstrated this
principle experimentally. Currently this equivalence has been
found to hold true to the eleventh order of magnitude.

If matter is accelerated by electromagnetic fields --- both
static and DC magnetic fields included --- it is regarded as in
its accelerated state. But if matter is accelerated by the
gravitational field, theories consider that it remains in its
inertial states of rest or translation although, if such matter
were released above the surface of the earth at our approximate
latitude, bith it and the earth would acclerate towards one
another at a combined acceleration of 32.17 ft/sec2.

Kinemassic field reasoning provides for accelerated relative
motions even though two bodies are, for example, in translatory
motions of constant velocities. Therefore a body may be at rest
in its relationship to the motion-averaging of universal
relative motion --- with respect to that spatial matter, still
within KF communication either because of the curvature of space
or, alternatively, because of not exceeding the velocity, viz.,
of electromagnetic propagation --- but still be in an
accelerative state of motion with respect to a local second body
which also is in its inertial rest state also with respect to
inertial space. Bodies, in these so-called inertial states ---
although experiencing distinct local relative motions --- are
reasoned to be centered within the sphere of the universes
total relative motion. This concept is more easily grasped if
the inertial state is that one of rest. Here the vector
summation, of this total relative motion, is zero, when measured
by an observer located at the position of the sphere-centered
body in its rest state, as would the gas molecules within a
gas-filled chamber when the chamber is held at a zero
temperature gradient. When in its inertial state of translation,
the body remains sphere-centered because of the curvature of
space as a mite would remain centered on the surface of a
sphere, as it moved about in an imaginary, so-called
3-dimensional universe of space-time.

One final distinction is presently worth citing. The same
edition of *Van Nostrands Scientific Encyclopedia*
earlier referenced (p. 973), under Gravitation and Gravity:
"Einsteins Equivalence Principle makes no distinction between
gravitation and centrifugal force...". Providing this statement
is quoted correctly by Van Nostrand, then a further difference
exists between this field theory of gravity and the KF reasoning
in the respect that the KF reasoning makes a distinction between
the gravitational field force and the centrifugal/ centripetal
force pair arising from radial acceleration: this distinction
concerns the differences in the characteristics of the two force
gradients. For all practical purposes, the earths gravitational
field force gradient diminishes exponentially --- to the second
power --- as elevation is gained along a local vertical above
the earth. The centrifugal force, acting on a spinning bodys
particles, diminishes linearly along a radial line of approach
to the bodys axis of rotation.

In review then --- as regard the macro state of the KF from an
inertial point of view --- all matter is in an accelerative
state of universal relative motion. Consequently, when based on
the foregoing reasoning, the kinemassic field is everywhere, in
its time-variant state, continuously inducting tie-variant
gravitational fields. The kinemassic field provides the
explanation for, and is the cause of, the inertial property of
matter. When matter is accelerated --- that is: when the
kinemassic field is made time-variant --- this time variance
causes induction of a secondary, time-variant gravitational
field; its physical presence is mechanically felt as that F =
Mdv / dt force reaction so well expressed by Newtons second and
third laws of motion as stated by Harvey E. White in *Classical
and Modern Physics*: Second Law --- The rate at which
momentum of a body changes is equal to the force acting and
takes place in the direction of the straight line in which the
force acts. Third Law --- "to every action force there is always
an equal and opposite reaction force".

Briefly, in closing, unpaired nucleons are reasoned to not only
possess spin axes and magnetic moments but also kinemassic
moments . This hypothesis seemingly is borne out by the actual
testing of polarized odd-A nuclide matter, in which field forces
--- probed/sensed up to 11.5 cm from the apparatus field
circuit test air gap --- were measured and determined not to be
of electromagnetic or gravitational energies. Because these
bodies of matter are 1.6 x 1013 more dense than
platinum and because their mass dynamic interactions are
comprehended as naturally occurring within atomic nuclei, the
measuring of such matter interactions within experimental
laboratory apparatus was deemed worth trying to measure. The
important concept of field permeability was incorporated within
the apparatus and, as was experimentally verified, success
depended upon the utilization of permeable field circuit
structure in order to provide sufficient field enhancement for
detection and measurement. This micro KF then is to be
identified in its macro form and, as briefly reviewed in the
preceding paragraph, provides the surprising insights that the
inertial forces of mass acceleration arise from induction of a
secondary gravitational field via a time-variant kinemassic
field, the kinemassic field providing the inertial property of
matter.

---

**US Patent # 3,626,605**

**Method
& Apparatus for Generating a Secondary Gravitational
Force Field**

**Henry W. Wallace**

December 14, 1971   
US CL. 35-19

**Abstract --** Apparatus
and
method
for generating a time variant non-electromagnetic force field
due to the dynamic interaction of relatively moving bodies
through gravitational coupling, and for transforming such
force fields into energy for doing useful work.

**Description**

The method for generating
such time variant force fields including the steps of
juxtaposing in field series relationship a stationary member
of spin nuclei material, and a member capable of assuming
relative motion with respect to said stationary member also
characterized by spin nuclei material; initiating relative
motion by rotation of said one member with respect to the
other, which rotational motion may occur both about an axis
within the plane of said other member and about an axis
perpendicular thereto; whereby the rotational motion of said
one member about the axis perpendicular to the plane of said
other member results in the dual interaction of the angular
momentum property of said other member thereby resulting in a
dynamic interaction field arising through gravitational
coupling which dynamic interaction is further characterized by
its non-electromagnetic nature and its mass-proximity and
relative motion dependency; the rotation of said one member
about the axis within the plane of said other interaction
field within said other member which in turn gives rise to a
secondary time-variant gravitational field in the surrounding
space.

The present invention
relates to an apparatus and method for generating a
time-variant force field due to the relative motion of moving
bodies; which force field exhibits itself in the form of an
induced secondary gravitational force. As such, this invention
constitutes a continuation-in -part of an application field
Nov. 4, 1968 by the same inventor, entitled Method &
Apparatus for Generating a Dynamic Force Field and bearing
Ser. No. 773,116 (US Patent #3,626,606).

In the practice of the
present invention it has been found that when bodies composed
of certain material are placed in relative motion with respect
to one another there is generated an energy field therein not
heretofore observed. This field is not electromagnetic in
nature; being by theoretical prediction related to the
gravitational coupling of relatively moving bodies.

The initial evidence
indicates that this non-electromagnetic field is generated as
a result of the relative motion of bodies constituted of
elements whose nuclei are characterized by half integral
"spin" values, the spin of the nuclei being associated with
the net angular momentum of the nucleons thereof. The nucleons
in turn comprise the elemental particles of the nucleus; i.e.
the neutrons and protons. For the purposes of the present
invention the field, generated by the relative motion of
materials characterized by a half integral spin value, is
referred to as a "kinemassic" field.

It will be appreciated that
relative motion occurs on various levels, i.e., there may be
relative motion of discrete bodies as well of the constituents
thereof including, on a subatomic level, the nucleons of the
nucleus. The kinemassic force field under consideration is a
result of such relative motion, being a function of the
dynamic interaction of two relatively moving bodies including
the elemental particles thereof. The value of the kinemassic
force field created, by reason of the dynamic interaction of
the bodies experiencing relative motion, is the algebraic sum
of the fields created by reason of the dynamic interaction of
both elementary particles and of the discrete bodies.

For a closed system
comprising only a stationary body, the kinemassic force, due
to the dynamic interaction of the subatomic particles therein,
is zero because of the random distribution of spin
orientations of the respective particles. Polarization of the
spin components so as to align a majority thereof in a
preferred direction establishes a flux field aligned with the
spin axes of the elementary particles. The present invention
is in part comprised of an apparatus for polarizing its spin
nuclei material, while additional means are provided to induce
an alternating or undulating effect in the kinemassic field so
generated.

Accordingly, a primary
object of the present invention concerns the provision of
means for generating a time-variant kinemassic field within a
permeable field body due to the dynamic interaction of
relatively moving bodies and the relative motion of said
generating means with respect to the permeable field body.

The kinemassic force field
finds theoretical support in the laws of physics, being
substantiated by the generalized theory of relativity.
According to the general theory of relativity, there exists
not only a static gravitational field but also a dynamic
component thereof due to the gravitational coupling of
relatively moving bodies.

This theory proposes that
two spinning bodies will exert force on each other. Heretofore
the theoretical predictions have never been experimentally
substantiated; however, as early as 1896, experiments were
conducted on stationary bodies placed near large, rapidly
rotating masses. The results of these early experiments were
inconclusive, and little else in the nature of this type of
work is known to have been conducted.

It is therefore another
object of the present invention to set forth an operative
technique for generating a measurable time-variant force field
due to the gravitational coupling of relatively moving bodies.

In carrying out the present
invention, means are provided to enable the relative
rotational motion of a first member with respect to a
stationary member positioned in close proximity thereto; the
construction of one embodiment of the first member being such
as to enable portions thereof to assume rotational motion
about an axis perpendicular to the plane of said stationary
member. The effect of the rotation of said member about the
axis perpendicular to the plane of the stationary member is to
establish a kinemassic force field in the nature of that
referred to in the aforementioned co-pending application of
the same inventor. The rotation of said member about the axis
lying within the plane of said stationary member results in an
undulation of the dynamic interaction field within said field
members which in turn induces a secondary time-variant
gravitational field in the surrounding space.

Accordingly, another more
specific object of the present invention concerns a method of
generating a non-electromagnetic force field due to dynamic
interaction of relatively moving bodies and for utilizing such
force field to further generate a secondary gravitational
field.

The foregoing objects and
features of novelty which characterize the present invention,
as well as other objects of the invention, are pointed out
with particularity in the claims annexed to and forming a part
of the present specification. For a better understanding of
the invention, its advantages and specific objects allied with
its use, reference should be made to the accompanying drawings
and descriptive matter in which there is illustrated and
described a preferred embodiment of the invention.

In the drawings:

Figure 1 shows an overall
view of equipment constructed in accordance with the
principles of the present invention, including means to
demonstrate the effect of a time-variant kinemassic force
field;

[Click to enlarge]

![](01.jpg)

Figure 2 is an isolation
schematic of apparatus components comprising the time-variant
kinemassic field circuit of Figure 1;

![](02.jpg)

Figures 3, 3A, 3B, 4 and 5
show the details of construction of the generator and detector
assemblies of Figures 1 and 2;

![](03.jpg)

![](03a.jpg)![](03b.jpg)

![](04.jpg)![](05.jpg)

Figure 6 represents measured
changes in operating characteristics of the apparatus of
Figures 1 and 2 demonstrating the time-variant nature of the
kinemassic force field so produced;   
[Click to enlarge]

![](06.jpg)

Figures 7, 7A and 7B are
sectioned views of various embodiments of the present
invention for demonstrating the time-variant nature of the
kinemassic force field as used in establishing a secondary
gravitational component.   
[Click to enlarge]

![](07.jpg)![](07a.jpg)  
![](07b.jpg)

Before getting into a
detailed discussion of the apparatus and the steps involved in
the practice of the present invention, it should be helpful to
and understanding if the present invention of consideration is
first given certain defining characteristics thereof, many of
which bear an analogous relationship to electromagnetic field
theory.

A first feature is that the
kinemassic field is vectorial in nature. The direction of the
field vector is a function of the geometry in which the
relative motion between mass particles takes place.

The second significant
property of the kinemassic field relates the field strength to
the nature of the material in the field. This property may be
thought of as the kinemassic permeability by analogy to the
concept of permeability in magnetic field theory. The field
strength is apparently a function of the density of the spin
nuclei material comprising the field circuit members. Whereas
the permeability in magnetic field theory is a function of the
density of unpaired electrons, the kinemassic permeability is
a function of the density of spin nuclei and the measure of
magnitude of their half integral spin values. As a consequence
of this latter property, the field may be directed and
confined by interposing into it denser portions of desired
configuration. For example, the field may be in large measure
confined to a closed loop of dense material starting and
terminating adjacent a system wherein relative motion between
masses is occurring.

A further property of the
kinemassic force field relates field strength to the relative
spacing between two masses in relative motion with respect to
one another. Thus, the strength of the resultant field is a
function of the proximity of the relatively moving bodies such
that relative motion occurring between two masses which are
closely adjacent will result in the generation of a field
stronger than that created when the same two relatively moving
bodies are spaced farther apart.

As mentioned above, a
material consideration in generating the kinemassic force
field concerns the use of spin nuclei material. By spin nuclei
material is meant materials in nature which exhibit a nuclear
external angular momentum. This includes both the intrinsic
spin of the unpaired nucleon as well as that due to the
orbital motion of these nucleons.

Since the dynamic
interaction field arising through gravitational coupling is a
function of both the mass and proximity of two relatively
moving bodies, then the resultant force is predictably
maximized within the nucleus of an atom due to the relatively
high densities of the nucleons plus the fact that the nucleons
possess both intrinsic and orbital components of angular
momentum. Such force fields may in fact account for a
significant portion of the nuclear binding force found in all
of nature.

It has been found that for
certain materials, namely those characterized by a half
integral spin value, the external component of angular
momentum thereof will be accompanied by a force de to the
dynamic interaction of the nucleons.

This is the so-called
kinemassic force which on a sub-macroscopic basis exhibits
itself as a dipole moment aligned with the external angular
momentum vector. These moments are of sufficient magnitude
that they interact with adjacent, or near adjacent, spin
nuclei field dipole moments of neighboring atoms.

This latter feature gives
rise to a further analogy to electromagnetic field theory in
that the interaction of adjacent spin nuclei field dipole
moments gives rise to nuclear domain-like structures within
matter containing a sufficient portion of spin nuclei
material.

As in electromagnetic field
theory, in an unpolarized sample the external components of
angular momentum of the nuclei to be subjected to a kinemassic
force field are randomly oriented such that the material
exhibits no residual kinemassic field of its own. However,
establishing the necessary criteria for such a force field
effects a polarization of spin components of adjacent nuclei
in a preferred direction thereby resulting in a force field
which may be represented in terms of kinemassic field flux
lines normal to the direction of spin.

The fact that spin nuclei
material exhibits external kinemassic forces suggests that
these forces should exhibit themselves on a macroscopic basis
and thus be detectable, when arranged in a manner similar to
that for demonstrating the Barnett effect when dealing with
electromagnetic phenomena.

In the Barnett effect a long
iron cylinder, when rotated at high speed about its
longitudinal axis, was found to develop a measurable component
of magnetization, the value of which was found to be
proportional to the angular speed. The effect was attributed
to the influence of the impressed rotation upon the revolving
electronic systems due to the mass property of the unpaired
electrons within the atoms.

In an apparatus constructed
in accordance with the foregoing principles it was found that
a rotating member such as a wheel composed of spin nuclei
material exhibits a kinemassic force field. The interaction of
the spin nuclei angular momentum with inertial space causes
the spin nuclei axes of the respective nuclei of the material
being spun to tend to reorient parallel with the axis of the
rotating member. This results in the nuclear polarization of
the spin nuclei material. With sufficient polarization, an
appreciable field of summed dipole movements emanates from the
wheel rim flange surfaces to form a secondary dynamic
interaction with the dipole moments of spin nuclei contained
within the facing surface of a stationary body positioned
immediately adjacent the rotating member.

When the stationary body,
composed of suitable spin nuclei material, is connected in
spatial series with the rotating member, a circuitous form of
kinemassic field is created, the flux of which is primarily
restricted to the field circuit.

If now means are provided to
periodically reverse the direction of rotation of the wheel
with respect to the facing surfaces of the stationary body
positioned in immediate proximity thereto, then the resultant
time-varying kinemassic field generates or induces an
accompanying time-varying secondary gravitational field in the
space immediately surrounding. That is to say, if the
time-varying kinemassic field is made to undulate typically
sinusoidally, there will be induced an accompanying undulating
secondary gravitational field, which is phase-related to the
kinemassic field. In this respect the induced secondary
gravitational field is generated in a manner analogous to
electromagnetic induction theory.

By properly configuring the
undulating kinemassic field, the resultant secondary
gravitational field may be essentially restrained to or
confined within an enclosed space. Although numerous geometric
configurations may be proposed, the necessary conditions are
established in the preferred embodiment of the present
invention by enclosing the kinemassic field generating
apparatus, including the rotational members and at least a
portion of the stationary member thereof, within an enclosure,
the material portions of which obey the rules concerning
kinemassic permeability.

The kinemassic field when so
configured, will shield the enclosed space both with respect
to the secondary gravitational field induced therein and with
respect to the ambient gravitational field caused by the earth
and other cosmic bodies, existing externally of the shielded
space. The undulating kinemassic field, which gives rise to
the enclosed secondary undulating gravitational field, is
effective in reducing the quantity of flux lines within the
space surrounded by the undulating kinemassic field
contributed by the ambient gravitational field, thus reducing
the mutual force of gravitational attraction acting between
this structure and the earth or other cosmic bodies dependent
upon their relative contribution to the local gravitational
flux density.

It is well known that nature
opposes heterogenous field flux densities. If the normal local
flux density contributed by the earth and the other cosmic
bodies within the space occupied by and surrounded by the
undulating kinemassic field permeable structure were added to
by the forcibly enclosed flux of the induced secondary
undulating gravitational field, this enclosed flux density
would be in opposition to nature. Although the induced
secondary undulating gravitational field would cause an
undulating variation of the cosmic or primary gravitational
field flux lines of force to penetrate within the kinemassic
field permeable structure, if this undulation were sinusoidal,
for example, the RMS or 0.707 value of peak reduction in
mutual gravitational attraction would apply.

Means for increasing the
relative magnitude of the undulating kinemassic field is
effected by positioning a mass circuit within the induced
secondary field space. The mass circuit in linking with the
undulating kinemassic field circuit results in an increase in
the kinemassic field and in the same sense effectively
intensifies the primary gravitational field shielding. A
partial parallel can be found in electromagnetic field theory,
where it is known that a shorted secondary turn enhances iron
saturation.

The mass circuit located in
the induced secondary field space need not be comprised of
material having a spin nuclei characteristic; rather, it is
more important that this mass circuit have high mass density.
A further desirable characteristic if this mass circuit is
that it have a capability for mass flow with respect to the
undulating kinemassic field structure. Mercury has the desired
combination of properties and while other materials may be
used, mercury is the most effective thus far known.

As indicated above, the
effective result of generating a secondary undulating
gravitational field within the space enclosed by the
undulating kinemassic field is a relative reduction in
apparent weight of the kinemassic field permeable structure,
with respect to its apparent weight without such an undulating
kinemassic field. The explanation of this phenomenon may be
readily conceived as caused by the generation of a field force
vector anti-parallel in direction to the local gravitational
field force vector. If the shielding is sufficiently effective
to reduce the density of gravitational field flux lines within
the shielded space to the equivalent of the ambient flux lone
density, there will be no net local distortion of the
gravitational field flux line pattern in the space enclosed by
the kinemassic field configuration. Without distortion of the
local flux line pattern the two bodies cease to mutually
attract and, in effect, become weightless, one with respect to
the other.

Although similar in result,
the technique for effecting the state of weightlessness in the
present invention differs from conventional apparatus for
achieving such a state of weightlessness. The latter, in
general, utilize the force of radial acceleration to
effectively "balance" the gravitational forces acting on a
body.

The relative magnitude of
the undulating kinemassic force field and the kinemassic
permeability characterizing the associated structure are both
influential in determining the effective shielding of the
kinemassic field permeable structure. If the shielding is
sufficiently effective so as to reduce the primary
gravitational field flux line density within the enclosed
space to less than that of the ambient, the distortion of the
local gravitational field flux line pattern of reduced flux
density would result in the anti-parallel field force vector
magnitudes exceeding that force of the kinemassic field body's
initial weight, i.e., the effective weight of the kinemassic
field permeable structure absent the generated undulating
kinemassic field. This condition would effectively endow the
kinemassic field structure with a negative weight
characteristic. As a consequence, the two bodies, that is the
kinemassic field body and the earth or other cosmic body,
would experience relative motion separating one another along
the local primary gravitational field flux lines unless acted
upon by other forces.

The hardware required to
generate and sustain such an undulating kinemassic field is in
part comprised of components which continue to retain a
"non-field-energized" weight during the period of field
generation. Therefore, the ambient gravitational field flux
line pattern within the structure will simultaneously
experience zones of both reduced and increased densities. It
is the average density of all the zones that determines the
magnitude of the anti-parallel field force vector in its
opposition to the ambient gravitational field force vector.
Bodies located within the shielded space enclosed by the
undulating kinemassic field will lose their weight with
respect to the body earth in direct proportion to the
reduction of ambient gravitational field flux lines which are
common to it and the body earth.

As a consequence of the
above, the shielding which results in a reduction of mutual
attraction between bodies screened by the shielding effected
by the undulating kinemassic force field does not violate the
principle of equivalence. Thus, two free bodies of different
masses, located within the shielded space, will fall within
this space toward or away from the earth with equal
accelerations. Also, the force of mutual gravitational
attraction of two or more bodies located within the shielded
space will be unaffected by the various degrees of shielding
although their freefall acceleration toward one another will
be affected.

From the foregoing
discussion, it will be appreciated that both for the purpose
of detecting the kinemassic field forces operative in the
present invention, and for transforming such forces into
energy for doing useful work, several basic apparatus elements
are necessary. First apparatus is needed to enable masses to
be placed in relative motion to one another; which relative
motion may occur in two mutually orthogonal directions. In
order to maximize field strength the apparatus should be
capable of generating high velocities between the particles in
relative motion. Furthermore, the apparatus should be
configured so that the proximity of the particles which are in
relative motion is maximized. The necessity of using
relatively dense material comprising half integral spin nuclei
for the field circuit portion of the apparatus has already
been stressed. These and other features are discussed in
greater detail below in explanation of the drawings depicting
an implementation of the invention.

In considering the drawings,
reference will first be made to the general arrangement of
components shown in Figures 1 and 2. As viewed in Figure1, the
equipment is mounted upon a stationary base comprising a
horizontal structural element 11 which rests upon poured
concrete pilings not shown or other suitable structurally
rigid material. It should be made clear at the outset that the
stationary base although not a critical element in its present
form nevertheless serves an important function in the subject
invention. Thus, the stationary base acts as a stabilized
support member for mounting the equipment and, perhaps more
significantly, the horizontal portion thereof is of such
material that it tends to localize the kinemassic force field
to the kinemassic force field generating apparatus proper.
This latter feature is discussed in more detail below. The
surface uniformity of the horizontal structural element 11
also facilitates the alignment of equipment components. In the
reduction to practice embodiment of the present invention, a
layer of shock-absorbing material, not shown, was interposed
between the stationary base and the floor.

Shown mounted on the
horizontal structural element 11 is the kinemassic force field
generating apparatus indicated generally as 10, the lower
portion of which is referred to as the lower mass member 12.
The lower mass member 12 is not to be confusingly associated
with the mass circuit mentioned above as being positioned in
the space experiencing the secondary gravitational field. The
nature and specific identity of the latter mentioned mass
circuit will be more fully explained in connection with the
explanation of Figure 7.

An upper mass member 13 is
positioned in mirrored relationship with respect to member 12
and separated somewhat to provide two air gaps therebetween.
The lower and upper mass members 12 and 13 function as field
circuit members in relationship to a generator 14 and a
detector 15 positioned with respective one's of two said gaps.
The spatial relationship of the generator 14, the detector 15
and the mass members 12 and 13 is such as to form a kinemassic
force field series circuit.

All of the material members
of the field circuit are comprised of half integral spin
material. For example, the major portion of the generator 14,
the detector 15, as well as the upper and lower mass members
13 and 12 are formed of a particular brass alloy containing
89% copper of which both isotopes provide a three-halves
proton spin, 10% zinc, and 1% lead as well as traces of tin
and nickel. The zinc possesses one spin nuclei isotope which
is 4.11% in abundance and likewise the lead also contains one
spin nuclei isotope which is 22.6% in abundance. In order to
gain an estimate of apparatus size, the upper mass member 13
has an overall length of 56 m and a mass of 43 kilograms.

It will be seen that, by
far, the constituents of the mass members a re such as satisfy
the criteria of half integral spin nuclei material for those
apparatus parts associated with the field and the use of
non-spin nuclei material for those parts where it is desired
to inhibit the field. Accordingly, all support or structural
members, such as the horizontal element 11 consist of steel.
The iron and carbon nuclei of these structural members are
classed as no-spin nuclei and thus represent high relative
reluctance to the kinemassic field. Supports 1 are provided to
accommodate the suspension of the upper mass member 13. The
supports 16 are of steel the same as the horizontal support
element 11. The high relative reluctance of steel to the
kinemassic field minimizes the field flux loss created in the
field series circuit of mass members 12 and 13, the generator
14 and the detector 15. The loss of field strength is further
minimized by employing high-reluctance isolation ridges at the
point of contact between the lower and upper mass members 12
and 13, and the structural support members 11 and 16.

Shunt losses within the
apparatus were, in general, minimized by employing the
technique of minimum mass contact; the use of low field
permeability material at the isolation bridges or structural
connections; and avoiding bulk mass proximity.

A number of techniques were
developed for optimizing the isolation bridge units including
Carboloy cones and spherical spacers. As is depicted more
clearly in Figures 3,4,and 5, the structural connection unit
ultimately utilized consisted of a hardened 60 deg steel cone
mounted within a setscrew and bearing against a hardened steel
platen. The contact diameter of the cone against the platen
measured approximately 0.007 inch and was loaded within
elastic limits. Adjustment is made by means of turning the
setscrew within a mated, threaded hole.

Figure 2 is presented in
rather diagrammatic form; however, the diagrammatic
configuration emphasizes that it consists of a rotatable
member corresponding to the generator 14 of Figure 1 which is
"sandwiched" between a pair of generally U-shaped members
corresponding to the lower and upper mass members 12 and 13 of
Figure 1. The wheel of the generator 14 is mounted for
rotation about an axis in the plane of the drawing. The
generator assembly is also shown as being mounted for rotation
about an axis perpendicular to the plane of the drawing;
however, the generator assembly may alternatively be oriented
to rotate in the plane of the drawing. When member 14 is
rotated rapidly with respect to the U-shaped member 12 and 13,
a kinemassic field is generated which is normal to the plane
defined by the rotating member and within the plane of the
drawing. As such, it may be represented in the drawing of
Figure 2 as taking a generally counter-clockwise direction
with respect to the field series circuit members.

Referring once more to
Figure 1, it is seen that support for the generator unit 14 is
provided by way of a support assembly 17, also fabricated of
steel components. The support assembly 17 is in turn clamped
to the horizontal structural element 11 by way of bracket
assemblies 18.

The detector 15 is of
similar configuration to the generator assembly 14, the
exception being that the detector assembly is mounted for
limited rotation about the axis normal to the plane of the
paper. The limited rotational capability is effected by a
knife-edge mounting 19 more clearly discernable in Figures 3A
and 3B. As will become more readily apparent from the
discussion of the operation of the embodiment of Figure 1
which follows, the knife-edge mounting enables a slow
sinusoidal oscillation of the detector assembly about its
knife-edge axis.

A pair of light-emitting and
light-sensing elements 20a and 20b respectively are shown in
Figure 1 in operative relationship to the generator and
detector assemblies 14 and 15. The function of the
light-generating and light-sensing members 20a and 20b is to
measure the rate of spin of the generator and detector wheels
respectively. For this purpose every other quadrant on the rim
surface is painted black. Accordingly, light directed at the
rim of the wheel will be reflected by the unpainted surfaces
into light-sensing cells associated with a rate-sensing
circuit of conventional design. Since the rate-measuring
circuit forms no part of the present invention it has not been
depicted in the actual drawing nor is it the subject of
further explanation.

Compressed air or nitrogen
is used to drive the generator and detector wheels. In this
respect the compressed gas is directed against turbine buckets
21b cut in the rim of wheel 21 of both the generator and
detector assemblies and such buckets are more readily
discernible in Figures 3, 4, and 5.the compressed gas is
supplied to the generator and detector assemblies by way of
air supply lines 28a and 28b.

Figures 3, 4 and 5 present
details of the generator and detector assemblies of Figures 1
and 2. In particular, these figures disclose the relationship
between a freely rotatable wheel 21, a bearing frame 22m and a
pair of pole pieces 23. The bearing frame 22 is of structural
steel, and functions to spatially orient the three generator
parts without shunting the generated field potential as well
as to maintain this orientation against the force moment
stresses of precession.

Positioning of the generator
wheel 21 with respect to the cooperative faces of the pole
pieces 23 is effected by way of the bearing frame upon which
the generator wheel is mounted. In this respect the
high-reluctance isolation bridges mentioned with respect to
Figures 1 and 2 are herein shown as set screws 24 which are
adjustably positioned to cooperate with hardened steel platens
25. The set screws 24 are mounted on the pole pieces 23 and
are adjustably positioned with respect to steel platens 25
cemented to the bearing frame 22 with respect to the interface
surfaces 23a of the pole pieces 23.

In the implementation of the
present invention the air gap formed between the generator
wheel rim flanges and the stationary pole pieces 23 was
adjusted to a light-rub relationship when the wheel was slowly
rotated; as such this separation was calculated to be 0.001
centimeter for a wheel spin rate of 28,000 rpm due to the
resulting hoop tension. In the drawing of Figure 3 the spacing
between the pole pieces 23 and the generator wheel rim flange
has been greatly exaggerated to indicate that in fact such a
spacing does exist.

The generator wheel 21
utilized in the implementation of the present invention has an
8.6 cm diameter and an axial rim dimension of 1.88cm. The rim
flange surfaces 21a which are those field emanating areas
closely adjacent the surfaces 23a of the pole pieces 23, are
each 29.6 square cm. The rim portion of the wheel has a volume
of 55.7 cubic cm neglecting the rim turbine slots 21b.

The generator wheel 21 and
an associated mounting shaft 26 are mounted of the bearing
frame 22 by means of enclosed double sets of matched high
speed bearings 27.

Shaft members 30 carry
suitable bearing members 31 for rotatably mounting the
generator assembly with respect to a second axis. The support
assembly 17 of Figure 1 is partially represented in Figure 3,
and as noted above provides the mounting means for positioning
the generator assembly 14 with respect to the lower and upper
mass members 12 and 13.

Reference is now made to
Figures 3A and 3B which disclose a portion of the detector 15
of Figure 1 including the knife-edge mounting 19 of Figure 1.
Adjusting means 32 are shown connected to the bearing frame
22a of the detector assembly 15 by means of a disc-like member
33. Attached to the lower portion of the disc 33, and depicted
in the end view of the detector assembly of Figure 3B, is
shown a second adjusting member 34, which in combination with
equivalent members 32 and 34 mounted on the other end of the
detector assembly, provide means for symmetrically aligning
the detector assembly within the gap provided by the lower and
upper mass members 12 and 13. This further means that the
knife-edge assembly is mounted so that the knife-edge axis is
coincident with the geometric axis of the detector assembly.
At the same time, the center of mass of the detector assembly
is located below the geometric center of the detector assembly
thereby providing a righting moment to the assembly due to the
asymmetry of the mass center with respect to the knife-edge
axis. The adjusting means 32 is shown as bearing against the
support assembly 17, thereby, in combination with the
knife-edge mounting at either end of the detector assembly,
providing an effective four point suspension for symmetrically
positioning the detector assembly 15 within the end poles of
the upper and lower mass members.

In Figures 1, 2 and 3 the
detector assembly 15 is shown in three different positions. As
will become apparent from the discussion of the operation of
the subject system which follows, the facility to so
reposition the detector assembly is necessary to demonstrate
its operative capabilities. Accordingly, the bearing frame 22a
is rotatably mounted with respect to the disc 33 by means of a
bearing surface interfacing the frame 22a with the shaft 35,
the latter being affixed to the face of the disc 33.

Proceeding now to the
explanation of the operation of the embodiment of the
invention thus far disclosed, it will be appreciated that in
accordance with the theory of operation of the present
apparatus when the generator wheel is made to spin at rates
upwards of 10 to 20 thousand rpm, effective polarization of
spin nuclei within the wheel structure gradually occurs. This
polarization gradually gives rise to domain-like structures
which continue to grow so as to extend their field dipole
moment across the interface separating the rim 21 from the
pole pieces 23. Secondary dynamic interaction of gravitational
coupling increases the field flux lines around the kinemassic
force generating assembly, thus resulting in ever increasing
total nuclear polarization of half integral spin nuclei.

The non-electromagnetic
forces so generated within the subject apparatus are primarily
channeled through the high-kinemassic permeability material
defining the series field circuit of the apparatus. The fact
that the high speed rotatable wheels of both the generator and
detector assemblies are capable of being positioned in a
series aiding or series opposing relationship, facilitates the
determination of the effective influence of the energies
generated in one on the other.

The detector, when carefully
balanced on its knife-edges as shown in Figures 3A and 3B,
exhibits an oscillation period of 11 seconds. When the wheels
are energized a stiffening action is induced due to the
reaction of the compressed gas impingement against the wheel
bucket 21b, since the jet nozzle is fixed with respect to the
apparatus base. This results in a reduction of the oscillation
period to approximately 6 seconds. A light image not shown is
directed against the mirrored face of the knife-edge 19 and
reflected onto a calibrated wall screen. Measurements were
taken with the apparatus so operative, which measurements
established the oscillatory extremes of the reflected light
beam for a pole-aligned relationship of the spinning generator
and detector wheels. The results of one such set of
measurements are recorded in Figure 6. Therein, the x's and
dots represent extremes in deviation while the large circles
represent the mean thereof. The mean was in turn used to
establish a null line to be compared with a similar null line
derived from pole-opposed orientation of the generator and
detector wheels. As a result, a displacement from equilibrium
of approximately 13 arc minutes is shown.

In order to minimize the
shift of the null line, the field circuit polar relationship
of the generator and detector poles was reversed every30 or 40
minutes from a relation of poles aligned, to poles opposed, to
poles aligned. An average null shift of 26 arc minutes is
indicated in Figure 6. That the interaction between generator
and detector was in fact accountable for the recorded results
was demonstrably supported when the upper mass member was
raised so as to create two air gaps one cm in length
respectively. Predictably, the disruption to the field circuit
continuity resulted in the failure of the apparatus to
register a shift in the null lines upon reversal of the poles.

Reference is now made to
Figure 7 which discloses an apparatus constructed in
accordance with the principles of the present invention for
generating a time-variant secondary gravitational field. This
apparatus is a mere modification of the apparatus in Figures 1
and 2 wherein one detector assembly 15 has been removed and
supplementary means are provided to mechanically implement the
rotation of the generator assembly 14 about the axis
perpendicular to the pane of the paper. These supplementary
means are in the nature of an auxiliary motor 36 having a
drive pulley 38 adapted to spin the generator assembly 14
about an axis normal to the plane of the drawing and
coincident with that of the shaft 30. The shaft 30 carries a
pulley 40 which is driven by the motor and pulley assembly
36-38 by way of a conventional drive belt 42. The wheel 21 of
the generator assembly 14 is driven in the manner outlined
above, namely by means of a source of compressed air not
shown.

The supporting assembly
depicted in Figure 7 in partially sectioned form as member 44,
is in reality the equivalent of the series mass circuit of
Figures 1 and 2, inverted or turned inside out so s to form a
shield for the kinetic field generating apparatus. Included as
part of the supporting assembly is member 44A which is
provided to position the generator assembly 14 in the
discontinuity formed in the mass circuit. The kinemassic field
generated within the apparatus of Figure 7 upon energization
of the wheel 21 is directed in an enveloping fashion about its
generator, being confined in general to the shell. The cross
sectional thickness of the shell along equipotential lines
must be equal in order to ensure a homogenous field within the
structure. If now the spin rate of the wheel 21 is made to
vary, or if the generator assembly 14 is made to rotate about
the axis defined by the shaft 30, a time-variant secondary
gravitational field is induced in the toroidal space 46.

The secondary gravitational
field undulates in a sinusoidal manner with the undulating
kinemassic field confined to the series mass circuit. Since
the kinemassic field in the dense mass circuit 44 has been
restricted through permeability, into an enveloping shell
about the generator 14, it follows that the induced undulating
secondary gravitational field is likewise restricted to the
enclosure 46 as the flux lines of both fields must interlink.
In accordance with the analogous electromagnetic field theory,
the kinemassic field flux lines and the secondary
gravitational field flux lines interlink in such manner that,
as the kinemassic field alternates, these interlinking loops
decay and build up in alternate vector directions in proper
phase relation.

A hollow ring member 48 is
positioned within the toroidal space 46 and supported thereby
a series of fine steel wire spokes 50 secured to the ring and
the outer portion of the inverted core housing 44 preferably
along points of equipotential of the kinemassic field. Within
the hollow ring 48 is contained a dense fluid such as mercury
depicted in Figure 7 generally as member52. Alternatively, the
ring-fluid combination may take the form of a single solid
mass. In the latter event the mass circuit would be supported
on bearings facilitating its rotation about an axis common to
the axis of the generator 21 in order to permit mass flow or
rotation of the mass circuit under the influence of the
alternating secondary gravitational field. The shielding
effected by the design considerations of the toroidal shell 44
with respect to the primary gravitational field reduces the
inertial parameter of mass acceleration within the toroidal
space 46 in proportion to the ambient gravitational shielding
effect. With reduced inertia there will be an appreciable
rotational flow displacement of the mass circuit 48-52 fore
ach half cycle of the induced secondary gravitational field,
thereby further strengthening the coupling effected between
the effective field forces, i.e., the primary gravitational
field, the kinemassic field and the secondary gravitational
field.

Consider now that the
apparatus of Figure 7 is energized such that the wheel 21
spins about its axis creating a uniformly distributed
kinemassic field throughout the entire field circuit referred
to generally as that encompassed within the inverted core
housing 44. As the generator assembly 14 is energized to
rotate about the axis passing through shaft 30, a uniformly
distributed alternating kinemassic field is established
throughout the field circuit.

The presence of the
undulating kinemassic field produces a shielding effect within
the inverted housing effectively restricting the induced
secondary gravitational field while at the same time tending
to shield or force out the flux due to the ambient
gravitational field. As the spin rates of the wheel and the
generator assembly about their respective axes are increased,
there results a stronger undulating kinemassic force field of
higher frequency. The spin rates may be so varied that a mean
gravitational flux line density within the apparatus of Figure
7 exists which is equivalent to the primary
gravitational  flux line density, i.e., that due to the
earth and other cosmic bodies. This condition establishes a
state of weightlessness or zero gravitational force of
attraction with respect to other masses such as earth. For
that particular value of gravitational field gradient.

If the spin rates of the
wheel and the generator assembly are further increased there
results a "bowing-out" or spreading of the gravitational flux
lines within the immediate proximity of the apparatus of
Figure 7 so as to result in a lesser flux line density, thus
resulting in the propulsion of the apparatus along the local
gravitational field lines of force in a direction
diametrically opposed to the local gravitational field force
vector.

Because of the nature of the
interaction of the primary gravitational field, the secondary
gravitational field forces will continue to act upon the
apparatus as it passes into lesser gravitational field
gradients; however, it will do so with diminishing magnitudes
until the local gravitational flux line density about the
apparatus of Figure 7 is no longer effectively diminished
thereby. The energy required to propel a vehicle powered by an
engine, such as is described above, is accounted for by the
way of the gravitational filed potential energy gained by such
a vehicle as it passes to areas of lesser gravitational field
intensities. Energy input into this engine would appear as the
product of torque and rotational values about the spin axes of
both the wheel and the generator assembly, and especially
about the latter axis which is responsible for alternating the
kinemassic field and thereby generating the secondary
gravitational component.

As was mentioned above in
explanation of the embodiment of Figures 1 and 2, the wheel 21
and the generator assembly 14 are mounted so as to be
rotatable in mutually orthogonal directions. It was further
mentioned that such orthogonal rotation is not an absolute
necessity, it being only necessary that relative motion be
established between the wheel 21 and the stationary pole
pieces 23. The generator assembly is made to rotate thereby
effecting an undulation in the kinemassic field flux in the
associated mass circuit. Figure 7A and 7B disclose a variation
of the apparatus of Figure 7 which satisfies the basic
requirements outlined above while at the same time providing
certain advantages not available in the aforementioned
structure.

In this respect Figures 7A
and 7B disclose an embodiment wherein the spin axis of the
equivalent wheel structure 21 and the generator assembly 14
are concentric thereby eliminating precessional forces present
in the embodiment of Figure 7 due to the rotation of the
respective members about the two mutually orthogonal axes. The
absence of precessional forces permits a close tolerance to be
established between the cooperating faces of the wheel
structure 21, the pole pieces 23 and the mass circuit 44.

The embodiment of Figures 7A
and 7B is also to be preferred to that of Figure 7 in that the
design of the generator assembly of the former permits the
energization of the independently rotatable members 21 and 23
by means of a single motor 36 differentially geared so as to
effect the rotation of the wheel 21 at a speed in excess of
that of the generator assembly, and as indicated, in a reverse
direction thereto.

Also indicated in the
embodiment of Figures 7A and 7B is the orientation of the flux
within the mass circuit, the latter being constructed
preferably of bismuth. It should be understood that the
direction of flux within the mass circuit reverses with each
reversal in orientation of the equivalent pole pieces 23 due
to the rotation of the generator assembly 14.

It will be apparent from the
foregoing description that there has been provided an
apparatus for generating time-variant kinemassic forces due to
the dynamic interaction of relatively moving bodies. Although
in its disclosed application the time-variant kinemassic force
has been described in relation to its function in generating a
secondary gravitational force, it should be readily apparent
that other equally basic applications of these forces are
contemplated.

Thus, in addition to
providing an effective propulsion technique, the principles of
the present invention may be utilized for the purpose of
generating localized areas of gravitational shielding for
housing medical patients for which such weight reductions
would be beneficial. In addition, the principles may be
adapted to laboratory use, as for example the analysis of the
effects of a sustained reduction of "g" value upon astronauts
and for specialized manufacturing techniques.

While in accordance with the
provisions of the statutes there has been illustrated and
described the best form of the invention known, it will be
apparent to those skilled in the art that changes may be made
in the apparatus described without departing from the spirit
of the invention as set forth in the appended claims, and that
in some cases, certain features of the invention may be used
to advantage without corresponding use of other features.

Having now described the
invention, what is claimed as new and for which it is desired
to secure Letters Patent is:

(1) An apparatus for
establishing a time-variant kinemassic force field resulting
for the relative motion of moving bodies, comprising a
generator assembly independent portions of which are mounted
to assume relative rotational motion about at least a single
axis locate within said generator assembly, a mass circuit of
dense material of discontinuous configuration, means for
positioning said generator assembly within said mass circuit
discontinuity, and means for initiating independent relative
motion of said generator assembly portions whereby an
undulating kinemassic force field is established within said
mass circuit.

(2) Apparatus according to
claim 1 further characterized in that said mass circuit and
said relatively moving portions are comprised of spin nuclei
material.

(3) An apparatus according
to claim 1 wherein said mass circuit is further characterized
by first and second U-shaped members positioned in mirrored
relationship with respect to each other and displaced somewhat
so as to form two air gaps therebetween, one of said gaps
corresponding to said mass circuit discontinuity and being
adapted to receive said generator assembly and the other gap
being adapted to receive a detector assembly.

(4) Apparatus constructed in
accordance with claim 1 wherein said mass circuit is further
characterized by a shell of generally toroidal configuration
having a cylindrical central portion within which is located
said mass circuit discontinuity.

(5) An apparatus constructed
in accordance with claim 2 wherein said generator assembly
mounted within said mass circuit discontinuity further
comprises a rotatable member, a frame, means for mounting said
rotatable member on said frame, pole pieces mounted on said
frame on either side of said rotatable member, each pole piece
presenting a generally circular face in close proximity to but
spaced from a face of said rotatable member about a first
axis, and means for rotating said frame about a second axis
oriented perpendicular to said first axis.

(6) Apparatus constructed in
accordance with claim 4 and further characterized by a dense
mass ring mounted within the walls of said shell structure by
mounting mass establishing small area contact between said
mass ring and said shell structure.

(7) An apparatus constructed
in accordance with claim 6 wherein said dense mass ring is
further comprised of a hollow shell housing a liquid metal of
suitable density.

(8) Apparatus according to
claim 6 wherein said shell is further characterized as being
of equal cross sectional area normal to the kinemassic lines
of force.

(9) Apparatus constructed
according to claim 3 wherein said shell is further
characterized as being of equal cross sectional area normal to
the kinemassic lines of force.

(10) A method of generating
a time-variant kinemassic force field including the steps of:

juxtaposing in field series
relationship a first member comprised of spin nuclei material
similarly constituted, portions of said member being adapted
to assume relative rotational motion about at least a single
axis;

initiating the independent
rotation of said first member about at least a single axis
whereby an undulating kinemassic force field is established
therein;

and so configuring said
second member as to confine said undulating kinemassic force
field thereto whereby a time-variant secondary gravitational
force field is induced in the surrounding space.

---

**US Patent # 3,626,606**

**Method
& Apparatus for Generating a Dynamic Force Field**

**Henry W. Wallace**

December 14, 1971   
US Cl. 35-19

**Abstract --** Apparatus
and
method
for generating a non-electromagnetic force field due to the
dynamic interaction of relatively moving bodies through
gravitational coupling, and for transforming such force fields
into energy for doing useful work.

**Description**

The method of generating
such non-electromagnetic forces includes the steps of
juxtaposing in field series relationship a stationary member,
comprising spin nuclei material further characterized by a
half integral spin value, and a member capable of assuming
relative motion with respect to said stationary member and
also characterized by spin nuclei material of one-half
integral spin value; and initiating the relative motion of
said one member with respect to the other whereby the
interaction of the angular momentum property of spin nuclei
with inertial space effects the polarization of the spin
nuclei thereof, resulting in turn in a net component of
angular momentum which exhibits itself in the form of a dipole
moment capable of dynamically interacting with the spin nuclei
material of the stationary member, thereby polarizing the spin
nuclei material in said stationary member and resulting in a
usable non-electromagnetic force.

This invention relates to an
apparatus and method for use in generating energy arising
through the relative motion of moving bodies and for
transforming such generated energy into useful work. In the
practice of the present invention it has been found that when
bodies composed of certain material are paced in relative
motion with respect to one another there is generated an
energy field therein not heretofore observed. This field is
not electromagnetic in nature; being by theoretical prediction
related to the gravitational coupling of moving bodies.

The initial evidence
indicates that this non-electromagnetic field is generated as
a result of the relative motion of bodies constituted of
elements whose nuclei are characterized by half integral
"spin" values; the spin of the nuclei being synonymous with
the angular momentum of the nucleons thereof. The nucleons in
turn comprise the elemental particles of the nucleus; i.e.,
the neutrons and protons. For purposes of the present
invention, the field generated by the relative motion of
materials characterized by a half integral spin value is
referred to as a "kinemassic" force field.

It will be appreciated that
relative motion occurs on various levels; i.e., there may be
relative motion of discrete bodies as well as of the
constituents thereof including on a subatomic level, the
nucleons of the nucleus. The kinemassic force field under
consideration is a result of such relative motion, being a
function of the dynamic interaction of two relatively moving
bodies including the elemental particles thereof. The value of
the kinemassic force field, created by reason of the dynamic
interaction of the bodies experiencing relative motion, is the
algebraic sum of the fields created by reason of the dynamic
interaction of both elementary particles and of the discrete
bodies.

For a closed system
comprising only a stationary body, the kinemassic force, due
to the dynamic interaction of the particles therein, is zero
because of the random distribution of spin orientations of the
respective particles. Polarization of the spin components so
as to align a majority thereof in a preferred direction
establishes a field gradient normal to the spin axis of the
elementary particles. The present invention is concerned with
an apparatus for establishing such a preferred orientation and
as a result generating a net force component capable of being
represented in various useful forms.

Accordingly, the primary
object of the present invention concerns the provision of
means for generating a kinemassic field due to the dynamic
interaction of relatively moving bodies.

A further object of the
present invention concerns a force field generating apparatus
wherein means are provided for polarizing material portions of
the apparatus so as to reorient the spin of the elementary
nuclear components thereof in a preferred direction thereby
generating a detectable force field.

The kinemassic force field
finds theoretical support in the laws of physics, being
substantiated by the generalized theory of relativity.
According to the general theory of relativity there exists not
only a static gravitational field but also a dynamic component
thereof due to the gravitational coupling of relatively moving
bodies. This theory proposes that two spinning bodies will
exert force on each other. Heretofore the theoretical
predictions have never been experimentally substantiated;
however, as early as 1896, experiments were conducted in an
effort to detect predicted centrifugal forces on stationary
bodies place near large, rapidly rotating masses. The results
of these early experiments were inconclusive, and little else
in the nature of this type of work is known to have been
conducted.

It is therefore another
object of the present invention to set forth an operative
technique for generating a measurable force field due to
gravitational coupling of relatively moving bodies.

Another more specific object
of the present invention concerns a method of generating a
non-electromagnetic force field due to the dynamic interaction
of relatively moving bodies and for utilizing such forces for
temperature control purposes including the specific
application of such forces to the control of lattice
vibrations within a crystalline structure, thereby
establishing an appreciable temperature reduction, these
principles being useful for example in the design of a heat
pump.

The foregoing objects and
features of novelty which characterize the present invention
as well as other objects of the invention are pointed out with
particularity in the claims annexed to and forming part of the
present specification. For a better understanding of the
invention, and its advantages and specific objects allied with
its use, reference should be made to the accompanying drawings
and descriptive matter in which there is illustrated and
described a preferred embodiment of the invention.

In the drawings:

Figure 1 is an overall
perspective view of equipment constructed according to the
present invention, this equipment being designed especially
for demonstrating the useful applications of kinemassic force
fields;   
[Click to enlarge]

![](001.jpg)

Figure 2 is an isolation
schematic if apparatus comprising the kinemassic field circuit
of the apparatus of Figure 1, showing the field series
relationships of the generator and detector units;   
[Click to enlarge]

![](002.jpg)

Figures 3, 4, and 5 show the
generator of Figures 1 and 2 in greater detail;   
[Click to enlarge]

![](003.jpg)![](004.jpg)  
![](005.jpg)

Figure 6 is an enlarged view
of the detector working air gap area of the apparatus in
Figures 1 and 2;   
[Click to enlarge]

![](006.jpg)

Figure 7 is a sectional view
of Figure 6 showing associated control and monitoring
equipment; and   
[Click to enlarge]

![](007.jpg)

Figure 8 represents measured
changes in the operating characteristics of a crystalline
target subject to a kinemassic force field generated in the
apparatus of Figures 1 and 2.   
[Click to enlarge]

![](008.jpg)

Before getting into a
detailed discussion of the apparatus and steps involved in the
practice of the present invention it should be helpful to an
understanding of the present invention if consideration is
first given to certain defining characteristics, many of which
bear an analogous relationship to electromagnetic field
theory. A first feature is that the kinemassic field is
vectorial in nature. The direction of the field vector is a
function of the geometry in which the relative motion between
mass particles takes place.

The second significant
property of the kinemassic field relates the field strength to
the nature of the material in the field. This property may be
thought of as the kinemassic permeability by analogy to the
concept of permeability in magnetic field theory. The field
strength is apparently a function of the density of the spin
nuclei material comprising the field circuit members. Whereas
the permeability in magnetic field theory is a function of the
density of spin nuclei and the measure of magnitude of their
half integral spin values. As a consequence of this latter
property, the field may be directed and confined by
interposing into it denser portions of desired configuration.
For example, the field may be in large measure confined to a
closed loop of dense material starting and terminating
adjacent a system wherein relative motion between masses is
occurring.

A further property of the
kinemassic force field relates field strength to the relative
spacing between two masses in relative motion with respect to
one another. Thus, the strength of the resultant field is a
function of the proximity of the relatively moving bodies such
that relative motion occurring between two masses which are
closely adjacent will result in the generation of a field
stronger than that created when the same two relatively moving
bodies are spaced farther apart.

As mentioned above, a
material consideration in generating the kinemassic force
field concerns the use of spin nuclei material. By spin nuclei
material is meant materials in nature which exhibit a nuclear
external angular momentum component. This includes both the
intrinsic spin of the unpaired nucleon as well as that due to
the orbital motion of these nucleons.

Since the dynamic
interaction field arising through gravitational coupling is a
function of both the mass and the proximity of two relatively
moving bodies, then the resultant force field is predictably
maximized within the nucleus of an atom due to the relatively
high densities of the nucleons, both in terms of mass and
relative spacing, plus the fact that the nucleons possess both
intrinsic and orbital components of angular momentum. Such
force fields may in fact account for a significant portion of
the nuclear binding force found in all nature.

It has been found that for
certain materials, namely those characterized in a half
integral spin value, the external component of angular
momentum thereof will be accompanied by a force due to the
dynamic interaction of the nucleons. This is the so-called
kinemassic force which on a submacroscopic basis exhibits
itself as a field dipole moment aligned with the external
angular momentum vector. These moments are of sufficient
magnitude that they interact with adjacent, or near adjacent
spin nuclei field dipole moments of neighboring atoms.

This latter feature gives
rise to a further analogy to electromagnetic field theory in
that the interaction of adjacent spin nuclei field dipole
moments gives rise to nuclear domain-like structures within
matter containing sufficient spin nuclei material.

Although certain analogies
exist between the kinemassic force field and electromagnetic
field theory, it should be remembered that the kinemassic
force is essentially non-responsive to or affected by
electromagnetic force phenomena. This latte condition further
substantiates the ability of the kinemassic field to penetrate
through and extend outward beyond the ambient electromagnetic
field established by the moving electrons in the atomic
structure surrounding the respective spin nuclei

As in electromagnetic field
theory, in an unpolarized sample, the external components of
angular momentum of the nuclei to be subjected to a kinemassic
force field are originally randomly oriented such that the
material exhibits no residual kinemassic field of its own.
However, establishing the necessary criteria for such a force
field effects a polarization of the spin components of
adjacent nuclei in a preferred direction thereby resulting in
a force field which may be represented in terms of kinemassic
field flux lines to the direction of spin.

The fact that spin nuclei
material exhibits external kinemassic forces suggests that
these forces should exhibit themselves on a macroscopic basis
and thus be detectable, when arranged in a manner similar to
that for demonstrating the Barnet effect when dealing with
electromagnetic phenomena.

In the Barnett effect a long
iron cylinder, when rotated at high speed about its
longitudinal axis, was found to develop a measurable component
of magnetization, the value of which was found to be
proportional to the angular speed. The effect was attributed
to the influence of the impressed rotation upon the revolving
electronic systems due to the mass property of the unpaired
electrons within the atoms.

In the apparatus constructed
in accordance with the foregoing principles it was found that
a rotating member composed of spin nuclei material exhibits a
kinemassic force field. The interaction of the spin nuclei
angular momentum with inertial space causes the spin nuclei
axes of the respective nuclei of the material being spun to
tend to reorient parallel with the axis of the rotating
member. This results in the nuclear polarization of the spin
nuclei material. With sufficient polarization, an appreciable
field of summed dipole moments emanates from the wheel rim
flange surfaces to form a secondary dynamic interaction with
the dipole moments of spin nuclei contained within the facing
surface of a stationary body positioned immediately adjacent
the rotating member.

When the stationary body,
composed of suitable spin nuclei material, is connected in
spatial series with the rotating member, a circuitous form of
kinemassic field is created; the flux of which is primarily
restricted to the field circuit.

Having now further defined
the substantiating theory giving rise to the kinemassic forces
operative in the present invention, reference is now made to
the aforementioned drawings depicting in general an apparatus
embodying the defining characteristics outlined above.

From the foregoing
discussion, it will be appreciated that for both the purpose
of detecting and exploiting the kinemassic field, several
basic apparatus elements are necessary. First, apparatus is
needed to enable masses to be placed in relative motion to one
another. In order to maximize field strength the apparatus
should be capable of generating high velocities between the
particles in relative motion. Furthermore, the apparatus
should be configured so that the proximity of the particles
which are in relative motion is maximized. The necessity of
using relatively dense material comprising half integral spin
nuclei for the field circuit has already been stressed. These
and other features are discussed in greater detail below in
explanation of the drawings depicting an implementation of the
invention, primarily for detection of the kinemassic field.

In considering the drawings,
reference will first be made to the general arrangement of
components, as particularly shown in Figures 1 and 2. As
viewed in Figure 1, the equipment is mounted upon a stationary
base comprising a horizontal structure element 10 which rests
upon permanent pilings of poured concrete 11 or other suitable
structurally rigid material. It should be made clear at the
outset that the stationary base although not a critical
element in its present form nevertheless serves an important
function in the subject invention. Thus, the stationary base
acts as a stabilized support member for mounting the
equipment, and perhaps more significantly, the horizontal
portion thereof is of such material that it tends to localize
the kinemassic force field to the kinemassic force field
generating apparatus proper. This latter feature is discussed
in more detail below. The surface feature is discussed in more
detail below. The surface uniformity of the horizontal
structure element 10 also facilitates the alignment of
equipment components. In the reduction to practice embodiment
of the present invention a layer of shock-absorbing material
(not shown) was interposed beneath the stationary base and the
floor.

Shown mounted on the
horizontal structural element 10 is the kinemassic force field
generating apparatus indicated generally as 20, the lower
portion of which is referred to as the lower mass member 12.
An upper mass member 13 is positioned in mirrored relationship
with respect to member 12 and separated somewhat to provide
two air gaps therebetween. The lower and upper mass members 12
and 13, respectively, are formed of a particular brass alloy
containing 89% copper, of which both isotopes provide a
three-halves proton spin, 10% zinc, and 1% lead, as well as
traces of tin and nickel. The zinc atom possesses one spin
nuclei isotope which is 4.11% in abundance and likewise the
lead also contain one spin nuclei isotope which is 22.6% in
abundance. In order to gain an estimate of apparatus size, the
upper circuit member has an overall length of 56 centimeters
and a mass of 43 kilograms.

It will be seen that the
constituents of the mass members are such as satisfy the
criteria of half integral spin nuclei material for those
apparatus parts associated with the fields and the use of
non-spin material for those parts where it is desired to
inhibit the field. Accordingly, all support or structural
members, such as the horizontal structural element 10, consist
of steel. The iron and carbon nuclei of these structural
members are classed as no-spin nuclei and thus represent high
relative reluctance to the kinemassic field. Supports 16 are
provided to accommodate the suspension of the supper mass
member 13. The supports 16 are of steel the same as the
horizontal support element 10. The high relative reluctance of
steel to the kinemassic field minimizes the field flux loss
created in the field series circuit of mass members 12 and 13,
the generator 14, and the detector 15. The loss of field
strength is further minimized by employing high-reluctance
isolation bridges at the points of contact between the lower
and upper mass members 12 and 13, and the structural support
members 10 and 16.

Shunt losses within the
apparatus were, in general, minimized by employing the
technique of minimum mass contact; the use of low field
permeability material at the isolation bridges or structural
connections; and avoiding bulk mass proximity.

A number of techniques were
developed for optimizing the isolation bridge units including
Carboloy cones and spherical spacers. As is depicted more
clearly in Figures 3,4,and 5, the structural connection unit
ultimately utilized consisted of a hardened 60 deg steel cone
mounted within a setscrew and bearing against a hardened steel
platen. The contact diameter of the cone against the platen
measured approximately 0.007 inch and was loaded within
elastic limits. Adjustment is made by means of turning the
setscrew within a mated, threaded hole.

Figure 2 is presented in
rather diagrammatic form; however, the diagrammatic
configuration emphasizes that it consists of a rotatable
member corresponding to the generator 14 of Figure 1 which is
"sandwiched" between a pair of generally U-shaped members
corresponding to the lower and upper mass members 12 and 13 of
Figure 1. The wheel of generator 14 is mounted for rotation
about an axis lying in the plane of the drawing. When member
14 is rotated rapidly with respect to the U-shaped members 12
and 13, a kinemassic field is generated which is normal to the
plane defined by the rotating member and within the plane of
the drawing.

As such, it may be
represented in the drawing of Figure 2 as taking a generally
counterclockwise direction with respect to the field series
circuit members.

Referring once more to
Figure 1, it is seen that support for the generator unit 14 is
provided by way of a support assembly 17, also fabricated of
steel components. The support assembly 17 is in turn clamped
to the horizontal structural element 10 by way of bracket
assemblies 18.

In the embodiment of the
present invention depicted in Figures 1 and 2, the lower and
upper mass members 12 and 13 are fashioned into conical
sections terminating in conical pole faces 12a and 13a in the
area of the detector 15. This configuration tends to maximize
the flux density in this area.

For isolation purposes, a
curtain of transparent plastic material 19 is positioned so as
to geometrically bisect the detector portion of the field
circuit from the generator portion thereof. The function of
the transparent curtain is to provide a degree of thermal
isolation between the generator and detector units. Although
not actually shown in Figure 2, the transparent curtain is of
H configuration and forms a vertical plane normal to the plane
of the drawing and symmetrically positioned with respect
thereto.

Not shown in the drawings
are a tunnel of transparent material and a film of flexible
plastic material which surrounds the detector 15 and
associated equipment and thus serve to further stabilize the
temperature conditions, thereby diminishing the adverse
effects due to thermal gradients.

Before proceeding with the
explanation of the operation of the apparatus disclosed in
Figures 1 and 1, a more detailed description of certain
portions of the structure will be given.

Figures 3, 4, and 5 present
the generator assembly 14 of Figures 1 and 2 in greater
detail. In particular, these figures disclose the relationship
between a freely rotatable wheel 21, a bearing frame 22, and a
pair of pole pieces 23. The bearing frame 22 os of structural
steel, and functions to spatially orient the three generator
parts without shunting the generated field potential.

Positioning of the generator
wheel 21 with respect to the cooperative faces of the pole
pieces 23 is effected by way of the bearing frame upon which
the generator wheel is mounted. In this respect the
high-reluctance isolation bridges mentioned with respect to
Figures 1 and 2 are herein shown as setscrews 24 which are
adjustably positioned to cooperate with hardened steel platens
25. The setscrews 24 are mounted on the pole pieces 23 and are
adjustably positioned with respect to steel platens 25
cemented to the bearing frame 22 so as to facilitate the
centering of the generator wheel 21 with respect to the
interface surfaces 23a of the pole pieces 23.

In the implementation of the
present invention the air gap formed between the generator
wheel rim flanges and the stationary pole pieces 23 was
adjusted to a light-rub relationship when the wheel was slowly
rotated; as such this separation was calculated to be 0.001
centimeter for a wheel spin rate of 28,000 rpm due to the
resulting hoop tension. In the drawing of Figure 3 the spacing
between the pole pieces 23 and the generator wheel rim flange
has been greatly exaggerated to indicate that in fact such a
spacing does exist.

The generator wheel 21
utilized in the implementation of the present invention has an
8.6 cm diameter and an axial rim dimension of 1.88cm. The rim
flange surfaces 21a which are those field emanating areas
closely adjacent the surfaces 23a of the pole pieces 23, are
each 29.6 square cm. The rim portion of the wheel has a volume
of 55.7 cubic cm neglecting the rim turbine slots 21b.

The generator wheel 21 and
an associated mounting shaft 26 are mounted of the bearing
frame 22 by means of enclosed double sets of matched high
speed bearings 27.

Compressed air or nitrogen
is used to drive the generator wheel by means of gas
impingement against turbine buckets 21b cut in the wheel rim.
The compressed gas is supplied through the supply line 28 and
emanates from the air jet tube 29. Rate of spin is sensed by
light rays reflected from the rim. For this purpose every
other quadrant on the rim surface was painted black.
Accordingly, light directed at the rim of the wheel will be
reflected by the unpainted quadrants into light-sensing cells
associated with a rate-measuring circuit of conventional
design. Since the rate-detecting means form no part of the
present invention they have not been depicted in the actual
drawing.

Shaft members 30 carry
suitable bearing members 31 for rotatably mounting the
generator assembly with respect to a second axis. The support
assembly 17 of Figure 1 is partially represented in Figure 4,
and, as noted above it provides the mounting means for
positioning the generator assembly 14 with respect to the
lower and upper mass members 12 and 13.

Before proceeding to an
explanation of the operation of the generator assembly with
respect to the apparatus of Figure 1, reference is made to
Figures 6 and 7 which disclose an enlarged view of the
detector 15. The lower and upper mass members 12 and 13 are
given a conical configuration so as to maximize kinemassic
densities in the area of the working air gap, within which the
detector is positioned. Figure 7 represents a sectional view
taken across the working air gap, showing the projection of
the conical surface of the upper mass member onto the
corresponding surface of the lower mass member. Although
symmetrical in shape, the projection of the conical surface of
the upper mass member onto the corresponding surface of the
lower mass member has been slightly reduced for purposes of
illustration. In the subject apparatus the two conical brass
pole faces 12a and 13a form a working air gap measuring 0.114
cm across. Each disc shape pole face measures 0.71 square cm
in area.

The detector or probe 15 is
of indium arsenide and is inserted in the detector air gap
with a spacing from either pole face of 0.02 cm, the target
thickness measuring 0.07 cm. Both indium and arsenic possess
100% isotope abundance of half integral spin nuclei; arsenic
nuclei consist of one isotope of three halves proton spin,
while indium nuclei are of two isotopes, both being
nine-halves proton spin.

A second probe of similar
semi-conductor material 15a is shown in Figure 6 as being
positioned in close proximity to the first detector. Both
probes 15 and15a are shown mounted on a boom 15b which is
shock-mounted by means not shown. Shock mounting of the
components is important due to the relatively close spacing
between the probe and conical pole faces. Lateral displacement
of the second probe from the vicinity of the working air gap
measured as 25 cm.

Although not critical to the
overall theory of the present invention, the selection of a
semi-conductor probe of the nature heretofore described and
the effective results realized through the positioning of the
probe 14 and the associated probe 15a with respect to the
working air gap between the conical pole faces as well as the
manner in which signals measured by the two probes is
correlated, are important to an understanding of the forces
involved. In this respect it is important to realize that the
first and second semi-conductor probes were differentially
connected in terms of electrical output and are
polarity-sensitive to magnetic field measurements. Together
the two probes constitute a differential magnetic probe for an
FW Bell Gaussmeter. As conventionally used, such probes
provide a measure of the magnetic field intensity from both AC
and DC sources, via the Hall Effect. The Hall Effect is a well
known phenomenon whereby a potential gradient is developed in
a direction transverse to the direction of current flow within
a conductor when the conductor is positioned in a magnetic
field. It should be clearly understood, however, that no
magnetic field phenomenon is associated with the present
invention. Thus the lateral voltages which are measured in the
present arrangement are not Hall voltages. This statement is
substantiated by the explanation that follows, clearly
establishing the absence of any hall voltage indicative of
magnetic fields. In this respect, the two probes are
differentially connected for magnetic field measurements to
eliminate errors due to ambient magnetic field changes whereas
they are additively connected for sensing changes in thermal
vibration of crystal lattices. Although polarity sensitive to
the magnetic field, the differential magnetic probe is not
polarity-sensitive to changes in thermal vibration of crystal
lattices.

The fact that the probes are
polarity-sensitive with respect to magnetic field but not with
respect to the direction of crystal lattice vibrations means
that when the probes are reversed with respect to polarity any
discernable difference in the output readings might be
attributed to a magnetic field induced into the system by the
rotating wheel. Inasmuch as the field conductive portions of
the apparatus are comprised predominantly of brass which is a
paramagnetic material, no appreciable magnetic field should be
detected. This in fact corresponds to the actual results in
that no measurable difference in magnetic flux was recorded
when the polarity of the probe was changed. It is thus
possible to realistically discount magnetic fields as
influencing operating results.

As seen in Figure 7, the
detector 15 has associated therewith two pairs of contacts 32
and 33, the first of which represents current contacts
connected in turn to a source of constant current 34 of
conventional design. The second set of contacts 33 are voltage
contacts connected to detect any potential gradient transverse
to the direction of current flow within the detector. The
meter 36 represents means for detecting such potential
differences and may be in the form of a very sensitive
galvanometer.

A thermocouple 35 is
positioned in close proximity to the detector 15 to monitor
the temperature thereof. Temperature differences, such as
recorded by the thermocouple 35, are used for purposes of
providing correction figures to the test results. A similar
thermocouple is used in conjunction with the second detector
15a, as well as with the upper mass member particularly in the
area of the generator wheel. Thermocouples are used for
temperature monitoring since the energy change of their
conducting electrons, by which they sense temperature change,
are not measurably affected by the kinemassic field.

Proceeding now to an
explanation of the operation of the subject invention, it will
be appreciated that in accordance with the theory of operation
of the present apparatus when the generator wheel is made to
spin at rates upwards of 10 or 20 thousand rpm, effective
polarization of spin nuclei within the wheel structure
gradually occurs. This polarization gradually rises to
domain-like structures which continue to grow so as to extend
their field dipole moment across the interface separating the
rim 21 from the pole pieces 23. Secondary dynamic interactions
of gravitational coupling between respective dipoles increase
the field flux lines around the apparatus field circuit, thus
resulting in ever-increasing total nuclear polarization of
half integral spin nuclei.

The non-electromagnetic
forces so generated within the subject apparatus are directed
to the working air gap within which is positioned the
semi-conductor probe 15. Therein the kinemassic forces are
constructively used to reduce the vibrational degrees of
freedom of the crystal lattice structure, resulting in a
change of its electrical conductivity property. More
specifically, the kinemassic field, due to the dynamic
interaction of the gravitational coupling of the mass
components of the wheel in relation to the stationary portions
of the pole pieces in immediate proximity therewith, is
restricted to the relatively high permeability material
comprising the lower and upper mass members, and is
concentrated at the working air gap by means of the conical
pole pieces. Inserted in the air gap is the probe of
semiconductor spin nuclei material.

Control circuitry connected
to two of the four contacts on the semiconductor probe 15 is
designed to maintain a constant current flow across these
contacts. At the same time the ambient temperature of the area
surrounding the equipment is permitted to increase. In fact
the increase in ambient temperature is initiated well in
advance of the initiation of rotation of the generator wheel
giving rise to the non-electromagnetic kinemassic force field.
The constant increase in temperature is meant to mask out
otherwise positive and negative temperature variations
resulting in a signal-to-noise ratio of measurement.

In light of the gradual and
constant increase in temperature of both the equipment and
ambient conditions surrounding the equipment, it might be
expected that the thermal vibrations of crystal lattice of the
semiconductor probe would likewise increase. In actuality, a
measurable decrease in crystal lattice vibrations is detected
within the semiconductor probe. The actual measurements
recorded are in terms of nanovolts of meter movement, and
correspond to a decrease in lateral voltages measured across
the semiconductor probe. These values can only be accounted
for by an effective polarization of the spin nuclei of the
lattice structure due to the polarizing effects of the applied
kinemassic force field. The polarization results in a change
in the specific heat property of the crystal material, which
in turn reflects itself as an increase in electrical
conductivity measurable by the galvanometer.

Reference is now made to
Figure 8 which discloses in graphical relationship the results
achieved by various test arrangements of the semiconductor
probe with respect to the subject apparatus.

In the interpretation of the
graphical relationships of Figure 8 it should be understood
that corrections for temperature variations have already been
applied. These temperature corrections account for the heat
applied to the system, as well as that due to the change in
specific heat property of the apparatus due to frictional
heating, as well as that due to the change in specific heat
property of the apparatus, principally the brass members die
to their relative bulk. The later component represents a
positive contribution to the ambient temperature due to the
decrease in degrees of freedom of the crystal lattice
structure of the spin nuclei material when subjected to the
kinemassic force field. The above mentioned heat factors
result in the increased temperature of the brass members of
the apparatus; these increases being monitored by way of
thermocouples positioned in proximity to the kinemassic field
generating apparatus, member 35 of Figure 7 being an example
thereof.

Curve 1 of Figure 8
represents a static test conducted over a period of 150
minutes, values being recorded at 3 minute intervals which was
standard procedure for the entire test series. Information
gathered in respect to curve 1 was useful in determining
compensating factors for ambient temperature changes. In curve
1 as well as each of the other curves of Figure 8, the
ordinate values measure a level of thermal vibration, in
nanovolts of meter movement, of InAs lattice structure against
time in which ambient temperature change of the two probes has
been quantitatively compensated.

Curve 2 represents a portion
of a standard test run, the portion shown being the active
portion of the curve, i.e., that portion of the curve for
which measurable results were recorded due to the spinning of
the generator wheel. Not included in curve 2 are measurements
taken during a 78-minute pre-energizing thermal calibration
period typical of the initial portion of each test run
conducted. The pre-energizing thermal calibration period is
effected in order to illustrate the ambient temperature
compensation of the probes and as such is similar to that of
the static test of curve 1.

The first 45 minutes of the
indicated 150 minute test period of curve 2 represents the
time during which the continuity of the negatively sloping
curve prior to, during and following the time interval of the
wheel returning to its no-spin state, and subsequently (an
indication of a return toward thermal equilibrium percentage
distribution of spin angular moment) is consistent with the
explanation advanced above concerning the force field
generated due to the dynamic interaction of relatively moving
bodies. It should be noted with respect to curve 2 that
separate test runs conducted some 6 weeks apart tend to
corroborate the independent test results. The results of the
two separate tests are superimposed in curve 2. These two
tests, in addition to being spaced in time, were spaced many
test runs apart. The two test results further establish the
repeatability of the operation.

The change in thermal
vibration of the InAs crystal lattice for the test run of
curve 2 is approximately equivalent to an11 deg C reduction in
probe temperature. This figure has been substantiated by
computer studies. The computer has also been used to
statistically analyze the test data and establish the
probability of error in terms of the information recorded. In
this respect the results of the computerized study indicate a
probability of error of 1 in 1 billion. Since any ration in
excess of 1 in 20 eliminates the probability of chance
occurrence, the results obtained in the present instance
should be above reproach.

In order to substantiate the
distance dependency of the gravitational coupling force due to
the dynamic interaction of relatively moving bodies it was
predicted that increasing the separation between the generator
rim flange 21a and the cooperating surface of the pole pieces
23a should measurably reduce the results obtained. The results
obtained when this separation was increased to 0.006 cm
appears in curve 3. A comparison of these results with those
of curve 2 seemingly substantiates the conclusion that upon
widening the gap a lessening of the dynamic interaction due to
gravitational coupling between the spinning wheel and the
stationary pole piece actually occurs.

The data of curve 4 was
taken with the air gap separation of the wheel to pole piece
established at 0.001 cm as in the arrangement of curve 2;
however, the duration of wheel spin was decreased from 45
minutes to 30 minutes. Curve 2 results are shown superimposed
on the solid line of curve 4. The relative magnitudes of
curves 2 and 4, when so contrasted with their respective wheel
spin periods, would appear to indicate a degree of half
integral spin nuclei polarization saturation.

Curve 5 depicts the results
achieved by way of a shunt test wherein two lead bars were
secured to the stationary brass bodies of the generator
assembly so as to measure the effect of shunting the field at
zones of maximum field potential. As contrasted with the
results of curve 2, superimposed thereon, a statistically as
well as visually significant difference is associated with the
experimental results which, realistically, may be attributed
to the shunting effect. The statistical study mentioned above
substantiates the distinguishable nature of the data groups
resulting in curves 2 and 5.

Curve 6 depicts the results
of a test run in which the field permeability has been
eliminated by removal from the test apparatus of the upper
mass member and the two detector conical pole faces. The lower
mass member has also been adjusted downward to as to rest on
the horizontal structural element 10. At the same time the
spatial relationship between the generator assembly and the
two differentially connected probes was not altered. As may be
observed from the curve 6, there occurred no change in the
thermal vibration of the InAs crystal lattice. The plot
scatter observable during the 45 minutes wheel spin period is
attributable to increased temperature gradients which
developed between the probes and the respective thermocouples
in the absence of the various filed circuit member thermal
masses.

Further experimental results
are available to substantiate the heretofore stated
conclusions concerning the operating characteristics of the
subject apparatus. In this respect reference is made to the
copending application of the present inventor entitled Method
& Apparatus for Generating a Secondary Gravitational Force
Field, field Nov. 4, 1968 and bearing Serial No. 773,051, the
subject of which concerns an apparatus for establishing a
time-variant kinemassic force field.

It will be apparent from the
foregoing description that there has been provided an
apparatus for generating and transforming kinemassic forces
due to a dynamic interaction field arising through
gravitational coupling of relatively moving bodies. Although
in its original application the kinemassic force has been
applied to the reduction of thermal vibrations in the lattice
structure of a crystal, it should be readily apparent that
other more significant uses of these forces are contemplated.
In this respect the principles of the present invention may
well be applied to any system in which bodies are
non-responsive or only partially responsive to conventional
forces such as electromagnetic force fields. Thus, the present
invention should have particular applicability to the
stabilization of plasma particles, pursuant to controlled
thermal nuclear fusion, or in the governing of temperatures
and thermal energies within matter.

While in accordance with the
provisions of the statutes, there has been illustrated and
described the best forms of the invention known, it will be
apparent to those skilled in the art that changes may be made
in the apparatus described without departing from the spirit
of the invention as set forth in the appended claims and that
in some cases, certain features of the invention may be used
to advantage without a corresponding use of other features.

Having now described the
invention, what is claimed as new and for which it is desired
to secure Letters Patent is:

(1) An energy generating and
transforming apparatus comprising a first member, said first
member further comprised of spin nuclei material and mounted
so as to be freely rotatable about an axis located within said
first member, at least one stationary member, said stationary
member comprised of spin nuclei material and positioned
immediately adjacent sad first member, and means for effecting
the rotation of said first member whereby it is effective in
impressing a non-electromagnetic force onto said stationary
member.

(2) A method for generating
a non-electromagnetic force field and for converting such
force field into useful work comprising the steps of mounting
a first member comprised of preferred material in a manner
which enables said first member to assume a degree of relative
motion with respect to a second member also comprised of
preferred material, establishing a degree of relative motion
between said first and second members, and sensing the
resultant energy due to the dynamic interaction of the
relatively moving members.

(3) The method of claim 2
wherein the sensing further comprises the steps of positioning
a member of preferred material within said non-electromagnetic
force field and measuring the change in the physical
characteristics thereof.

(4) An apparatus comprising
two U-shaped members of spin nuclei material, non-spin nuclei
material means for positioning said U-shaped members in
mirrored relationship with one another and separated by two
gaps, means including a freely rotatable member of spin nuclei
material mounted in one of said two gaps, means including a
detector mounted in the other one of said two gaps, and means
for effecting the rotation of said freely rotatable member
whereby a non-electromagnetic force is impressed upon said
detector.

(5) The apparatus of claim 4
wherein the detector positioned within the second of said two
gaps comprises a crystalline structure of spin nuclei material
such that the non-electromagnetic force impressed upon said
crystalline structure is effective in polarizing said spin
nuclei material sufficiently to reduce the specific heat
properties of the crystalline structure so as to effect a
substantial increase in the temperature thereof.

(6) An energy generating
apparatus comprising a first member, a second member, and
means for establishing relative motion between said first and
second members whereby a non-electromagnetic force is
generated within said first and second members de to the
dynamic interaction of said relatively moving members.

(7) An energy generating and
transforming apparatus comprising a mass circuit constructed
of spin nuclei material of half integral spin value, said mass
circuit having two gaps therein, field generating means
rotatably mounted in one of said mass circuit gaps, said field
generator means further comprising a frame for rotatably
mounting thereon a member comprising spin nuclei material of
half integral spin value, the axis of rotation of said
rotatable member lying in the plane of said mass circuit, said
pole pieces being disposed on said frame on opposite side of
said rotatable member, each pole piece presenting a generally
circular face in close proximity to but spaced from a face of
said rotatable member, said pole pieces being further
configured to substantially fill the gap in said mass circuit,
means for rotating the rotatable member of said field
generator means at high velocity, and means mounted in the
other gap of said mass circuit for detecting a field in said
circuit.

(8) An energy generating and
transforming apparatus comprising: a mass circuit of dense
material, and having two gaps therein, mounting means for said
mass circuit, mounting means having restricted contact area
with said mass circuit, field generator means rotatably
mounted in one of said mass circuit gaps; said generator means
further comprising a frame, a rotatable member mounted on said
frame for rotation, the axis of rotation of said rotatable
member lying in a plane of said of said mass circuit
throughout all relative positions of said frame, a pair of
pole pieces mounted on said frame by mounting means
establishing restricted contact area between each pole piece
and said frame, said pole pieces being further configured to
substantially fill the gap in said mass circuit, means for
rotating the rotatable member of said generator means at high
velocity, an means mounted in the other gap of said mass
circuit for demonstrating a change in physical characteristics
within said gap region due to the field generated within said
mass circuit.

(9) The apparatus of claim
8, wherein said means mounted in the other gap of said mass
circuit comprises a member whose atomic structure is such that
it is affected by said field generated within said mass
circuit.

(10) A method for
controlling the temperature in a crystalline structure by
subjecting the crystalline structure to non-electromagnetic
forces capable of altering the specific heat properties
thereof, including the steps of: connecting in field series
relation a mass circuit constructed of dense spin nuclei
material of half integral spin value, a field generator
constructed essentially of spin nuclei material having a half
integral spin value and rotatably mounted in one of said mass
circuit gaps, and a crystalline structure also of spin nuclei
material having a half integral spin value positioned in the
other of said mass circuit gaps; initiating the rotation of
said field generator whereby the external angular momentum of
spin nuclei material within said rotating field generator
interacts with inertial space to effect the polarization of
the spin nuclei thereof, resulting in turn in a net component
of angular momentum which dynamically interacts with the spin
nuclei of the mass circuit thereby further polarizing the
nuclei of the material therein; and concentrating the
resultant field within said field series circuit onto said
crystalline structure within the second of said mass circuit
gaps whereby the spin nuclei material of said crystalline
structure is sufficiently polarized to reduce the specific
heat properties of the crystalline material due to a reduction
in degrees of freedom of the lattice vibrations thereby
effecting a substantial temperature increase in the body
thereof.

---

**US Patent # 3,823,570**

**Heat
Pump**

**Henry W. Wallace**

July 16, 1974   
US Cl. 62/56, 62/3, 62/467,
35/15   
Intl. Cl. F25d

**Abstract --** Method
& Apparatus for utilizing for the purpose of heat flow by
means of controlled temperature change a field energy, other
than electric, magnetic or gravitational field energies,
capable of reducing the specific heat properties of a broad
class of substances.

**Description**

The present invention
pertains to manipulation of atomic nuclear structure so as to
modify the state of an energy transfer medium, and utilization
of the modified medium. More particularly, the invention
pertain to effecting reorientation of nucleons of a material
whose spin number (1) is half-integral, and imposing the
effect of such orientation on a medium adapted to do
productive work.

In the past century great
strides have been made in harnessing the three degrees of
translational movement of electrons in the electromagnetic
regime. Very little if anything has been done to utilize the
inertial regime comprising the relatively massive nucleons,
and particularly the three degrees of rotational freedom
thereof, one of which is preempted by nuclear spin.

In my US Patent # 3,626,606,
I demonstrated how, by applying a rotational force to material
whose nuclear spin number (I) is half-integral, a
reorientation can be achieved in the nuclear structure. In my
US Patent # 3,626,605, I demonstrated how a time variant may
be imposed on the output resulting from such reorientation.

It immediately becomes
evident that there are potentially many, many uses of these
reoriented nucleons. In all probability, techniques will be
found which t some extent parallel those employed for
utilization of the electron in the electromagnetic field, and
it becomes clear that the thus reoriented nuclear structure
may lend itself to such uses as modification of the
gravitational field acting on a body so as to alter its
gravitational attraction toward another body, separation of
isotopes by distinguishing between nuclei according to their
nucleon content, generating of gravity waves for communication
and other energy transfer, stabilizing of plasma and
maintenance of plasma density for controlled nuclear fusion,
possible harnessing of cosmic gravitational energy in addition
to utilization in many, many other fields.

For purposes of
demonstration the utilization of the inventio0n in heat pumps
will be explained. For brevity, material whose spin number (I)
is half-integral will be referred to hereafter as "spin nuclei
material". As in US Patent # 3,626,605 and 3,636,606, the
generated field will be referred to as a "kinemassic field".

The Spin Values (I) for the
isotopic forms of the elements are well known and may be found
in tabular form, for example, "The NMR Table, 5th Edition"
published by Varian Associates of Palo Alto, CA. Typical among
substances in elemental form having such half integral spin
values are beryllium with a neutron spin of I - 3/2, aluminum
with a proton spin of I = 5/2, chlorine of which both isotopes
provide proton spins of I -3/2, vanadium (useful for alloys)
of which one isotope of 99.76% abundance provides a proton
spin of I = 7/2, cobalt with a proton spin of I - 7/2, copper
of which both isotopes provide spin of I = 3/2, and bromine of
which both isotopes provide spins of I = 3/2. These chemical
elements and others of half integral spin values may be
alloyed together as well as to elements possessing no-spin and
integral spin nuclei provided quantity percentages of such
additional elements are small.

In US Patent # 3,626,606 it
was explained that the kinemassic force resulting from this
dynamic interaction of relatively moving bodies of spin nuclei
material can be utilized for temperature control purposes
including the specific application of such kinemassic forces
to the control of lattice vibrations within a crystalline
structure thereby establishing an appreciable temperature
reduction, these principles being useful, for example, in the
design of a heat pump.

The half-integral spin
nucleus of this spin nuclei material is characterized by
possession of an odd nucleon, either neutron or proton, which
is consequently unpaired. The remainder of the nucleons of
such a half-integral spin nucleus are acted upon by both the
short-range force and the weaker long-range force which
together constitute the nuclear binding force. The unpaired
nucleon is acted upon only by the weaker long-range force and
it is the energy of the absent short-range force
characterizing the half-integral spin nucleus contained
therein due to their absent short-range force nuclear energy
causing an available, responsive energy, this polarization
resulting in a diminishing of the lattice vibrations within
said crystalline structure.

The kinemassic field may be
utilized in static form for reducing the specific heat of such
spin nuclei material. Establishing of this static field energy
within said atomic structure effectively reduces its specific
heat capacity concomitantly causing a controlled temperature
increase therein due to the presence of the substance's
enthalpy content. Concomitantly there is caused to occur a
decrease of temperature which is possessed prior to
application of the static field energy. This below-ambient
temperature is caused by the now-reduced enthalpy content
which resulted from the heat flow away from the substance
which had occurred when it contained the static field energy.
As a consequence heat now flows back into this substance from
the ambient substance of higher temperature.

It is provided for in this
invention that the substance, with its controllable specific
heat property, be capable of physical transport from one
spatial location to another. However, for the following
explanation these locations will be limited to two in number.
For both spatial locations, the ambient substance possesses an
adequate thermal conductivity property. If now the static
field energy is caused to be present within the transportable
substance of controlled variable specific heat property, when
at the first of these spatial locations but removed from this
substance when it has been transported to the second of these
locations, it is evident that heat flow from the transportable
substance into the ambient substance will always occur at the
first location identified by the presence of the static field
energy and that heat flow from the ambient substance into the
transportable substance will always occur at the second
location identified by the absence of the static field energy.
It is then apparent that the transported substance of spin
nuclei material alternately and cyclically experiences
temperature changes such that, at the designated first
location, its temperature exists at a value higher than that
of the temperature of the ambient substance and also, at the
designated location, that its temperature exists at a lower
value than that of the temperature of the ambient substance.
This one-way heat flow from the transported substance into the
ambient substance of the designated first location in
combination with the one-way heat flow from the ambient
substance of the designated second location into the
transported substance, this dual heat flow phenomenon, then
constitutes a heat pump.

Although several techniques
are known for altering specific heat, such as changing the
density of a gas, the technique utilized in this invention
concerns the limiting of the degrees of freedom of particle
vibration of a substance by means of a static energy field.
More specifically, consider the thermal vibration of a crystal
structure. The assembly of atoms bound together by local
atomic forces, composing a crystal lattice, is capable of
vibrating in a large number of independent normal modes about
a static equilibrium configuration. In these vibrations a
large portion of the enthalpy is stored; these vibrations are
the major contribution to the structure's specific heat.

One object of this invention
is to utilize the so-called kinemassic force to alter the
energy state of a relatively movable medium.

A further object of the
invention is to condition spin nuclei material so that it will
alternately cause heat to flow out of it and into it by means
of a temperature change.

A further object is to
utilize the kinemassic force field concept in a heat pump.

According to the present
invention there is provided a method of modifying the energy
state of a relatively movable transfer medium, which comprises
applying to a material whose nuclear spin number (I) is
half-integral a force which reorients nucleons thereof,
exerting on a transfer device a force resulting from said
orientation, and exposing said relatively movable transfer
medium to said device to effect said modification of the
energy state of said medium.

The invention also provides
a heat pump comprising a rapidly rotatable generator formed of
spin nuclei material closely juxtaposed to said generator and
forming therewith a closed field circuit, and heat transfer
means formed of spin nuclei material and adapted to move
through the vicinity of said relatively stationary body
whereby the specific heat of said heat transfer means is
altered to accomplish useful work.

In order that the disclosure
will be more fully understood and readily carried into effect,
the following detailed description is given with reference to
the accompanying drawings in which:

Figure 1 is an end view,
with housing partly removed, of a heat pump according to the
present invention.

![](0001a.jpg)

Figure 2 is a side view,
with housing partly removed, of the heat pump shown in Figure
1.

![](0002.jpg)

Figure 3 is a sectional view
taken along the line 3-3 of Figure 2.

![](0003.jpg)

Figure 4 is an end view,
with housing partly removed, of the heat pump shown in Figure
1.

![](0004.jpg)

Figure 5 is a sectional side
view taken along line 5-5 of Figure 4.

![](0005.jpg)

Figure 5A is a detailed view
of a portion of Figure 5.

![](0005a.jpg)

Figure 5B is a parallel
perspective view of a component part of Figure 5.


![](0005b.jpg)

Figure 6, 7, 8 and 9 show
respectively top, front, side and rear views of symmetrical
field circuit segments employed in the embodiment of Figures 4
and 5.

![](0006.jpg)![](0007.jpg)![](0008.jpg)![](0009.jpg)

Figure 10 is an end view of
a further modification of the invention.

![](00010.jpg)

Figure 11 is a sectional
view taken along the line 11-11 of Figure 10, and

![](00011.jpg)

Figure 12 is a detailed view
of one aspect of the eccentric adjustment.

![](00012.jpg)

Figures 1 to 3 show a
solid-state heat pump. As disclosed in Figures 1 and 2,
housing 1 encloses a duct system 2. Air or other fluid is
conducted through inlet 3 and into blower 4. Air under
pressure emerging from blower 4 is conducted to manifold 5
where it is divided into two air streams, one of which flows
through lower duct 6 to reduced-temperature heat flow zone 7
and then to exhaust outlet 8. The other stream of air from
manifold 5 flows upwardly through upper duct 9 to
increased-temperature heat flow zone 10 and then to exhaust
outlet 11.

The kinemassic force, which
is utilized in accordance with the invention to effect the
desired heat flow is generated in a kinemassic generator rotor
20. Portions of an upper field circuit segment 21 and a lower
field circuit segment 22 are juxtaposed to rotor 20 to form
therewith a part of a kinemassic field circuit. At the
increased temperature heat flow zone 10 a heat flow is
effected with air or other fluid as hereinafter described.

To achieve this heat flow,
an enthalpy transfer ring 25 is rotatable on a shaft 26 driven
by a belt 27 through a pulley 28 mounted on said shaft 26.
Said belt 27, in turn, is driven by a pulley 29 mounted on a
shaft 30 forming a part of a gear reduction assembly 31.
Blower 4 is driven by blower motor 32 which is also connected
to a rotor shaft 33 (Figure 3) and worm gear 34 through a worm
wheel 35 which is integral with a second worm gear 35 which is
integral with a second worm gear 34a which, in turn, drives a
worm wheel 35a connected to shaft 30.

As seen in Figure 3 the
kinemassic generator rotor 20 includes a generator drive motor
40 which, in the present embodiment, is shown as an inside-out
electric motor having shaft 41 mounted integrally on upper
field circuit segment 21. The motor may, for example, be a
hysteresis type motor and driven by a solid stage
frequency-controlled source.

The outer housing 42 of
drive motor 40 is adapted to rotate and has integrally mounted
thereon a cylindrical generator rotor member 43 formed of spin
nuclei-containing material. Drive motor 40 is adapted to
rotate cylindrical generator rotor member 43 at extremely high
rates of rotation. The kinemotive force generated is a direct
function of rate of rotation, so that it is desirable to
achieve the highest rate of rotation compatible with the
permissible stresses in the system. These stresses vary with
the physical size and proportions of said cylindrical
generator rotor member 43 and the material of which it is
composed. Such rates of rotation can range from approximately
30,000 rpm to values of 100,000 rpm or greater, the lower
limit preferably being in the neighborhood of 50,000 rpm.

Cylindrical generator rotor
member 43 is formed with a flat pole face surfaces identified
as generator lower pole-face 44 and generator upper pole-face
45 at its lower and upper ends respectively which are
juxtaposed to flat pole face surfaces identified as lower
field pole-face 46 and upper field pole-face 47 forming a part
respectively of lower field circuit segment 22 and upper field
circuit segment 21. It is essential to maintain air gaps of
minimum width between pole face surfaces 44, 46 and between
pole face surfaces 45, 47 in order to provide maximum
kinemassic field permeability as well as to optimize the
secondary interaction of kinemassic field generating.

The upper and lower field
circuit segments 21 and 22 are formed of spin
nuclei-containing material and each terminates adjacent
enthalpy transfer ring 25 as upper enthalpy transfer pole-face
48 and lower enthalpy transfer pole face 49, respectively. The
pole faces 48 and 49 are cylindrical surface segments and are
equal in surface area. As seen in Figures 1 and 2, these
respective pole faces 48 and 49 so encompass a portion of
enthalpy transfer ring 25. In order to minimize reluctance,
the respective air gaps formed by pole faces 48 and 49 and the
juxtaposed portion of enthalpy transfer ring 25 should be of
minimum air gap width.

Enthalpy transfer ring 25 is
provided with a multiplicity of enthalpy transfer surfaces
which may be in the form of tubular channels 55 which, in
part, function to increase the enthalpy transfer surface area
resulting in greater heat flow between the enthalpy transfer
ring 25 and an enthalpy transfer fluid which is caused by
blower 4 to flow through duct 9, through these tubular
channels 55 and then to exhaust outlet 11. The tubular
channels 55, only a few typical ones of which are shown, have
a second function of reducing the cross-sectional area of a
kinemassic field circuit in the increased-temperature heat
flow zone 10 in order to increase the flux density within the
permeable portion of ring 25 within zone 10 while imparting a
minimum increased reluctance to the overall field circuit.
This increased flux density within the permeable portion of
ring 25 within zone 10 results in greater reduction of the
specific heat of ring 25 within zone 10. The tubular channels
55 may be variously configured and distributed to achieve the
foregoing results.

End plate 60 may be
accurately pinned then bolted to circuit segments 21 and 22 to
maintain the air gaps in position and to support segment 22.
Also, connecting block 61 is provided at an intermediate
position between segments 21 and 22 for the same purpose.

In operation, after the
kinemassic generator rotor 20 has been caused to spin at a
high rate of rotation, air fed through inlet 3 I propelled by
blower 4 to manifold 5 where it is subdivided into a lower
stream flowing through duct 6 and an upper stream flowing
through duct 9.

The enthalpy transfer ting
25, which rotates at a suitably low speed, for example, 1 rpm,
will undergo a reduction in specific heat in any given portion
and then under the influence of the kinemassic force extending
between pole faces 48 and 49. The air passing through upper
duct 9 will be forced through those tubular channels 55 which
are at the instant in the increased-temperature heat flow zone
10 adjacent pole pieces 48 and 49 with the result that the air
will experience a temperature rise occurring in said given
portion of enthalpy transfer ring 25 due to the reduction of
its specific heat arising from the polarization of its spin
nuclei under the influence of the kinemassic force, whereby
the air which emerges from exhaust outlet 11 will possess a
temperature higher than its temperature possessed when it
previously flowed through duct 9.

As enthalpy transfer ring 25
continues to rotate, so that said portion thereof departs from
the spin nuclei polarizing effect of the kinemassic field flux
lines of zone 10, the specific heat will increase again to its
normal value thereby causing the temperature of said given
portion to drop below that value existent prior to entering
zone 10 because of the reduced enthalpy now contained therein.
The lower stream of air is forced from duct 6 through those
tubular channels 55 in the reduced-temperature heat flow zone
7 with the result that said given portion of enthalpy transfer
ring 25, due to its changed state of increased specific heat,
will absorb heat from the ambient flowing air, as said given
portion of ring 25 reaches zone 7, the result being that the
air emerges from outlet 8 with a temperature lower than that
temperature possessed when it was flowing through duct 6. IT
will be noted, as can be seen from Figure 2, that the
increased-temperature heat flow zone 10 is offset, with
respect to the vertical, from reduced-temperature heat flow
zone 7, this offsetting being desirable for optimum
coordination of the specific heat reduction and recovery times
respectively of the chosen material forming ring 25 in its
passage into and from the zone 10. The positions and
configuration of zones 7 and 10 may be varied depending on the
specific heat properties of the material forming ring 25.

Turning now to the
embodiment of Figures 4 to 9, the same reference numbers have
been used, so far as possible, as in Figures 1 to 3 but with
primes. The housing 1' encloses a duct system comprising an
inlet duct 3', best shown in Figure 5, which leads air to a
rotary blower 4' mounted on rotor shaft 33' driven by blower
motor 32' through, but bypassing, a drive unit 31' which may
be, if desired and as shown, in the form of a harmonic drive
unit manufactured by USM Corporation of Shelton, CT.

An enthalpy transfer ring
25' is also mounted for rotation about rotor shaft 33', and is
driven by blower motor 32' through drive unit 31' in
counter-rotation to rotary blower 4'. While the rate of
rotation of rotary blower 4' is preferably between 1745 and
3500 rpm, the rate of counter-rotation of enthalpy transfer
ring 25' is relatively slow, for example, one to several rpm.
A reduced-temperature duct 6' for leading cooled air from the
system to an exhaust 8' is formed by upper baffle 6a and lower
baffle 6b and side baffle 6c as shown in Figure 4 and another
similar side baffle (not shown), the width of duct 6' being
sufficient to snugly overlap enthalpy transfer ring 25'.
Similarly, an increased-temperature duct 9' for leading heated
air from the system to an exhaust 11' is formed by upper
baffle 9a, lower baffle 9b, side baffle 9c, and another side
baffle (not shown), the width of duct 9' also being sufficient
to snugly overlap enthalpy transfer ring 25'.

Kinemassic generator rotor
20' is provided for generating the desired kinemassic force.
As seen in Figures 5 and 5A, the rotor 20' includes a
generator drive motor 40' which may be of the so-called
"inside-out" type having a stationary shaft 41' on which is
mounted a winding 41a. The drive motor 40' may be powered by a
generator or solid-state frequency converter (not shown)
preferably with an output frequency of approximately 1234 cps.
In this embodiment an oil mist supply (also not shown) should
be provided for bearing lubrication). The oil mist can, for
example, be delivered by a small size air compressor unit.
Concentrically mounted on shaft 41' is a rotatable outer iron
rotor and conductor cage 42' fitted into housing 42" of
generator drive motor 40'. Integrally mounted on said
rotatable iron rotor and outer conductor cage 42' is a
cylindrical generator rotor member 43' formed of spin-nuclei
containing material. Cylindrical generator member 43' is
formed with flat pole faces 44' and 45'. Juxtaposed thereto
are flat field pole faces 46' and 47' of field circuit
segments 21' and 22' formed of spin-nuclei containing material
and adapted to provide a path for kinemassic flux between
generator rotor member 43' and transfer ring 25'. It is
essential to maintain air gaps of minimum width between
pole-face surfaces 44', 47' and between pole-face surfaces
45', 46' in order to provide maximum kinemassic field circuit
permeability, the width of the air gaps in the drawings being
exaggerated for clarity.

The rotor 20' is provided
with an axial cylindrical recess 20a adapted to mate with
axial cylindrical recesses 23' provided in the field circuit
segments 21' and 22' being beveled as shown in Figure 5.
Fitted into each of the recesses 23' are respective shaft
mounts 50' which non-rotatably secure the shaft 41' to
segments 21' and 22', the motor 40' fitting firmly within
axial cylindrical recess 20a. The motor 40' may, for example,
be a hysteresis type motor driven by a solid-state frequency
controlled source. The outer iron rotor and conductor cage 42'
of motor 40' rotates about the stationary motor shaft 41'
through its mounting on generator drive motor bearings 51' of
which there are a pair but only one of which is shown. A
concentric bearing block 53' associated with each of the
bearings 51' contain s in the illustrated block the power
leads for the generator drive motor 40' through power lead
channel 52'.

The identical first and
second field circuit segments 21' and 22' each terminate
adjacent enthalpy transfer ring 25' as first enthalpy transfer
pole-face 48' and second enthalpy transfer pole-face 49'
respectively. The first enthalpy transfer pole-face 48' and
the second enthalpy transfer pole-face 49', in this
embodiment, are identical in configuration and having flat
surfaces and are of hollow circular segment form as best shown
in Figures 6 to 9. As seen in Figures 4 and 5, these
respective pole-faces 48' and 49' so encompass a portion of
enthalpy transfer ring 25' about portions of its flange
surfaces that they provide for minimum kinemassic reluctance
of the flux lines passing through that portion of enthalpy
transfer ring 25'. The respective air gaps formed by
pole-faces 48' and 49' and the adjacent flanges of enthalpy
transfer ring 25' should be of minimum width. Enthalpy
transfer ring 25' is provided with a multiplicity of enthalpy
transfer channels which may be in the form of involute
channels 55', the involute surfaces of which may be described
by the x,y coordinate equations:

x - a cos o + a o sin o and
y = a sm o - a o cos o

where "a" is the inner
radius of the enthalpy transfer ring 25' and o is the polar
angle described between the starting point and tangent point
of a string which is kept taut while being unwound from a
cylindrical surface of radius "a", the curve formed by the
string end describing the involute surface of the channel.
Such an involute channel in conjunction with the
counter-rotating relation between blower 4' and enthalpy
transfer ring 25' serve to enhance the enthalpy transfer
effect between involute surface and the fluid due to the
surface impingement arising from the angular paths required of
the fluid particles. More important, the involute channels 55'
permit a uniform cross-section of field permeable material
distribution from inner radius to outer radius of the enthalpy
transfer ring 25' while also causing the kinemassic field flux
density increase described for the first embodiment.

As shown in Figure 4, the
periphery of blower 4' is partially surrounded by fixed
shrouds 5a and an adjustable shroud 5b adapted to control the
amount of air flowing into ducts 6' and 9'. The adjustable
shroud 5b is attached by bolt and slot connections to the
housing of blower 4'. The adjustable shroud 5b is integral
with inlet sleeve 5c as shown in Figure 5B in parallel
perspective. Inlet sleeve 5c is designed to concentrically
nest, in a rotatable sliding relation, within inlet duct 3' as
shown in Figure 5. Flange 5d of inlet sleeve 5c possesses an
arc slot 5e of a sufficient number of angular degrees that, in
conjunction with a bolt stud 5f secured to housing 1' and
extending through arc slot 5e in combination with wing nut 5g,
adjustable shroud 5b can be fixed in any required angular
orientation so as to apportion the air flow in cooperation
with shrouds 5a into ducts 6' and 9'.

In operation air under
pressure emerging from blower 4' is divided into two air
streams by means of the shrouds 5a and 5b. One air stream
flows directly into a reduced-temperature enthalpy transfer
zone 7' and then through reduced-temperature duct 6' to
exhaust 8'. The second air stream flows directly into
increased-temperature enthalpy transfer zone 10' and then
through increased-temperature duct 9' to exhaust 11'. The
fixed shrouds 5a are carefully positioned for directing the
air into the two enthalpy transfer zones 7' and 10'. The
number of involute channels 55' which are effective at any one
time to pass air through enthalpy transfer zones 7' and 10'
can be adjusted by varying the setting of movable shroud 5b.
By adjusting said shroud 5b so as to reduce the air flow rate
through the reduced-temperature enthalpy transfer zone 7',
while simultaneously increasing air flow rate through the
increased-temperature enthalpy transfer zone 10', a lesser
amount of enthalpy will be transferred out of said ring within
the increased-temperature enthalpy transfer zone 10', thus
resulting in a gradually increasing enthalpy deficit in
enthalpy transfer ring 25'. This will then cause the mean
temperature of the enthalpy transfer ring 25' to reduce until
there is no longer an imbalance between the rate of enthalpy
introduced and the rate of enthalpy removed from enthalpy
transfer ring 25'. Thus, there is provided a self-stabilizing
system since the temperature difference between the ambient
temperature air, arriving through inlet duct 3' into the
involute channels 55' within the increased-temperature
enthalpy transfer zone 10', and the surface temperature of the
involute channels 55' will diminish as the average temperature
of the enthalpy transfer ring 25' reduces.

The extremes of temperature
difference of enthalpy transfer ring 25', occurring between
the maximum existent in those involute channels 55' located in
enthalpy transfer zone 10' and the minimum existent in those
involute channels 55' located in the enthalpy transfer zone
7', not only are dependent upon their temperature values above
0 deg K as reflected by the average temperature of enthalpy
transfer ring 25', but also by the particular half-integral
spin nuclei utilized in the enthalpy transfer ring 25'. These
temperature differences are therefore limited and consequently
determined by the temperature at which self-stabilization will
occur as exemplified by that state where the temperature of
the air or other fluid entering inlet duct 3' is of the same
value as that temperature of the involute channels 55' located
in the enthalpy zone 10'. That temperature at which
self-stabilization occurs can be significantly lowered by
returning to inlet duct 3', by means of commonplace ducting
and therefore not shown, a portion of the lower temperature
air leaving reduced-temperature duct 6' to exhaust 8'. Thus
the average temperature of enthalpy transfer ring 25' can be
lowered to a value considerably greater than that temperature
difference existent in enthalpy transfer ring 25' between its
maximum and minimum values at any moment of time.

It is therefore significant
to note that a reduction of the enthalpy transfer ring 25 or
25' mean temperature of from 70 deg to 35 deg F represents a
reduction of only 6.6% with respect to 0 deg K and that this
technique of heat pumping via cyclic changing of a material
specific heat by way of the kinemassic field force is not
restricted to a narrow temperature range as is the case in the
conventional heat pump with its narrow limits of
temperature-pressure parameters required for boiling and
condensing states. For example, the temperature difference
between the inflowing air or other fluid entering inlet duct
3' and the outgoing air or fluid leaving exhaust 8' can thus
be increased by adjusting the blower motor movable shroud 5b,
or by other equivalent controls, so as to reduce the air or
fluid rate of flow through those involute channels 55' located
within the reduced-temperature enthalpy transfer zone 7' and
simultaneously increasing the air or fluid rate through those
involute channels located within the increased-temperature
enthalpy transfer zone 10' while causing the temperature of
the outgoing air or other fluid of exhaust 8' to be
progressively lowered by means of the reintroduction of a
portion of this reduced-temperature air or other fluid of
exhaust 8' back into the inlet duct 3'.

Conversely, if it is desired
to increase the air or fluid temperature difference between
the inflowing air or fluid entering inlet duct 3' and the
outgoing air or fluid leaving increased-temperature duct 9'
while progressively increasing the temperature of the outgoing
air or other fluid of exhaust 11', the blower motor movable
shroud 5b is adjusted so as to reduce the air or fluid flow
rate through the increased-temperature enthalpy transfer zone
10' and simultaneously increasing the air or fluid flow rate
through the decreased-temperature enthalpy transfer zone 7'
while reintroducing a portion of this increased-temperature
air or other fluid of exhaust 11' back into inlet duct 3',
this resulting in a mean temperature increase of the enthalpy
transfer ring 25'.

Blower motor movable shroud
5b may also be adjusted by a temperature-responsive servo
drive system of conventional design and therefore not shown,
which is temperature sensitive to the air or other fluid
leaving exhaust 8' or to that of an enclosure, whose
temperature is being controlled by this air or other fluid,
thus providing an especially effective means of removing
enthalpy from a solid or fluid through a broad temperature
range. Such a conventional servo system can also be applied to
the air or other fluid leaving exhaust 11' or elsewhere that
temperature feedback is possible in order more effectively to
establish and control elevated temperatures. Where system
performance is closely repeatable, a simple time-controlled
mechanism may be substituted for either servo system
application in driving the blower motor movable shroud 5b.

Referring to the embodiment
shown in Figures 10, 11 and 12 a modified kinemassic force
generator system is shown to demonstrate advantages to be
gained by the presence of additional, usable spin nuclei
material at lesser inner diameters occupied by the generator
drive motors 40 and 40' in the other embodiments and by
increasing in the axial direction the length of the generator
rotor 20", such increase being possible without adding to the
centrifugal force on the material forming the generator rotor
20" thereby causing a kinemotive force of greater magnitude to
occur for a given set of air gaps formed between a generator
rotor 20" and field circuit segments 21" and 22".

Field circuit segments 21"
and 22" are shown juxtaposed to end surfaces of generator
rotor 20' in a manner similar to the juxtaposition of segments
21' and 22' to generator 20' in Figure 5. Field circuit
segment 21" is shown in fragmentary form in Figure 10 to
indicate that various uses may be made of the output of
generator rotor 20". For example, by suitable configuration of
segments 21" and 22" the kinemassic force may be led to a
transfer ring such as transfer ring 25' of Figure 4.

In the present embodiment,
generator drive motor 40" drives a spindle 60" through the
intermediary of a belt 61", said spindle 60" being rotatable
in suitable bearing assemblies 62" and 63". Mounted at the end
of spindle 60" opposite belt 61" is a drive pulley 64" which
is connected by a belt 65" to a driven pulley 66" secured to a
drive shaft 67" adapted to rotate generator rotor 20". Drive
shaft 67" is rotatably mounted in suitable bearing assemblies
68" and 69" supported in a generator drive chassis 70"
together with bearing assemblies 62" and 63".

Typical specifications for
generator rotor 20" may be that it be formed of aluminum alloy
with 15.24 cm outside diameter and 20.32 cm axial length.
Shaft 67" may be of steel with 19 mm outside diameter. Shaft
67" may be push-fit and secured to generator rotor 20" with an
epoxy adhesive. Generator rotor 20" may be designed to rotate
at 48,300 rpm. To achieve this angular velocity, drive motor
40" may be a one-sixth HP capacitor start, induction run type
115 VAC single phase 3450 rpm rated motor.

The spindle 60" may be
provided with a pulley section 72" adapted to be rotationally
engaged by belt 61". Pulley 74" driven by motor 40" and
adapted to drive belt 61" may be a low-speed 8.89 cm diameter
minimal crown type. Belt 61" may be of seamless polyflex
material. The outside diameter of pulley section 72" may be
2.54 cm thus providing a 3.5 to 1 ratio between pulley section
72" and pulley 74". Thus, spindle 60" will be driven at 12,075
rpm.

Pulley 64" may be of
intermediate-speed 10.2 cm diameter minimal crown type. Pulley
66" may be of high-speed 2.54 cm diameter type, thus providing
a 4 to 1 ratio between pulley 66" and pulley 64".

The field circuit segments
21" and 22" may be formed of cast aluminum. The air gaps
between segments 21" and 22" and generator 20" should
advantageously be held to 0.005 mm., but are exaggerated for
clarity. Chamfers 76" on each end of generator 20" should be
45 deg x 1.6 mm.

The driving pulley 64" may
be secured to spindle 60" by cap lock nut 78". Bearing
assemblies 62" and 63" may each be provided with eccentric
rollers 80" adapted to be adjusted by pin sets 81" and 82" for
belt tension control as shown in Figure 12. Pin sets 81" and
82", only one set being depicted in Figure 12, assure equal
degrees of eccentricity adjustment of eccentric collars 80"
thus maintaining a parallel orientation between the respective
axes of spindle 60" and drive shaft 67" while adjusting their
separation distance for the purpose of tension control of belt
65". After such adjustment, pin sets 81" and 82" are removed
and the proper tensioning of belt 61" is caused by means of
laterally moving the generator drive motor 40" with respect to
generator drive chassis 70" by conventional means. Bearing
assembly 63" is provided with bearing thrust cap 83". Bearing
assembly 62" is provided with spring thrust cap 84" and thrust
spring 85" which may be a disc-type spring.

Bearing assembly 68" may be
provided with spring positioning cap 88" and thrust spring 89
which may be a disc-type spring. Bearing assembly 69" may be
provided with bearing positioning cap 90" and bearing
assemblies 63" and 69" may each be longitudinally adjusted
with shims 91" and 92" which may be of ground plate and/or
shim stock.

It has thus been
demonstrated how the energy characterizing the half-integral
spin nucleus can be utilized in a heat pump by altering the
degrees of freedom of the crystal lattice structure. It is
interesting to note that the assembly of atoms bound together
by local inter-atomic forces to make up this crystal lattice
structure is capable of vibration in a large number of
independent normal modes about the static equilibrium
configuration. In these vibrations is stored a large portion
of the enthalpy of the solid, and hence the vibrations are
believed to make the major contribution to the specific heat.
The vibrational energy is quantized so there is recognized to
be some zero-point motion even at 0 deg K.

While the inventive concept
has been specifically demonstrated as applied to utilization
in heat pumps, it will now be evident that the energy which
characterizes the half-integral spin nucleus in fact provides
a generally usable new tool for producing interactions among
atomic structures and is in no way limited or restricted to
such use in heat pumps or similar devices.

I claim: [ Claims not
included here ]

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