Thermalloy US Patent # 2,796,345 ~ Samuel Freedman

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**Samuel FREEDMAN**

**Chemalloy**

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Like Eugene Anderson's "CB II" alloy (which is
dubiously claimed to catalyze the decomposition of water ---
eyewitnesses have stated that the pieces of alloy appear to be
diminished after the demonstrations), Chemalloy also generates
hydrogen/oxygen gases, though catalysis has not been claimed
for it. Chemalloy has several other unique properties, and the
preparation has a distinct "alchemical" flavor to it. Very
interesting stuff...

**[S. Freedman: Science &
Mechanics (1960s)](#scimech)**

**[USP # 2,796,345: Process
of Producing Lead-Zinc Alloys](#2796345)**

**[USP # 2,927,856:
Multi-Purpose Alloys of Controlled Homogeneity](#2927856)**

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***Science and Mechanics*** (early
1960's.) ~ *Provenance*: Transmitted by Alex Peterson to
Peter Lindemann, who shared it at the KeelyNet Convergence
2001 conference; the text below is provided by Dan York.
Posted on KeelyNet June 25, 2001 and transcribed from scans
sent by Dr Lindemann to Rex Research.

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**"CHEMALLOY --- A
New Alloy for the Science Student"**

**by**

**Samuel Freedman**

Originally conceived as a soldering alloy, this
patented substance has anti-friction properties, will aerate
soil, improves seed germination, stimulates pant growth, will
generate electricity, and ????

What relation there can be between soldering
aluminum and promoting the growth of huckleberries is hard to
see --- yet in the broadest view, scientists say, all things
are in some way interrelated. Chemalloy, with its strangely
diverse properties seems to support this view.

Put a Chemalloy rod in plain water (Fig.1) and
you have a battery of 0.55 volt potential that will last as
long as the rod is kept wet, generating enough power to
operate a voltmeter, milliameter or oscilloscope. In different
liquids, voltage varies from almost zero for petroleum to 1.1
for certain types of chili sauce.

![](1chem1.jpg)

As a bearing material, Chemalloy in a solid dry
state withstands friction without coolant or lubricant.

Chemalloy powderized to about 1,000,000
particles per pound exhibits the same elecritical properties
(Fig. 2) as the solid rod. Here it generates slightly more
than 0.5 volt, and in addition decomposes the water,
liberating hydrogen.

This process is further examined in Fig 3. First
fill three graduated cylinders with water, one cold, the
second warm, and the third hot. Add equal amounts of Chemalloy
to each graduated cylinder. Instantly, the graduated cylinder
containing hot water liberates hydrogen (Fig. 3A).

![](1chem2.jpg)

Heat is generated by the reaction so that with
the passage of a few minutes (Figs. 3B and C) the three
graduated cylinders are equally warm and hydrogen production
in all three is the same.

One of the most significant uses of powdered
Chemalloy may be the warming and loosening of soils that are
too cold or compact for optimum seed generation and plant
growth. The warming and areation of soil on a laboratory basis
is shown in Fig. 4. A sample of dry soil is placed on top of
powdered Chemalloy in a glass case. Note the temperature rise
from 94o F. to 126o F. Voltage remains approximately at 0.6.

![](1chem3.jpg)

From this point on, voltage will remain
constant, but soil temperature will decline and finally
stabilize at a point a few degrees above the environmental
temperature. The electrical action will continue and will
generate warmth at this reduced magnitude. To date, the
capability of Chemalloy to generate electricity in water has
been observed for seven continuous years, and no limit is
known. The liquid, rather than the metal is the substance
which is consumed and must be replaced.

A Provincial Horticulture Station in Alberta,
Canada, summarizes an experiment in seed germination as
follows:

                        
%germinated            
%germinated
  
Vegetable         
(Chem.
Treated)         
(untreated)   
Cucumber                   
50                     
16
  
Red
Beet                     
96                     
70
  
Lettuce                        
64                     
34
  
Leek                           
86                     
54
  
Carrot                         
68                     
32

The assistant superintendent supervising this
experiment stated that the addition of Chemalloy powder
resulted in speedier germination of seeds as well as larger
percentages germinated. Initial growth of the plants after
emergence was also more rapid in the case of treated seeds.

For field crops, Chemalloy is applied at the
rate of one to five pounds per acre, in the row or hill with
the seeds. It is not broadcast over the entire field area, as
this would waste material. It needs to be buried where it will
be in contact with soil moisture since it is inert when dry.

The peach and nectarine trees in Fig. 5 were
planted in poor compact clay soil in El Cajon, Calif., and
stands in sharp contrast to anything else in the area having
grown in 1-1/2 years to the height shown from 1-in. diameter
stubs.

![](1chem5.jpg)

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![](1chem6.jpg)

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**US Patent #
2,796,345**

**Process of Producing Lead-Zinc Alloys**

**(June 18, 1957)**

**Samuel Freedman**

This invention relates to welding or soldering
alloysand to processes of making such alloys.

One object of this invention is to
provideawelding or soldering alloy which can be used to unite
metal parts including aluminum parts, without teh necessity of
employing careful cleaning procedure or fluxes, and without
the necessity of employing the drastic cleaning measures or
using the corrosive fluxes or specialized equipment previously
required with aluminum welding or soldering processes in order
to remove the tenacious oxide film from the surface of the
aluminum.

Object is to provide a welding or soldering
alloy for uniting metal parts, including aluminum or aluminum
alloy parts, which alloy is quickly and easily employed by
merely bringing the aluminum or aluminum alloy parts together,
heating them at their proposed junction by any suitable means
such as a gas torch in order to raise them above the melting
point of the welding alloy, and then stroking the parts at
their juntion by passing a rod of the alloy back and forth
along their juntion, whereupon the welding rod melts and flows
by capillary attraction into and along the joint without
previously applying a flux, uniting the parts tenaciously in a
firm and permanent joint.

Another object is to provide a welding or
soldering alloy for uniting metal parts, including aluminum or
aluminum alloy parts, wherein the welded area, after welding
or sodlering, has a strength at the junction which is greater
than the strength of the adjacent metal, so that if the parts
are sibjected to excessive force, they will break adjacent the
junction, but not at the junction itself, even if the welding
alloy has approximately the same thickness at the junction of
the adjoining aluminum or aluminum alloy parts which have been
welded.

Another object is to provide a welding or
soldering alloy for uniting metal parts, including aluminum or
aluminum alloy parts, which alloy has a silvery appearance at
the welded junction and which will not rust or corrode, and
which can be readily machined, polished, plated or painted.

Another object is to provide a welding or
soldering alloy for uniting metal parts, including aluminum or
aluminum alloy parts, which alloy can be employed by
inexperienced persons without special training and without the
need for any of the special preparatory measures previously
required in uniting aluminum parts, and not requiring welding
hoods, colored glasses or special eye protection.

Another object is to provide a welding or
soldering alloy for uniting metal parts, including aluminum or
aluminum alloy parts, wherein the welded area has a very fine
grain structure without porosity, and wherein soft solder will
adhere so as to enable the attachment of wires to aluminum or
aluminum alloy parts by soldering the wires to the welding
metal.

Another object is to provide a welding or
soldering alloy for uniting metal parts, including aluminum or
aluminum alloy parts, where special grooving or other special
preparation of the edges of the aluminum parts to be united is
not necessary, because the welding alloy of the present
invention penetrates throught the oxide film to the interior
of the metal to make a strong fusion, and flows readily
without spattering or creating lumps, and without the
production of the fumes or odors produced when fluxes are used
as in prior processes of uniting aluminum or aluminum alloy
parts.

Another object is to provide a process for
making a welding or soldering alloy having the characteristics
set forth in the preceding objects, wherein the process
enables the introduction of chemicals into the alloy while it
is in a molten state, without the production of dangerous
explosives which have hitherto characterized the attempted
mixing of such chemicals with molten metal, these chemicals
giving the alloy its properties of penetrating through oxide
layers or coatings of impurities and of flowing easily and
naturally by capillary attraction into the junction between
the parts to be united.

Another object is to provide a process of making
a welding or soldering alloy, as set forth in the object
immediately above, wherein the danger of explosion in
introducing the chemicals into the molten alloy is further
reduced by the use of a layer of carbon, such as fine grain
charcoal forming an insulating blanket, over the top of the
molten alloy, the porous material containing the chemicals
being placed upon this carbon layer and pushed through it into
the molten alloy beneath it, the slag, after being freed from
its chemicals, floating to the surface where it is skimmed
off.

Hitherto, the welding or soldering of aluminum
has been a difficult procedure requiring specialized
knowledge, skilled workmanship, and careful preparation of the
aluminum or aluminum alloy parts to be welded. The tenacious
film of oxide which adheres to the surface of aluminum or
aluminum alloys, unless removed by careful preparation or by
the use of corrosive fluxes, effectively prevented the
obtaining of a strong welded junction between the parts being
united. Furthermore, the fact that aluminum melts suddenly at
1217o F without any advance indication, such as
discoloroation, of nearing nearing the melting point, has made
high temperature welding procedures dangerous, due to the
possibility of destroying the parts themselves by their sudden
disintegration. The corrosive fluxes hitherto used have also
caused the creation of annoying fumes and odors, and
protective goggles, hoods or the like have been required
because of the danger to the eyes of the welding material
spattering or sputtering. Nevertheless, without first applying
a flux to create a flow path, the welding or soldering alloy
would not flow along or into the junction of the parts to be
united. The welding alloy of the present invention, as made by
the process of the present invention, eliminates these defects
and accomplishes the new results and advantages set forth in
the above-stated objects.

In preparing the alloy of the present invention,
the following metals and metal alloys are melted together in a
crucible in the following proportions to provide the metallic
ingredients:

Yellow brass (30% zinc and 70% copper):  8
lb   
Aluminum:    8 lb   
40-60 solder (40% tin 60% lead):    1.5 lb   
Silver (.1%) or Nickel (0.1%):  0.1 lb   
Zinc, to make up a 100 pound batch or:    
82.3 lb

The chemical ingredients are next prepared in
approximately the following proportions, for a 100 pound batch
of the above metal ingredients:

Powdered copper slag   3.0 lb   
Yellow sulphur    1.25 lb   
Willow charcoal    0.75 lb   
Commercial muriatic (hydrochloric) acid    0.50
gallons

The chemical ingredients are mixed together
thoroughly and the acid added and stirred into the dry
ingredients until a thin or watery paste-like mass is
produced.

Meanwhile, the metal ingredients in the crucible
have been heated until they reach the temperature of
approximately 1450o F. and a layer of fine grain powdered
charcoal of approximately a half-inch thickness is deposited
on top of the molten metal to form an insulating blanket. When
this charcoal layer has become red in color, the wet mass of
chemical ingredients is deposited entirely over the top of the
charcoal blanket in a thick layer. Using a suitable pushing
device, such as a metal rod, the chemical mass is forced down
through the charcoal blanket into the molten metal mixture, a
small area at a time. The charcoal blanket shields the
remainder of the mass from explosion or excessive reaction. As
the chemical mass is pushed into the molten metal mixture in
the crucible, a multitude of tiny reactions occurs throughout
it, instead of a single large explosion, due to the fact that
the chemical particles are separated from one another by the
porous inert slag and by the particles of charcoal. As each
portion which has been pushed down into the molten mixture is
absorbed into the latter, another portion is pushed down and
so on, until each portion of the chemical mass or layer has
been pushed through the insulating charcoal blanket, a small
area at a time.

After all of the wet chemical mass has been
pushed downward into the molten metal mixture in the crucible,
the entire mixture is stirred thoroughly to release all of the
chemicals from the pores of the copper slag and to cause the
tiny reactions and the explosions to be completed. When this
has been done, and the slag has lost its chemical
impregnations by these reactions and minute explosions, the
slag floats to the surface of the molten metal mixture, along
with other impurities or superfluous materials, these being
skimmed from the surface of the molten mixture, leaving the
latter in its finished state. The chemically-impregnated alloy
thus formed is then poured out and formed into suitable shapes
such as rods, bars or ingots.

During the period in which the chemical
ingredients are being pushed downward through the charcoal
blanket into the molten metal mixture, corrosive fumes are
emitted which must be carefully disposed of or they will
discolor paint, corrode ferrous metals, and cause annoyance to
persons in the vicinity. After the alloy has been made in the
above manner, however, it may be subsequently remelted without
the formation of such fumes. The chemically-impregnated alloy
remaining after the process has been completed is a finely
homogenized, high quality alloy which is easily machined,
plated or painted, as desired.

The present process also enables the combining
of zinc and lead in an alloy, even though these metals are
normally incompatible. For example, only one-half of one
percent of lead in a zinc based die, such as is used in
aircraft production, causes the die to crack during use,
because lead will not ordinarily mix with zinc satisfactorily.

The copper slag mentioned in the foregoing
process is the waste slag produced in copper smelting plants,
and is useful because of its porosity and inert
characteristics. It will be obvious that other porous
materials which are similarly inert may also be employed to
subdivide the chemical ingredients in the above manner and
thereby convert an otherwise dangerous single explosion into a
multitude of tiny harmless explosions and reactions.

The chemical ingredients thus incorporated into
the metal alloy impart to the alloy the capability of flowing
naturally and easily by capillary attraction when the alloy is
applied to the junction of metal parts, such as aluminum to be
united, without the previous use of a flux. Hitherto, it has
been necessary to apply a flux in order to form a flux path at
the junction of the metal parts to be united, or otherwise the
welding metal does not flow well, and does not easily enter
the junction between the metal parts to be united.

The proportions, and indeed, the components of
the metallic mixture are not critical and many variations may
be used. In place of the brass, pure copper or even bronze can
be employed, more copper giving greater strength. The nickel
and silver components are mere traces which produce better
uniting of the metal components with one another. The chemical
components of the alloy enable the alloy to penetrate the
oxide film on aluminum without wire brushing or other previous
preparation and to penetrate the crack or other junction
between the parts to be united and to emerge on the opposite
side thereof.

Proof that the chemical ingredients remain in
the alloy is found in the fact that shavings of the alloy
placed in a glass of ordinary tap water cause the flow of an
electric current which may be detected by a voltmeter,
milliampmeter or cathode ray oscilloscope when leads or
electrodes connected thereto are inserted in the water.
Moreover when the alloy particles or shavings have been
permitted to remain in the water for several hours, gas
bubbles will emerge from the water and form on the surface.
Each of these bubbles explodes upon the application of a
match, showing that **chemicals in the alloy shavings
produce hydrogen and other gases when placed in water**. A
still more powerful effect is obtained when salt water is
used. Moreover, if the alloy is prepared in the form of a
powder, this powder tends to come to the surface of the water
and float thereon even though its specific gravity or weight
is nearly seven times that of water.

In the use of the alloy of the invnetion in
soldering or welding metal parts, such as aluminum, the
extreme and exacting cleaning measures employed are
unnecessary. the parts to be united, if not already
satisfactorily supported adjacent one another, are placed in
proximity to one another at the location where they are to be
united, and heated by any suitable means, to a temperature
which sufficient to melt the alloy. A temperature of
approximately 800o F at the point of weld is sufficient, and
as this is 400o to 500o degrees lower than the melting point
of aluminum or aluminum alloys, there is no danger of harming
the parts if ordinary care is taken. No special heating
equipment is necessary, as the parts may be heated
electrically, as by a hot plate, or by the application of a
flame, such as from a gas torch, Bunsen burner, spirit lamp or
the like.

When the parts have been so heated, a piece,
such as a rod, of the alloy of the present invention is rubbed
against the parts and passed to and fro along their proposed
junction. Since the melting point of the welding alloy of the
present invention is below 825o F, it melts and flows easily
at that temperature, forming a silvery liquid resembling
mercury. No flux is necessary to cause the alloy to flow,
penetrate or adhere. As the rod is rubbed back and forth along
the junction, the alloy melts and flows easily and naturally
by capillary action into the junction where it quickly
solidifies. At the same time, it attacks the oxide film on the
aluminum or aluminum alloy, and penetrates below that film
into the metal itself, so that a strong weld is obtained. The
alloy, upon cooling, has a silvery, attractive appearance
which blends well with the adjacent aluminum or aluminum
alloy. It also has a very fine grain structure and is
substantially free from porosity.

The alloy of the present invention may be used
either in soldering, brazing or welding any aluminum or
zinc-based metal with a very high efficiency and also in
uniting other metals or materials with varying degrees of
efficiency. The welding handbook of the American Welding
Society in effect states that soldering takes place below 800o
F, brazing above 800o F, and welding at such higher
temperatures where the parent metal itself has been disturbed
and fusion has taken place.

The metal parts when united by the alloy of the
present invention, may be machined by the usual techniques and
equipment, as the alloy machines easily and is also painted or
plated.

The use of the alloy of the present invention
may be summarized by stating that it may be employed for (1)
welding of the metal parts without fusion, namely soldering or
brazing; (2) welding with fusion of the metal parts, namely
use of sufficient heat to cause surface fusion of the metal
parts to be united; and (3) welding with fusion of the parts
to be untied, accompanied by capillary action, namely welding
wherein the alloy flows along the parts and through the
junction thereof without the previous use of a flux.

The use of the alloy of the present invention
for soldering, brazing or welding metals other than aluminum
alloys, such as the zinc base metal mentioned above, is
carried out in a similar manner except that the working margin
of the temperature between the zinc in the parts to be united
and the present alloy is much smaller since aluminum melts at
the relatively high temperature of 1217o F, whereas zinc melts
at the relatively low temperature of 713o F. To lower the
melting temperature of the alloy of the present invention,
therefore, the silver and nickel should be omitted and the
proportionate amount of brass reduced, as these metals
contribute to raising the melting point. Experiments have also
shown that the alloy of the present invnetion may be used to
solder, braze or weld magnesium, but considerably more care
and vigilance is necessary because magnesium, although melting
at about 1200o F, occasionally catches fire at about 1000o F.
Here also, the working margin of temperature is rather small
and consequently operations must be conducted with caution.

In the process of preparing the alloy of the
present invention, if the furnace heat is inadvertently raised
to too high a temperature so that some of the metal
ingredients start to volatize, particularly the zinc, the
operator immediately covers the top of the molten metal in the
crucible with a layer of willow charcoal, which stops the
volatilization.

Normally, however, the operator does not use
more charcoal after the layer which he initially applies, and
waits until this charcoal powder has become completely red
before he attempts to push the chemical ingredients downward
through it into the molten metal. In practice, if the chemical
ingredients are forced through the charcoal blanket
prematurely, that is before it becomes fully red, the charcoal
powder will puff up in clouds of black smoke which is
irritating to the lungs and soils the clothing and the
surroundings. It has been found best to permit the charcoal to
ignite and burn at the outer periphery of the crucible and
gradually consume itself toward the center of the blanket,
whereupon the flame disappears and the top of the molten metal
in the crucible becomes tightly sealed with a red charcoal
coating.

To improve the free machining characteristics of
the alloy, the proportion of solder may be increased, the
machinability increasing as the proportion of solder is
increased. Thus, in the formula given above, instead of 1.5
pounds of solder for a hundred pound batch, as much as 3 to 5
pounds of solder may be beneficially employed.

Additional sulphur is employed occasionally if,
for example, it is found that high melting components of the
alloy are not properly melting, even though the temperature
has been raised to the point where other ingredients, such as
zinc, are ready to volatize. In that instance, the operator
throws yellow sulphur into the portion of the crucible where
the unmelted brass is located, whereupon a blue flame arises
and increases the temperature in the immediate vicinity of the
sulphur, causing the brass to melt readily. Thus, the addition
of sulphur has the opposite effect from the addition of
charcoal in that sulphur increases the heat or fire where
charcoal puts it out or minimizes it.

The muriatic acid may volatize, to some extent,
when it encounters the molten metal, but it undoubtedly reacts
chemically with the metals in the crucible to produce salts
such as chlorides which increase the tenacity of adhesion of
the alloy in welding or soldering, and thus render the use of
a separate flux unnecessary. The charcoal blanket however,
reduces the tendency of the muriatic acid to volatilize,
especially if only small portions of the chemical ingredients
are pushed through the charcoal layer into the molten metals
at a given time. The copper slag of the formula, being inert
and heat-resistant, merely serves as a vehicle or carrier or
modulator in a manner analogous to the phenomenon of
modulation in radio wave transmission. Thus, the alloy of the
present invention is characterized by the presence of
chemicals in solution with the metals, these chemicals
remaining in the alloy upon solidification and enhancing the
flow of the alloy by capillary action during welding without
the use of a separate flux.

The use of the alloy of the present invention
enables aluminum to be substituted for critically scarce
copper in many installations or applications where aluminum
was previously considered unsatisfactory because of the
difficulty of welding or soldering it. The present alloy may
also be used to coat aluminum wire by a procedure analogous to
"tinning" copper wire so that the thus coated aluminum may be
soft-soldered to other metals. The present alloy may also be
used in the form of a molten bath for "tinning" aluminum
articles for soldering them or for hermetically sealing them.

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**US Patent #
2,927,856**

**Multipurpose Alloys of Controlled
Homogeneity**

**Samuel Freedman**

[ This patent largely repeats USP # 2,796,345.
The unique sections are excerpted below:]

Another object is to reduce the melting
temperature of soldering alloys by the homogenization of
normally incompatible metals such as zinc and lead.

Another object is to increase the homogeneity
and reduce the heterogeneity of zinc-lead alloys.

Another object is to permit the introduction of
a violent liquid chemical into molten metals without hazardous
explosion wherein the chemical is introduced into the molten
alloy by being minutely subdivided into particles separated
from one another by inert material.

Another object is to cleanse molten metals of
superfluous impurities while in a molten state.

Another object is to create metals having
reduced corrosive and galvanic actions.

Another object is to provide metal alloys which
in the presence of moisture cause the conversion of the latter
into escapable hydrogen gas.

Another object is to provide a free machining
metal alloy that requires no coolant.

Another object is to provide a metal alloy which
electrifies and decomposes moisture in contact or during
immersion.

Another object is to provide a metal alloy which
can penetrate aluminum surface oxides and travel in the
direction of most metal by capillary action instead of burning
through the thin thickness of light gauge metal...

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