Charles TRIPLER // Jacob Tripler WAINWRIGHT -- Liquid Oxygen
Engine -- books & patents

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**Charles TRIPLER // Jacob Tripler WAINWRIGHT****Liquid Oxygen Engine**

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**A self-regenerating liquid O2 / CO2 engine****...**

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**<http://books.google.com/books?id=isOmR5YkpIEC&pg=PA57&lpg=PA57&dq=Tripler+Nature%27s+Secrets&source=bl&ots=R8ez-58sCf&sig=IOJtWS8C4tGu1A6hVVGCd_N5DpE&hl=en&sa=X&ei=fpoRU7T4GIeo2gXShoCYAw&ved=0CDcQ6AEwAQ#v=onepage&q=Tripler%20Nature%27s%20Secrets&f=false>**

**Doomsday Men: The Real Dr.
Strangelove and the Dream of the Superweapon**  
  
**by** **P. D. Smith**  
  
![](tripler1.jpg)



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**<http://www.gutenberg.org/files/33405/33405-h/33405-h.htm>**

**Nature's Miracles, Volume 1**  
  
**by**  
  
**Elisha Gray**

 **[ Excerpt ]**Mr. Tripler of New York, who has made liquid air in great
quantities, does it substantially as follows: First, he
compresses air to about 2500 pounds to the square inch. Of
course the air is very hot when it is first compressed because
all the air in the tank has been reduced in bulk about 166
times, and all the heat that was in the whole bulk of air is
concentrated into one-166th of the space it occupied before it
was compressed. It is 166 times hotter. There are two sets of
pipes running from the compressor to a long upright tank called
the liquefier. These pipes pass through running water, so that
the compressed air is quickly cooled down to the temperature of
the water (about 50 degrees Fahrenheit). The pipes a at least
one set of them a run the whole length of the liquefier, and
most likely are coiled. This set of pipes contains the air to be
liquefied. A second set of pipes runs to the bottom of the
liquefier, where there is a valve. By opening this valve a jet
of compressed air is allowed to play on the other set of pipes,
when intense cold is produced by the sudden[Pg 150] expansion of
the air. This cold air rushes up around the pipe containing the
air to be liquefied and escapes at the top, thus absorbing the
heat until the temperature is reduced to 312 degrees below zero.
Then the air liquefies and runs into a receptacle, where it may
be drawn off at pleasure...



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**The Fallacy of the Second Law of Thermodynamics****and the Feasibility of Transmuting Terrestrial Heat
Into Available Energy****by****Jacob Tripler WAINWRIGHT****[ [PDF](fallacyofsecond.pdf)
]**

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**An Investigation of the Second Law of Thermodynamics****by****Jacob Tripler WAINWRIGHT****[ [PDF](investigation.pdf) ]**

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**The New Thermodynamics****( The Non-Postulated Rationale of Motive Power of Heat ;
Also Comprising an Investigation of the Proposition of
Utilizing Heat of Environment as a Substitute for Fuel )****by****Jacob Tripler WAINWRIGHT****[ [PDF](newthermodynamics.pdf)
]**

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**Perpetual Motion of the Second Kind****Heat from the Atmosphere a Substitute for Fuel****by****Jacob Tripler WAINWRIGHT****[ [PDF](PerpetualMotion.pdf)
]**



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**Patents**

**Apparat til at bringe atmosfAcurrencyrisk Luft i
VAcurrencydskeform.**  
**DK3539**  
  
**[ [PDF](DK3539C.pdf) ]**  
  
![](d1.jpg)

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**Appareil pour la liquA(c)faction de l'air**  
**CH19922**  
  
**[ [PDF](CH19922A.pdf) ]**  
  
![](ch1.jpg)

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**Vorrichtungen zur VerflA1/4ssigung atmosphAcurrencyrischer Luft.**  
**AT2777**  
  
**[ [PDF](AT2777B.pdf) ]**  
  
![](at1.jpg)  ![](at2.jpg)  
![](at3.jpg) ![](at4.jpg)

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**Improvements in or relating to Fluid Pressure
Thermo-dynamic Engines.**  
**GB190003158**   
  
**[ [PDF](GB190003158A.pdf) ]**

**Abstract** -- Vapour engines. Relates to engines in which
the working fluid is liquid air, carbon monoxide, or other
substance having a sufficiently-low critical pressure and
temperature. The invention depends upon a revised statement of the
first and second thermodynamic laws, and consists in a special
cycle or system of working, whereby the heat rejected in the
Carnot cycle is intercepted and returned to the source, thus
rendering it possible to convert into motive power the diffused
heat existing in the atmosphere or elsewhere at ordinary
temperatures. Fig. 8 shows in plan a suitable form of motivepower
apparatus for putting the invention into effect, and Fig.
8<A> shows on larger scale a diagram to illustrate the heat
exchanges in the cycle. The heat to be converted into motive power
is abstracted by the working fluid in the conduit K from air
flowing through the adjacent conduit H. The working fluid is
conveyed from the conduit K to the cylinders E', E<2>,
E<3> of ordinary fluid-pressure engines, and is thence
exhausted by the pipe V into a conduit where it receives an
admixture of gas evaporated at the trap Z. The mixture is next
compressed in the cylinder C', and in flowing thence gives heat on
the one side to the gases entering the cylinder C' and on the
other to the liquid in the conduit K. This results in liquefaction
at the trap Z. Thence liquid is drawn by the pump P<3> and
delivered into the conduit K, leakage being made up by the pump.  
  
**PROVISIONAL SPECIFICATION.**  
I have invented a new and useful art, an apparatus, and a method
of operation, all of which pertain to said new art.  
  
This new and useful art consists in utilizing as a source of
energy heat that is common to terrestrial matter and manifested as
temperature condition. A rationale and description here follows.  
  
Heat engines which operate by the varying condition of a working
fluid, as regards pressure, volume, and temperature, have properly
been divided into two classes.  
  
1st. Those known as heat motor engines, and which by their
operation transform or convert heat into dynamic energy or work.
2nd. Those known as heat pumps, and which are merely motor engines
with a reversed cycle of operation, .and consequently transform
dynamic energy into heat.  
  
Heretofore, an essential to the operation of such motor engines
has been the maintenance of a refrigerator or medium of heat
reception to receive the accumulation of unconverted heat after
passing through the engine.  
  
Whereas, the object of my invention is to dispense with this
refrigerator, either wholely, or partially.  
  
Also, heat engines heretofore made exemplified the following
principles, first enunciated by Sadi Carnot, and now commonly
known as the second law of thermodynamics.  
  
1. All heat motor engines are similar in that they receive heat
from some source, transform part of it into work, and deliver the
remainder to a refrigerator.   
  
2. In the, thermodynamic sense, a heat motor engine is perfect
only when the cycle is reversible, and the efficiency of such an
engine is expressed by an average ratio of loss of temperature to
initial absolute temperature of the heat applied.  
  
Although these two principles or laws apply with correctness to
heat engines heretofore made, I have discovered or observed that
they are not correct for a broader and more comprehensive
treatment of the subject. In fact, they apply only to a specific
type of engine, have not the broad scope of a general nature, and
do not apply to all heat engines. However, they disclose the
present state of the art.  
  
Also, I have discovered or observed that the two above mentioned
laws should be revised so as to read as follows--  
  
1. All heat motor engines are similar in that they receive heat
from some source; transform this heat into work, wholely, or
partially; and deliver what remains to a refrigerator.  
  
2. In the thermodynamic sense, a heat motor engine is perfect only
when the cycle is reversible, and the efficiency of such an engine
is expressed by a ratio of loss of heat to quantity of heat
applied.  
  
An application of my invention consists in combining it. heat
motor engine with a novel apparatus which is merely a part of my
invention and is herein called a potential transformer; in a
manner to intercept the transfer to a refrigerator unconverted
heat that has passed through the motor engine; and return such
intercepted heat to its source, or to the motor engine, by the
expenditure of less dynamic energy than is generated by the motor
engine.  
  
When the heat from a heat motor engine is thus intercepted and
retained, a supply of heat can be utilized at a comparatively low
temperature and from some convenient source such as the
atmosphere, or a body of water, because it is not necessary to
maintain a' refrigerator' for the reception of an accumulation of
ejected heat.  
  
The above rationale of the matter is simple and explicit but
necessitates an explanation in regard to the nature and properties
of the potential transformer.  
  
For a potential transformer ; I have invented a new kind of heat
engine which I term potential transforming engine.  
  
When perfect and reversible in a thermodynamic sense; this kind of
engine can transform a fluid from one potential condition to an
other, without changing the intrinsic or total contained energy of
the fluid ; and consequently at no cost, nor gain, as regards
external work or dynamic energy. Also, its operation can be
regulated so as to transform the potential condition of the fluid
either with cost, or gain, as regards external work; and
consequently with a corresponding changed condition as regards the
intrinsic energy of the fluid.  
  
My invention is based on the feasibility of transmuting or
transforming the fluid from a lesser to a greater potential
condition, accompanied by but a meager increase in intrinsic
energy, for the purpose of affording means to manipulate for a
transmutation of its contained energy into dynamic energy or work;
all in accord with the first law of thermodynamics; and with the
second law, as hereinbefore revised by myself.  
  
In a generic sense; my preferable process or method of operation
for trans- forming a fluid from a lesser to a greater potential
condition; consists in densifying the fluid by abstracting heat or
energy therefrom while maintaining it at conveniently low
pressure, transferring this heat to the thus densified .fluid
while maintaining it at higher pressure, by or through a medium
which is adapted to cause a greater increase in potential
condition than' increase in intrinsic energy considered
proportionately respectively as regards total potential condition
and total contained or intrinsic energy.  
  
A perfect transformation is effected when there results no change
in intrinsic energy. With regard to most fluids ; it may be
remarked that such transformation of the potential condition
results at a corresponding temperature which does not differ from
that corresponding with the initial potential condition, when the
fluid is a perfect gas; and at a changed temperature when the
fluid is in the condition of a mixture of liquid and saturated
gas. With such a mixture, a change in potential condition
corresponding with no change in intrinsic energy necessitates a
change in the relative proportion of liquid to gas, and
consequently a change in its temperature because the values for
specific-heat respectively for the liquid and gas are not equal.  
  
Referring to the accompanying drawings. For the purpose of
simplicity, these drawings have been made in a conventional
manner, and refinements in matters of detail and scale have been
purposely omitted because the specified parts when taken
separately are well known devices and may be constructed in any
manner that is suitable and known.  
  
Figure 1. shows an elementary type of potential transforming
engine which approximates an ideal in a thermodynamic sense, but
is not so efficient in a mechanical sense. A diaphram capable of a
ready conduction of heat therethrough is shown at A, it separates
the 'Interior of a non-conducting cylinder into the two .parts B
and B B, each of these cylindrical parts are provided with a
non-conducting piston respectively indicated by C and C C, these
pistons are moved to and from the diaphram A by means of separate
racks and pinions respectively shown at D and D D. For explanatory
purposes, crank arms indicated at G and G G are here shown for
operating their respective pinions; and for the purpose of
avoiding prolixity, mechanism for operating these crank arms has
been 'purposely omitted because such explanation is not essential
to a proper understanding of the particular principles and
operation herein involved.  
  
![](gb1.jpg) ![](gb2.jpg)  
![](gb3.jpg)  ![](gb4.jpg)  
![](gb5.jpg)  
  
Preparatory to operating; a permanent charge of working fluid is
charged through the conduit E and opened cock F and into the
cylinder B while partially withdrawing the piston C ; the cock F
is then closed to put the engine in condition for operation. This
fluid is only a working fluid and not the fluid to be treated or
transformed. It is preferable that this fluid shall be the same
kind as that which is to be treated. Also, it is essential that
this cylinder shall now be only partially expanded and thereby
permit ample room for subsequent expanding and contracting of the
piston C.  
  
Preferably, a cycle is effected by the following successive
operations.-  
  
1. Starting with the pistons placed as shown in Figure 2. Through
the conduit E E and opened cock F F and while withdrawing the
piston C C to its full extent; a charge of vaporous, or gaseous
fluid to be operated upon or transformed is receivcd into the
cylinder J3 I3. '1'he cock F 1' is then closed. The pistons have
now acquired the positions shown in Figure 3.  
  
This fluid is thus received in a certain condition as regards its
contained or intrinsic energy, also in a certain potential
condition.  
  
This operation causes the piston C C to effect external work or
dynamic energy by reason of its withdrawal with the fluid pressure
thereon.  
  
2. The piston C C remaining stationary; the working fluid in the
cylinder B is expanded and cooled by a partial withdrawal of the
piston C; at a slow rate of speed so as to make efficient the
accompanying transfer of heat through the diaphram A, from the
fluid in the cylinder B 13 to the fluid in the cylinder B. Tins
operation causes the fluid in the cylinder B B to lessen its
pressure by reason of its loss of heat, while the fluid in the
cylinder B effects work by reason of its expansion and pressure.
The pistons have now acquired the positions shown in Figure 4.  
  
3. With the piston C slowly continuing its course of withdrawal;
the cylinder 13 B is contracted by forcing the piston C C towards
the diaphram A, preferably at constant pressure. The pistons have
now acquired the positions shown in Figure 5. This operation
causes the fluid in the cylinder B to be further cooled and
continue its production of work by reason of its expansion; while
the fluid in the cylinder B B is caused to contract by reason of
the application of external work thereon, and loss of the heat
transferred to the contents of the cylinder B.  
  
4. With the cylinder B B contracted, and the piston C C remaining
stationary, the cylinder B is contracted by slowly forcing its
piston C back to its initial position. This operation causes the
fluid in the cylinder B B to acquire temperature and pressure by
reason of the compression of fluid in the cylinder B.  
  
The pistons have now acquired the positions shown in Figure 6.  
  
5. The piston C remaining stationary, the fluid in the cylinder B
B is removed in a transformed condition through the conduit E E,
by opening the cock F F and forcing the piston C C to its initial
position; the pistons have again acquired the positions shown in
Figure 2, and the cycle is completed.  
  
The relative extent of the successive operations which make up a
cycle can be regulated so as to produce any desired degree of
change in potential condition.  
  
The degree of change in intrinsic energy is dependent upon the
degree of pressure under which the treated fluid is densified, and
is an increasing function of this pressure.  
  
This transforming engine posesses the following objectionable
features --  
  
1st. The process is not continuous. 2nd. The engine is not highly
efficient, in a mechanical and constructive sense.  
  
To overcome these objectionable features; I have invented the type
of transforming engine herein shown by Figures. 7A and 7", taken
together as a whole.  
  
I prefer to operate this engine so as to effect a process or
method of operation that is. less generic than that hereinbefore
mentioned, which consists in liquifying the fluid by abstracting
heat or energy therefrom while maintaining it at a relatively low
pressure, and transferring this energy to the liquified fluid
while maintaining it at a higher pressure. With this particular
apparatus'; this process or method of operation is effected in the
more specific manner which consists in liquifying the fluid by
abstracting heat therefrom, while maintaining it at a relatively
low temperature and pressure by a regenerative action; and
transferring this heat to the liquified liquid while maintaining
it at a higher pressure;  
  
A regenerative action is herein understood to be an action in
which there is an interchange of heat between working fluid that
precedes and working fluid that follows in the same routine.
Referring to Figures 7A and 7". In order to clearly show the
operation of this engine and the principles involved; in a
conventional manner the apparatus is shown by these two figures,
when they are taken together as a whole ; certain conduits shown
in one figure connect with and continue as the same conduit in the
other figure, these conduits are respectively indicated by the
same reference letter m each figure, and are the conduits Z, Y, X,
and W; the direction which the fluid is caused to pass through the
various conduits is indicated by conventional arrows. Figure 7A is
a sectional-elevation and shows that portion of the apparatus
where manipulations are effected) as regards regeneration .of
heat. Figure 7" is a plan and shows the dynamic mechanism, In a
conventional manner, and where desirable, the conduits and engine
cylinders are shown to be surrounded by suitable insulating
material to. prevent thermal inefficiencies by reason of external
radiation  
  
In operation, preferably, the fluid to be treated or transformed
is received in a gaseous condition by the conduit U and, passes
therethrough into the conduit Y which extends from the pressure
reducing-valve V to the compression cylinder Cl.  
  
This fluid enters the conduit Y, therein mixes with the current of
fluid passing therethrough from. the valve V, passes from this
conduit into the compression cylinder Cl, is compressed in this
cylinder and delivered therefrom into the conduit Z and passes
therethrough until the valve V is reached at the end of this
conduit Z, by passing through this opened valve it again enters
the conduit Y to again pass therethrough to the compressor Cl.
Through the conduit X, and as explained later, a portion of the
fluid is withdrawn from this circuit.  
  
A diaphram or siding capable of a ready conduction of heat
therethrough is indicated by D, and: separates the above mentioned
conduits Y and Z. The above mentioned compression effected by the
compression cylinder C1 causes a changed 'condition to the fluid,
as regards pressure and temperature; thereby the fluid pressure is
increased and also the temperature of the fluid is increased.  
  
The above mentioned passage of this fluid through the conduit Z,
in this compressed and heated condition, causes. an efficient
regenerative interchange of heat through the diaphram D, and with
the colder fluid passing in an opposite direction in the
adjoining, conduit Y.  
  
This regenerative interchange of heat effects a self-intensifying
frigerative effect, culminating at the valve V, and causing the
fluid in the thus frigefied end of the conduit Z to condense to
the liquid condition. By reason of gravitation, this frigefied
liquid fluid collects in the trap or upturn at the bottom of the
conduit Z, from whence it is forced through the upward turn of
this trap until it reaches the valve V at the top of this upturn
in the conduit. By passing from thence through the orifice or
opened pressure reducing valve V, the culminating frigefaction is
then effected by reason of the evaporation of this liquid due to
its entry into the conduit Y wherein a lesser pressure is
maintained by the combined action of the valve V and the
compressor C 1.  
  
For the purpose of effecting an efficient regenerative interchange
of heat to condense the hold in the conduit Z; the irigel1ed end
of the conduit Y and the adjoining branch from the conduit Z are
purposely , extended upwards and separated by the heat conducting
diaphram, in order that the released liquid from the valve V may
gravitate along the diaphram and toward the warmer portion of the.
conduit and thus insure a rapid, evaporation and thus prevent .an
accumulation of this liquid after passing through the valve V.  
  
Through the conduit X, a portion of the liquid fluid is withdrawn
from the conduit Z. This withdrawn liquid passes through the
conduit X and enters the pressure pump P 3 wherein it is put under
pressure and ejected therefrom into and through the conduit W
wherein this increased pressure is maintained. The conduit W is
separated from the conduits Z and Y by the diaphram or siding F
which is capable of a ready conduction of heat therethrough. for a
normal working or the apparatus ; the weight of the liquid fluid
thus withdrawn from the conduit % and forced through the conduit
W, and therefrom from this apparatus, is equal to the weight of
gaseous fluid received into the apparatus through the conduit U.
Through the diaphram F, there is an efficient interchange of heat
between the frigefied liquid passing through the conduit W and the
warmer and gaseous fluid passing under a lesser pressure and in an
opposite direction through the adjoining conduit Z. Thus; the
gaseous fluid to be treated or transformed is received into the
apparatus, through the conduit U is condensed to the liquid
condition when it reaches the frigefactive end of the conduit Z is
kept in a liquid condition and under a greater pressure after
passing through the pump P 3; and while under this pressure and
passing through the conduit W along the diaphram F, it receives
heat abstracted from the gaseous fluid in the adjoining conduit,
for the purpose of aiding the condensation in the conduit Z.  
  
The circuit through the valve V is maintained for the purpose of
producing the self-intensive frigefactive effect, and should .be
operated with sufficient flow, but with little difference in
pressure through this valve; because the efficiency of a
reducing-valve or orifice for . this purpose, in a-thermodynamic
sense, is affected by this difference in pressure and is a
decreasing function thereof.  
  
The counter shaft '1' is driven by any suitable source of
dynamic-energy. By means of suitable regulating devices such as
the belted sprocket cones shown at R and R 3, the counter shaft T
actuates the compressor C 1 and the pressure pump P 3 by means of
their respective crank shaft and piston shown at S 1 and S 3.
These sprocket cones or an equivalent regulating device afford
suitable means for regulating the relative flow through the
compressor C 1 and the pressure pump' P 3. The pressure reducing
valve -NI is of the type used on self-intensive frigefactive
apparatus, and can be readily adjusted to effect any desired
change of pressure.  
  
Thus as preeexited a description of a type of potential
transforming engine that receives a continuous, now of gaseous
fluid to be treated ejects the same in a continuous flow, and in a
changed potential condition in the same sense as hereinbefore
mentioned and described in connection with the apparatus shown by
Figure 1.  
  
Figures 8A and 8B, taken together as a whole, show a preferable
manner of combining the type of potential transforming engine
shown in Figures 7A and 7" with an ordinary type of heat motor
engine. In order to clearly show the operation of this combination
and the principles involved; in a conventional manner the
apparatus is shown by these two figures, when they are taken
together .as a whole; certain conduits shown in one figure connect
with and continue as the same conduit in the other figure, these
conduits are respectively indicated by the same reference letter
in each figure, and are the conduits Z, Y, X, W, U, and L ; the
direction ,which the fluid is caused to pass through the various
conduits is indicated by conventional arrows. Figure 8, is a
sectional elevation. and shows that portion of the apparatus where
manipulations arc effected, as regards regeneration, and
interchange of heat. Figure 8" is a plan and shows the dynamic
mechanism. 1'or the purpose of convenience, the various parts of
the transforming engine, where shown in this combination, arc
respectively indicated by the same reference letters that are used
in Figures 7A and 7". In a conventional manner and where
desirable, the conduits and engine cylinders are shown to be
surrounded by suitable insulating material to prevent thermal
inefficiencies by reason of external radiation.  
  
The object of this combination is to effect an interception of the
ejected low pressure fluid from the heat motor engine, transform
the potential condition of this ejected fluid by passing same
through the potential transforming engine, return this transformed
and high pressured fluid to the heat motor engine, increase the
intrinsic energy of this returned fluid by raising its temperature
to that of available terrestrial atmosphere, pass this
comparatively heated fluid through the working cylinder of the
heat motor engine, and thus complete the cycle -in accordance with
the principles hereinbefore explained in the rationale oi the
matter as regards utilizing heat that is common to terrestrial
matter for the purpose of transmuting same into dynamic energy.  
  
In operation, the low pressure gaseous fluid is ejected from tho
working cylinder 2 of the heat motor engine, it is also.ejected
from the working cylinders of the auxiliary motor engines E 1 and
E 3, which are directly attached respectively to the compression
cylinder C 1 and the pressure pump P 3 for the purpose of
supplying the necessary dynamic energy to operate same. This
ejected low' pressure fluid is received in the conduit U and
therefrom passes into and through tho various conduits of the
transforming engine in identically the same manner as was
described for Figures 7" and 7". The transformed and comparatively
cold fluid, under high pressure, and in liquid condition, passes
from the conduit W into a continuation of this conduit shown at K
which is separated from the conduit H by a diaphram or siding J
capable of a ready conduction of heat there- through. Through the
conduit H; preferably; is forced a current of air taken directly
from the atmosphere, or a current of water taken from some large
body of same, by means of a suitable fan or circulating device
which it is not necessary to show here, and is purposely omittcd
in order to avoid prolixity. Through the diaphram J, the current
of atmosphere passing through the conduit H effects an exchange of
heat with the current of colder fluid passing in an opposite
direction in the adjoining conduit K; thereby, the high pressured
liquid fluid is heated and evaporated at high pressure and is
forced through the continuation of this conduit shown at L. From
thence, this high pressure gaseous fluid is withdrawn to operate
the before mentioned motor cylinders E 1, E 2, and E 3. From these
motor cylinders, this fluid is ejected at low pressure into the
conduit U, and thus the cycle is completed.  
  
In order to renew ).he working fluid lost. by leakage, and to
maintain a proper quantity of fluid in the conduit system, the
pump P 4 forces a supply through the conduit N and from thence
into the conduit W. '1'he fluid is supplied to this pump in a
liquified condition, and by means of the conduit M which leads
from some suitable reservoir containing a supply thereof. It is
desirable that this liquid shall be volatile, cheap, readily
available; and non-corrosive. Consequently, I prefer to use liquid
carbonic acid, or liquid air.  
  
The current of atmosphere passing through the conduit H is the
source from which heat is supplied for actuating this whole system
of mechanism. If it were possible to construct the apparatus so
that a perfect efficiency would be obtained from all of its parts;
the heat that disappears or is abstracted from the current of
atmosphere would represent the surplus of dynamic or mechanical
energy developed by the whole apparatus; in other words, all of
the heat taken from this current would be transmuted into dynamic
energy available for any purpose. In a practical apparatus; the
difference between the actual available dynamic energy and the
heat abstracted from the current of atmosphere represents that
portion of the abstracted heat that is not transmuted into dynamic
energy but is dissipated; consequently, it is desirable that the
various parts shall be constructed so as to effect the greatest
possible degree of efficiency, particularly as regards fluid
expansion and fluid compression. From the pulley U on the shaft of
the motor engine E 2, all available dynamic energy can be taken by
means of a belt or other suitable device and applied to any
desired purpose. For the purpose of effecting a suitable
regulation of the relative flow through the various conduits; the
various pistons are connected one to the other by means, of the,
counter shaft T and the several belted sprocket cones connecting
this counter-shaft with the crank shafts that operate with these
pistons, and shown respectively at R 1, R 2, R 3, and R 4.  
  
For convenience in starting. and stopping the apparatus; valves
for stopping the supply of motive fluid from the conduit L to the
engine cylinders E 1, E 2, . and E 3, are shown respectively at L
1, L 2, and L 3; clutches for disconnecting ''the torsional action
of the shaft T in regard to the several sets of sprocket cones are
shown respectively at T 1, T 2, '1' 3, and T 4. In like manner the
clutch T 5 disconnects the pulley R 5 which is used only when
starting the apparatus, and as a means, for then connecting some
suitable steam engine or other convenient source of dynamic energy
for the purpose of actuating the counter shaft and thereby actuate
the mechanism of the apparatus until a normal working is effected;
when the apparatus has acquired a normal working condition, this
pulley  is disconnected from the shaft T by this clutch T 5,
the auxiliary starting engine is stopped, and the apparatus
continues by its self operating action.  
  
By utilizing the cooled current of atmosphere ejected from the
conduit H, for frigefactive purposes, the apparatus becomes a self
operating frigefactive engine.  
  
In order to make clear the principles involved ; in Figures 7A and
8A, it was necessary to adopt a conventional manner of showing the
conduit system. In ' practice, it is desirable to adopt an annular
spiral coil system.  
  
Preferably; this coil system consists of a continuous series of
flat spirals placed one over the other, separated into successive
layers by horizontal partitions of non-conducting material; and
between these horizontal partitions, a spiral partition of the
same material is arranged to form a flat spiral conduit in each
layer, and so as to continue successively through the series of
layers, and to conduct the current of low pressure fluid; in and
along; this insulated conduit 'containing the current of low
-pressure fluid, are placed conduits or pipes containing
respectively the several high pressure fluid currents, these pipes
are made of material which is capable of a ready conduction of
heat therethrough.  
  
Figures 9 and 10 show a, spiral coil constructed on this system,
Figure 9 is a ~sectional plan, Figure 10 is a sectional elevation,
and the same reference letters are used in both of these figures
.to indicate the same parts. In the interior of the hermetically
closed casing C, the high pressure fluid pipes or conduits 2 and 3
arc contained in the insulated spiral conduit 1 and there
surrounded by the current of low pressure fluid contained in this
conduit 1.  
  
Thus, is presented a description of an operative and practical
apparatus for effecting the purpose. of my Invention.  
  
It is herein understood that any operation mentioned in connection
with my invention may be performed in any manner that is suitable
and known. Also, my invention is not limited to the use of any
particular material in the construction of the various parts, nor
to the use of any particular working fluid, Also, the application
of a multiplex method of combination, which consists in effecting
the same cycle of operation by means of interdependent action
between two or more apparatus, shall be considered as a mere
equivalent of the simple single apparatus shown.  
  
**COMPLETE SPECIFICATION.**  
Improvements in or relating to Fluid Pressure Thermodynamic
Engines.  
  
The purpose of this art consists in utilizing as a source of
energy heat that is cpaimmi to terrestrial matter and manifested
as temperature condition. A rationale and description here
'follows.  
  
Heat engines heretofore made which operate by the varying
condition of a working fluid, as regards pressure, volume, and
temperature; have properly been divided into two classes. 1st.
Those known as heat motor engines; and which by' their operation
transform or convert heat into dynamic energy or work.  
  
2nd. Those known as heat pumps, and which are merely motor engines
with a reversed cycle of operation, and consequently transform
dynamic energy into heat ' 'Heretofore, an essential to the
operation of such motor engines. has been the maintenance of a
refrigerator or medium of heat reception to receive the
accumulation of unconverted heat after passing through the engine.
Whereas, . the purpose of my invention is to dispense with this
refrigerator, either wholly, or partially.  
  
Also, heat' engines heretofore made exemplified the following
principles, first enunciated by Sadi Carnot, and now commonly
known as the second law of thermodynamics.  
  
1. All heat motor engines are similar in that they receive heat
from some source, transform part of it into work, and deliver the
remainder to a refrigerator.  
  
2. In the thermodynamic sense, a heat motor engine is perfect only
when the cycle is reversible; and the efficiency of such perfect
engine is expressed by the difference between the respective
temperatures of heat reception and heat rejection, divided by the
absolute-temperature of heat reception, taken as an average with
respect to the units of heat applied and the portions of these
units which are rejected."  
Although these two principles or laws apply with correctness to
heat engines heretofore made, I have observed that they are 'not
correct for a broader and more comprehensive treatment of the
subject. In fact, they have not the broad scope of a general
nature, do not apply to all heat engines, and merely apply to that
particular type in which all portions of the working fluid
progress through the same temperature changes with cOl1unon-to-aI1
corresponding rates of ' change in potential condition.   
  
Also, I have observed that the two above mentioned laws should be
revised so, as to read. as follows.-   
  
1. All heat motor engines are similar in that they receive heat
from some source ; transform this heat into work, wholely, or
partially; and deliver what remains to a refrigerator.  
  
2. In the thermodynmnic sense, a heat motor engine is possible
only when the cycle is reversible, and the efficiency of such
perfect engine is expressed by a ratio of loss of heat to quantity
of heat applied.  
  
A preferable application of my Invention consists in combining a
heat motor engine, with a novel apparatus which is merely a part
of my invention and is herein called a potential transformer; in a
manner to intercept, the unconverted heat that has passed through
the motor engine, and prevent the transfer of same to. a
refrigerator; and return such intercepted heat to its source, or
to the motor engine, by the expenditure of less dynamic energy
than is generated by the motor engine. When the heat from a heat
.motor engine is thus intercepted and returned, a. supply of heat
can lie utilized at a comparatively low temperature and from, some
convenient source such as the atmosphere, or  a body of
water, because, it is not necessary to maintain a refrigerator for
the reception of an accumulation of ejected heat..  
  
The above rationale of the matter is simple and explicit but
necessitates an explanation in regard to the nature and properties
of the potential transformer.  
  
For a potential transformer, I have .invented a new kind of heat
engine which.  
  
I term potential transforming engine. Its function, as applied to
my invention in. a preferable manner, is to transform or transmute
the potential condition of the working fluid after passing through
the motor engine, and thus dispense with the necessity of
maintaining an external refrigerator for receiving the
accumulation of such ejected heat. The preferable manner in which
this result is attained consists in reducing the potential
condition of the fluid to be treated, by abstracting heat from
same; when this fluid has thus acquired a. comparatively low
potential condition and consequently is not capable of developing;
much latent beat by. a change in condition as regards density and
pressure, its condition is then caused to be changed by a meager
external application of dynamic energy or work; the above
mentioned 'abstracted heat is then returned to the thus densified
fluid held under an increased pressure and thereby causes a
transmutation to the condition of greater potential by reason of
the returned heat existing in the same but more densified fluid;
and effecting this abstraction and return of heat by a
regenerative action which is made effective by causing different
portions of regenerative fluid to progress through the same
temperature changes with corresponding rates of change in
potential condition that differ.  
  
When perfect and reversible in a thermodynamic sense, this kind of
engine' can transform a fluid from one potential condition to an
other, without changing the total contained energy of the fluid ;
and consequently at no cost, nor gain. as regards external work or
dynamic energy. Also, its operation can be regulated so as to
transform the potential condition of the fluid either with cost,
or with gain, as regards external work; and consequently with a
corresponding. changed condition as regards the total contained
energy of the fluid.  
  
My invention is based on the feasibility of transmuting or
transforming the fluid from a lesser to a greater potential
condition, accompanied by but a meager increase in total contained
energy, for the purpose of affording means to manipulate for a
transmutation of its contained energy into dynamic energy or work;
all in accord with the first law of thermodynamics; and with the
second law of thermodynamics, as hereinbefore revised by myself.  
  
In a generic sense ; my preferable process for effecting such
transformation consists in lessening the potential condition of
the fluid by abstracting heat from same ; when the fluid has thus
acquired a, lowered potential condition, effecting a changed
condition. by Increasing its density, or fluid pressure, or both,
by an external application of force; returning said abstracted
heat to the thus densified fluid held under increased pressure ;
and effecting this abstraction and return of heat by a
regenerative action in which different portions of regenerative
fluid are caused to progress through some identical temperature
changes with corresponding rates of change in potential condition
that differ.  
  
A perfect transformation of the potential condition is effected
when there results no change in the total contained energy. With
regard to most fluids ; it may be remarked that such
transformation results at a temperature which does not differ from
that corresponding with the initial potential condition, when the
fluid is a perfect gas; and at a changed temperature when the
fluid is in the condition of a mixture of liquid and saturated
gas. With such a mixture, a change in potential condition
corresponding with no change in total contained energy
necessitates a change in the relative proportion of liquid to gas,
and consequently a change in its temperature because the values
for specific-heat respectively for the liquid and gas are not
equal.  
  
The drawings filed with my Provisional Specification are herein
referred' to. in all cases. For the purpose of simplicity/these
drawings have been made in: a conventional manner, and refinements
in matters of detail and scale have been purposely omitted because
the. specified parts when taken separately are well known devices
and may be constructed in any manner that is suitable and known.  
  
Figure 1 shows an elementary type of potential transforming engine
which approximates an ideal in a. thermodynamic sense, but is not
so efficient in a' mechanical sense. Figures 2; 3, 4, 5, and 6,
are merely of the nature of a diagram, and are for the purpose of
explaining the successive operations that make up a cycle. A
diaphram capable of a ready conduction of heat therethrough is
shown at A, it separates the interior of a non-conducting cylinder
into the two parts B and 13 B, each of these cylindrical parts are
provided with a non-conducting piston respectively indicated by C
and C C, these pistons are moved' to and from the diaphram A by
means of separate racks and pinions respectively shown at D and D
D. For explanatory purposes, crank arms indicated at G and G G are
here shown for operating their respective pinions ; and for the
purpose of avoiding prolixity, mechanism for operating these crank
arms has been purposely omitted because such explanation is not
essential to a proper understanding of the particular principles
and operation herein involved.  
  
Preparatory to operating, a permanent charge of working fluid is
charged' through the conduit E and opened cock F and into the
cylinder B while partially withdrawing the piston C; the cock F
is, then closed to put the engine in condition for operation. This
fluid is manipulated as a portion of the working fluid and is not
the fluid to be treated or transformed. It is preferable that this
fluid shall be the same kind as that which is to be treated, but
in  more densified condition. It is essential that this
cylinder shall now be only partially expanded and thereby permit
ample room for subsequent expanding 'and contracting by means of
the 'piston C.  
  
Preferably, a cycle is ejected by the following successive
operations.-  
  
1. Starting with the pistons placed as shown in Figure 2. Through
the conduit E E and opened, cock F and while withdrawing the
piston C C to its full extent ; a charge of vaporous, or gaseous
fluid to be operated upon or transformed, -is received into the
cylinder B B. The cock F F is then- closed. The pistons have now
acquired the positions shown in Figure 3. This operation causes an
interchange of heat through the diaphram A until a common
temperature is acquired in both cylinders, and also causes the
piston C C to effect external work or dynamic energy by reason of
its withdrawal with the fluid pressure thereon..   
  
2. The piston C C remaining stationary; the working fluid in the
cylinder B is expanded and cooled by a partial withdrawal of the
piston C ; at a slow rate of speed' so as to make efficient the'
accompanying transfer of heat through the diaphram A, from the
fluid in the cylinder B B to the fluid in the cylinder B.  
  
This operation causes the-fluid in the cylinder B 13 to lessen its
pressure,by reason of its loss of heat, while the fluid in the
cylinder B effects work by reason of its expansion and pressure.
The pistons have now acquired the positions shown in Figure 4.  
  
3. With the piston C slowly continuing its course of withdrawal,
the cylinder , B B is contracted by forcing the piston C C towards
the diaphram A, preferably at constant pressure. The pistons have
now acquired the. positions' shown in . Figure 5. This operation
causes the fluid in the cylinder B to be further cooled and
continue its production of work by reason of its expansion; while
the fluid in the cylinder B B is caused to contract by reason of
the application of external work thereon, and loss of the heat
transferred to the contents of the cylinder B.,  
  
4. With the cylinder B B contracted, and the piston C C remaining
stationary; the cylinder B is contracted by slowly forcing its
piston C back to its initial position. This operation causes the
fluid in the cylinder B B to acquire temperature and pressure by
reason of the compression of fluid in the cylinder B.  
  
The pistons have . now acquired the positions shown in Figure 6.  
  
5. The piston C remaining stationary, the fluid in the cylinder B
B is removed in a transformed condition through the conduit E E,
by opening the cock F F and forcing the piston C C to its initial
position; the pistons have again acquired the positions shown
in-Figure 2, and the cycle is completed.  
  
The relative extent of the successive operations which make up
this single cycle can, be regulated so as to produce any desired
degree of change in potential condition. The degree of increase in
total contained energy is dependent upon the degree of pressure
under which the treated fluid is densified, and is an increasing
function of this pressure.  
  
A more controllable result can be attained by a cycle which
consists in one or more repetitions of such single cycle modified
by retaining the fluid in the cylinder 13 B for the repeated
treatment. '1'he relative extent of the successive. operations can
be regulated to produce any desired change in potential condition,
and any desired change In total contained energy.  
  
This transforming engine possesses the following objectionable
features   
  
1. The process is not continuous.  
  
2nd. the engine is not highly efficient, in a mechanical and
constructive sense.  
  
To overcome these objectionable features; I have invented the type
of transforming engine herein shown by Figures 7 any 7", taken
together as a whole. I prefer to operate this engine so as to
effect a process or method of operation that is less generic than
that hereinbefore mentioned, which definiteness consists in
liquifying the fluid by abstracting heat or energy therefrom while
maintaining it at a relatively low pressure, and transferring this
heat to the thus liquified fluid while maintaining this liquified
fluid at a greater pressure. With this particular apparatus; this
process or method of operation is effected in, the more specific
manner having definiteness as regards the liquifaction of the
fluid by abstracting heat or energy therefrom while maintaining it
at a relatively low temperature and pressure by a regenerative
action, and transferring this heat to the thus liquified fluid
while maintaining this liquified fluid at a greater pressure.  
  
Referring to Figures 7A and 7B. In order to clearly show the
operation of this engine and the principles involved; - in a
conventional manner the apparatus. is shown by these two figures,
when they are taken together as a whole; certain. conduits shown
in one figure connect with and continue as the same conduit. in
the other figure, these conduits are respectively indicated by the
same reference letter in each figure, and are the conduits Z, Y,
X, and W; the direction which the fluid is caused to pass through
the various conduits is indicated by conventional arrows. Figure
7A is a sectional-elevation and shows that portion of the
apparatus where manipulations are effected as regards interchange
of heat. Figure 7" is a plan and shows the dynamic mechanism. In a
conventional manner, and where desirable, the conduits and engine
cylinders are. shown to be surrounded by suitable insulating
material to prevent thermal inefficiencies by reason of external
radiation.  
  
In operation, preferably, the fluid to be treated or transformed
is received in. a gaseous condition by the conduit U and passes
therethrough into. the conduit Y which extends from the pressure
reducing-valve V to the compression cylinder.Cl.  
  
This fluid enters the conduit Y, therein mixes with- the current,
of, fluid -passing therethrough from the valve V, passes from this
conduit into the compression cylinder Cl, is compressed in this
cylinder and delivered therefrom, into the conduit Z and passes
therethrough until the valve .Y is reached at the end of this
conduit Z, by passing through this opened valve it again enters
the conduit Y to again pass therethrough to the compressor Cl.
Through the conduit X, and as explained later, a portion of the
fluid is withdrawn from this circuit.  
  
A diaphram or siding capable of a ready conduction of heat
therethrough is indicated by D, and separates the above mentioned
conduits Y and Z. The above mentioned compression ejected by the
compression cylinder C causes a changed condition to the fluid, as
regards pressure and temperature; thereby the fluid pressure is
increased and also the temperature of the fluid is increased.  
  
The above mentioned passage of this fluid through the conduit Z,
in this compressed and heated condition, causes an efficient
regenerative interchange of heat through the diaphram D, with the
colder fluid passing in an opposite direction in the adjoining
conduit Y.  
  
This regenerative interchange of heat effects a, self-intensifying
frigefactive effect, culminating at the valve V, and causing the
fluid in the thus frigefied end of the conduit Z to condense to
the liquid condition. By reason of gravitation, this frigefied
liquid fluid collects in the trap or upturn at the bottom of the
conduit Z, from whence it is forced through the upward turn of
this trap until it reaches the valve V at the top of this upturn
in the conduit. By passing from thence through the orifice or
opened pressure reducing valve V, the culminating frigefaction is
then effected by reason of the evaporation of this liquid due to
its entry into the conduit Y wherein a lesser pressure is
maintained by the combined action of the valve V and the
compressor C 1.  
  
Through the conduit X, a portion of the liquid fluid is withdrawn
from the conduit Z. This withdrawn liquid passes through the
conduit X and enters the pressure pump P 3 wherein it is put under
pressure and ejected therefrom into and through the conduit W
wherein this increased pressure is maintained. The conduit it' is
separated from the conduits and Y by the diaphram or siding 1'
which. is capable of a ready conduction of heat therethrough.  
  
For a normal working of the apparatus; the weight of the liquid
fluid thus withdrawn from the conduit Z and forced into the
conduit W, is equal to the weight of gaseous fluid received into
the apparatus through the conduit U.  
  
Through the diaphram F, there is an efficient interchange of heat
between the frigefied liquid passing through the conduit W and the
warmer and gaseous fluid passing under a lessor pressure and in an
opposite direction through the adjoining conduit Z. Thus; the
gaseous fluid to be treated or transformed is received into the
apparatus, through the conduit U ; is condensed to the liquid
condition when it reaches the frigefactive end of the conduit Z;is
kept in a. liquid condition and under a greater pressure after
passing through the pump P 3 and while under this pressure and
passing through the conduit W along the diaphram if, it receives
heat abstracted from the gaseous fluid in the adjoining conduit,
thereby aiding the condensation in the conduit Z.  
  
The circuit through the valve Y is maintained for the purpose of
producing the self-intensive frigefactive effect, and should be
operated with sufficient flow, but with little difference in
pressure through this valve; because the efficiency of a reducing
valve or orifice for this purpose, in a thermodynamic sense, is
affected by this difference in pressure and is a. decreasing
function thereof.  
  
The counter shaft T is driven by any suitable source of dynamic
energy. By means of suitable regulating devices such as the belted
sprocket cones shown at R 1 and R 3, the counter shaft T actuates
the compressor C 1 and the pressure pump P 3 by means of their
respective crank shaft and piston shown at S 1 nnd S 3. These
sprocket cones or an equivalent regulating device afford suitable
means for regulating the relative flow through the compressor C 1
and the pressure pump P 3. The pressure reducing valve V is of the
type used on self-intensive frigefactive apparatus, and can be
readily adjusted to effect any desired change of pressure.  
  
Thus is presented a description of a type of potential
transforming engine that receives a continuous flow of gaseous
fluid to be treated; ejects the same in a continuous now, and in a
changed potential condition in the same sense as hereinbefore
mentioned and described in connection with the apparatus shown by
Figure 1. Also, it may be remarked that with each of these devices
it is desirable to densify the treated fluid at a degree of
pressure that is below but somewhat near its critical-pressure.  
  
Figures 8A and 8B, taken together as a whole, show a preferable
manner of combining the type of potential transforming engine
shown in Figures 7A and 7D, with an ordinary type of heat motor
engine. In order to clearly show the operation of this combination
and the principles involved ; in a conventional manner the
apparatus is shown by these two figures, when they are taken
together as a whole; certain conduits shown in one figure connect
with and continue as the same conduit in the other figure, these
conduits are respectively indicated by the same reference letter
in each figure, and are the conduits Z, Y, X, W, U, and L; the
direction which the fluid is caused to pass through the various
condiii4g is indicated by conventional arrows. Figure S' is a
sectional elevation and shows that portion of the apparatus where
manipulations are effected as regards interchange of heat. Figure
8B is a. plan and shows the dynamic mechanism. For the purpose of
convenience, the various parts of the transforming engine, where
shown in this combination, are respectively indicated by the same
reference letters that are used in Figures 7A and 7B. In a
conventional manner and where desirable, the conduits and engine
cylinders are shown to be surrounded by suitable insulating
material to prevent thermal inefficiencies by reason of external
radiation.  
  
The object of this combination is to effect an interception of the
ejected low pressure fluid from tho heat motor engine, transform
the potential condition of this ejected fluid by passing same
through the potential transforming engine, return this transferred
and high-pressured fluid to the heat motor engine, increase the
total contained energy of this returned fluid by applying heat
taken from available terrestrial atmosphere, pass this
comparatively heated fluid through the working cylinder of the
heat motor engine, and thus complete the cycle in accordance with
the principles hereinbefore explained in the rationale of the
matter as regards utilizing heat that is common to terrestrial
matter for the purpose of transmuting same into dynamic energy.  
  
In operation, the low pressure gaseous fluid is ejected from the
working cylinder E 2 of the heat motor engine, it is also ejected
from the working cylinders of the auxiliary motor engines E I and
E 3 which are directly attached respectively to the compression
cylinder 0 1 and the pressure pump P 3 for the purpose , of
supplying the necessary dynamic energy to operate same. This
ejected low pressure fluid is received in the conduit U and
therefrom passes into and through the various conduits of the
transforming engine in identically the same manner as was
described for Figures 7A and 7B. The transformed and comparatively
cold fluid, under high pressure, and preferably in liquid
condition. -passes from the conduit W into a continuation of this
conduit shown at K which is separated from the conduit H bv a
diaphram or siding J capable of a ready conduction of heat
therethrough. Through the conduit H; preferably: is forced a
current of air taken directly from the atmosphere, or a current of
water taken from some large body of same, by means of a. suitable
fan or circulating device which it is not necessary to show here
and is purposely -omitted in order to avoid prolixity. Through the
diaphram T the current of atmosphere passing- through the conduit
H effects an exchange of heat with the current of colder fluid
passing in an opposite direction in the adioining conduit K;
thereby, the hijyh pressured fluid is heated and expanded, or
evaporated, at high pressure, and is forced through the
continuation of this conduit shown at L. From thence, this high
pressured Pa.aeous ftniel is withdrawn to operate the before
mentioned motor cylinders E 1. E 2, and E 3. From the motor
cylinders, this fluid is ejected at low pressure into the conduit
TT, nnll thus the cycle is completed. In order to, rencw the
working fluid lost by leakage, and to maintain a proper quantity
of fluid in the conduit system, the pump P 4 forces a supply
through the conduit N and from thence into the conduit W. The
fluid is supplied to this pump in a liquified condition, and by
means of. the conduit M which leads from some suitable reservoir
containing a supply thereof. It .is desirable that this liquid
shall be non-corrosive, cheap, readily obtained, and .possess a
critical temperature and a critical-pressure that are conveniently
low. Consequently, I prefer to use liquid air, or liquid carbon
monoxide.  
  
The current of atmosphere passing through the conduit H is the
source from which heat is supplied for actuating this whole system
of mechanism. If .it were possible to construct the apparatus so
that a perfect efficiency would be obtained from all of its parts;
the heat that disappears or is abstracted from the current of
atmosphere would represent the surplus of dynamic or mechanical
energy developed by the whole apparatus; in other words, all of
the heat taken from this current would be transmuted into dynamic
energy available for any purpose. In a practical apparatus; the
difference between the actual, available dynamic energy and the
heat abstracted from.the current of atmosphere represents that
portion of the abstracted heat that is not transmuted into dynamic
energy but is dissipated; consequently, it is desirable that-the
various parts shall be con- 8li'uctqd so .as to . effect the
greatest possible degree of efficiency, particularly as regards
fluid expansion and fluid compression. From the. pulley O on the
shaft of the motor engine E 2, all available dynamic energy can be
taken by. means of a belt or other suitable device and applied to
any desired purpose. For the purpose of effecting a suitable
regulation of the relative flow through the.various conduits; the
various pistons are connected one to the other by means of the
counter shaft T and the several belted sprocket cones connecting
this counter shaft with the crank shafts that operate with these
pistons, and shown respectively at R, R 2, R 3, and R 4.  
  
For convenience in starting and stopping the apparatus; valves for
stopping the supply of motive fluid from the conduit L to the
engine cylinders E 1, E 2, and E 3, are shown respectively at, L
1, L 2, and L 3 ; clutches for disconnecting the torsional action
of tile shaft '1' in regard to the several sets of sprocket cones
are shown. respectively at T l, '1' 2, '1' 3,' and '1' 4. In like
manner the clutch '1" disconnects the pulley R 5 which is used
only when starting the apparatus, and as a means for then
connecting some suitable steam engine or. other convenient source
of dynamic, energy for the purpose of actuating the counter shaft
and thereby actuate the mechanism of the apparatus until a .normal
working is effected ; when the apparatus has acquired a normal
working condition, this pulley is disconnected from the shaft T by
this clutch T 5, the auxiliary starting engine is stopped, and the
apparatus continues its action by reason of the self operating
feature...  
  
By utilizing the cooled current of atmosphere ejected from the
conduit H, for frigefactive purposes, the apparatus becomes a self
operating frigefactive engine.  
  
In order to make clear the principles involved, in Figures 7A and
8A it was necessary to adopt a conventional manner of showing the
conduit system. In .practice it is desirable to adopt an annular
spiral coil system.  
  
Preferably; this coil system consists of a continuous series of
flat spirals placed one over the other, separated into successive
layers by horizontal partitions of non-conducting material; and
between these horizontal partitions, a spiral partition of the
same material is arranged to form a flat spiral conduit in each
layer, so as to continue successively through the series of
layers, and to conduct the current of low pressure flu14, In and
along this insulated conduit  the current of lower pressured
fluid are placed conduits or pipes containing respectively the
several higher pressured fluid currents, these pipes are made of
material which is capable of a ready conduction of heat
therethrough.   
  
Figures 9 and 10 show a spiral coil cont1'lcted on this system,
Figure 9 is a sectional plan, Figure 10 is a sectional elevation,
and the same reference letters are used in both of these figures
to indicate same parts. In the interior of the hermetically closed
casing C the higher pressured fluid pipes or conduits 2 and 3 are
contained in the insulated spiral conduit 1 and there surrounded
by the current of lower pressured fluid contained in this conduit
1.  
  
Thus, is presented a description of an operative and practical
apparatus for effecting the purpose of my invention. ' A
self-intensifying heat engine is herein understood to be a heat
engine in which the action of the cycle tends to intensify or
extend the limit of the working range of temperatures, when
interchange of heat with external sources is dispensed with. A
regenerative action is herein understood to be an interchange of
heat between fluid tha,t precedes and fluid tha,t follows in the
same routine, or the abstraction and subsequent return of heat to
and from the same fluid.  
  
Also, it is understood that any operation herein mentioned in
connection with my invention may be performed in any manner that
is suitable and known.  
  
Also; my invention is not limited to the use of any particular
material in the construction of the various parts; any particular
working fluid; nor any particular type of engine or device for
converting fluid pressure and expansion into dynamic energy,
particularly as regards the application of fluid jets and turbines
to such purposes. Also, the application of a multiples method of
combination, which consists in effecting the same cycle of
operation by means of inter-dependent action between two or more
apparatus, shall be considered as a mere equivalent of the simple
single apparatus shown.  
  


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