1. In resolving a conflict between Circuit Courts of Appeals
which, as to the same patent and upon substantially the same facts,
reached conflicting conclusions as to infringement, this Court will
reexamine concurrent findings of the District Court and the Circuit
Court of Appeals. P.
322 U. S.
473.
2. Patent No. 1,392,629, to Dubbs, for a process for producing
gasoline and other lighter oils from heavy crude oils,
held not infringed by a process which, in the step
corresponding to the B tubes of Dubbs, relies upon substantial
vaporization. P.
322 U. S.
484.
"Without substantial vaporization," as used in the Dubbs patent,
means that the generation and release of vapors in the B tubes is
to be avoided so that the charge will enter the C tubes for
cracking as nearly as may be in the liquid phase. P.
322 U. S.
482.
3. Egloff Patent No. 1,537,593, for an improvement on the Dubbs
process for producing lighter from heavier oils,
held
invalid for want of invention. P.
322 U. S.
486.
137 F.2d 3 affirmed.
Page 322 U. S. 472
Certiorari, 320 U.S. 730, to review a judgment which, on appeal
from a judgment of the District Court, 40 F. Supp. 575, in a suit
for infringement of patents, held the patents not infringed.
MR. JUSTICE REED delivered the opinion of the Court.
The petitioner sued the respondent for infringement of United
States Patents No. 1,392,629, dated October 4, 1921, and No.
1,537,593, dated May 12, 1925. The former was issued to Carbon P.
Dubbs; the latter, to Gustav Egloff. These patents cover the Dubbs
process for converting heavy crude oils to lighter oils, especially
gasoline. The claimed infringement arises from the respondent's use
for the purpose of such conversion of the "Winkler Koch process" in
apparatus designed and installed by the Winkler Koch Engineering
Company. The district court dismissed the bill on findings of fact
to the effect that Patent No. 1,392,629 was valid but not
infringed, and that Patent No. 1,537,593 was invalid, without
findings on the issue of infringement. [
Footnote 1] The majority of the Circuit Court of Appeals
found both patents not infringed, and did not pass on their
validity; Judge Lindley was of opinion that the Dubbs patent was
infringed, but that both patents were invalid. [
Footnote 2] The Court of Appeals for the Third
Circuit
Page 322 U. S. 473
found the same patents to be valid and infringed by the use of a
process substantially similar to respondent's in
Root Refining
Co. v. Universal Products Co., 78 F.2d 991. To resolve the
conflict thus presented, we granted certiorari, 320 U.S. 730.
Where the questions presented by the contested claims of
infringement and validity are purely factual, this Court ordinarily
accepts the concurrent conclusions of the district court and
Circuit Court of Appeals in these cases.
Goodyear Co. v.
Ray-O-Vac Co., 321 U. S. 275.
But, in resolving conflicting views of two Circuit Courts of
Appeals as to a single patent, we are obliged to undertake an
independent reexamination of the factual questions.
Sanitary
Refrigerator Co. v. Winters, 280 U. S. 30,
280 U. S.
35-36.
The patents and the allegedly infringing process concern
commercial methods for converting petroleum, as it is found in
nature, into the gasoline in everyday use as motor fuel. The
experts who testified in the district court have stated some of the
theoretical background of the processes used, and a brief summary
of this material may facilitate understanding of the process
involved.
Layman and chemist alike are, of course, familiar with the
conception of the atoms of "chemical elements" as the basic
building blocks of ordinary chemical compounds. [
Footnote 3] The atoms of the "elements" have
the capacity to combine with the atoms of other elements to form
the molecules of "chemical compounds," whose properties seem to
depend directly upon the nature of the molecule. In the field of
oil chemistry, the outstanding fact is the extraordinary ability of
carbon and hydrogen to combine with each other into molecules
containing widely varying numbers of carbon atoms with different
proportions of hydrogen atoms in an almost unlimited number of
different
Page 322 U. S. 474
structural arrangements. These combinations, generically termed
hydrocarbons, are present in great variety in crude oil.
The hydrocarbons differ widely from one another in their
physical properties, particularly in the property of volatility,
which is of prime importance in motor fuels. As one might expect,
the hydrocarbons composed of large molecules with many carbon atoms
are heavy, sluggish liquids with relatively high boiling points;
they are not suitable for use as gasoline. Those with smaller
molecules are much more volatile -- indeed, the very smallest are
gases at ordinary temperatures.
The initial step in the preparation of gasoline from crude oil
involves no molecular change; it consists merely in separating the
light hydrocarbons in the natural mixture from the heavy
hydrocarbons. This step is accomplished by heating the oil until it
vaporizes and then carrying the vapors through a device familiar to
industrial chemistry under the name of a fractionating tower. Such
a tower is in effect a series of condensers in which the vapor
mixture is cooled and the liquid condensate drawn off in separate
steps. First the high boiling point constituents, reaching a liquid
phase after relatively little cooling, are condensed and withdrawn;
this process is repeated on the remaining constituents in
successive steps as the vapors cool, until there remain only those
low boiling point hydrocarbons suitable for use as gasoline.
By fractional distillation alone, a typical sample of
Mid-Continent crude oil might yield approximately 25% gasoline,
5-7% kerosene, 30% gas oil, and a balance of 38-40% fuel oil. The
fraction remaining after the distillation of gasoline or gasoline
and kerosene is termed "topped crude."
For many years, the commercial petroleum industry carried the
production of gasoline from crude oil no farther than this initial
step of separating it from the mixture.
Page 322 U. S. 475
But, with the introduction of the automobile, the demand for
gasoline increased rapidly, and it became necessary to develop
commercial apparatus for the conversion of heavy hydrocarbon
molecules to light hydrocarbon molecules by the chemical process
known as "cracking." [
Footnote
4] Chemists had long known that, by heating the heavier
hydrocarbons to temperatures of the order of 750-900�
Fahrenheit, it was possible to decompose the heavy molecules into
lighter molecules with fewer carbon atoms, with the maximum
decomposition resulting from fairly prolonged application of heat.
[
Footnote 5] The breakdown of
the heavy molecules into lighter ones was accompanied, however, by
a concurrent phenomenon -- namely, the formation of even heavier
hydrocarbons and the deposit of solid matter called "coke" or
"carbon." Likewise, at the temperatures used, the oil boiled, and
if the vapors were not released (and they could not be if heat was
to be applied for a long period of time), high pressures developed
in the still. And as the cracking operation yielded products of
increasing volatility, this pressure would apparently rise as the
reaction progressed.
The engineering problems involved in the reduction of the
laboratory knowledge of cracking to commercial practice were
formidable, since the pressures and temperatures employed carried
severe risks of fire and explosion. The first commercial process
was introduced about 1913 -- the so-called Burton process. Burton
heated the charge -- gas oil -- in a simple tank, or shell still.
The tank was not continuously fed; a charge of 8,250 gallons was
pumped into it and brought to a temperature of 700-750� over
a
Page 322 U. S. 476
period of some 12 hours under autogenous gas pressure of 75
pounds. The cracking operation was then continued for 24 hours. The
vapors liberated in the still were conducted through an inclined
line to an aerial condenser, where the heavier and less volatile
vapors were liquified and drained back into the still through the
same vapor line, there to be mixed with the unvaporized residue and
subjected to further cracking. This first fraction of the vapors
was called "reflux condensate;" the unliquefied vapors were carried
to a second condenser and liquefied as "pressure distillate," a
liquid convertible by further refining operations not here relevant
to commercial gasoline.
The coke deposited during cracking tended to cause uneven
heating of the shell still, with resultant formation of weak spots
and danger of explosion. Consequently, it was necessary to shut
down the still after about 24 hours of cracking to permit the coke
to be cleaned out. The cleaning and pre-heating processes consumed
about half the operating time; the gasoline yield ranged only about
25-28% of the gas oil charge, and the menace of explosion was
serious. The Burton process was modified and improved somewhat in
1915 by the introduction of the Burton-Clark process, which
differed in that it did not apply heat directly to the shell still,
but, instead circulated the oil in the still by convection through
a separate heating coil. This improvement increased the yield to
some 30-32%. The Burton-Clark process constituted the general
industrial practice at the time of Dubbs' patent.
Chemical engineers in the refining industry were engaged in
continuous research looking to the solution of the coking problem
and the development of a process which might operate continuously,
without wasteful periodic shut-downs of expensive plant equipment.
The processes in suit are among the results of their efforts.
Dubbs Patent No. 1,392,629, the alleged infringement of which
forms the basis of this action, covers a process first
Page 322 U. S. 477
demonstrated in a pilot plant at Independence, Kansas, in 1919.
The oil charge is fed through a nest of heated tubes -- called "B
tubes" -- about four inches in diameter -- a heating process not
unlike that used in Burton-Clark. The heated oil is then delivered
to tubes of about ten inches diameter -- "C tubes" -- which are
only partly filled with liquid oil. The C tubes are insulated, but
unheated or only lightly heated to prevent the escape of heat by
radiation. Here, the vapor generated as the result of heating and
cracking passes from the liquid oil and is carried to vapor line
condensers of the same general kind used in the Burton system. The
first vapors to condense -- that is, the reflux condensate -- are
returned to the B tubes for further heating and cracking; the
lighter vapors are carried to a second condenser to become
gasoline. The unvaporized residue of liquids and suspended solid
particles in the C tubes is continuously withdrawn from the system;
thus, only the light oils of the reflux condensate, which have but
a limited tendency to form coke, are recycled through the B tubes.
Such deposit of coke in the lightly heated C tubes as occurs
involves no marked danger of explosion, and it precludes clogging
of the smaller superheated B tubes. Gas oil subjected to the Dubbs
process has been made to yield 40-50% gasoline, and continuous runs
of from ten to twenty days are usual.
In the commercial practice of the Dubbs patent, a simple vapor
separation tank usually takes the place of the C tubes.
The points of similarity and dissimilarity to the Burton-Clark
process are worth noting. Burton-Clark subjected to prolonged
heating the unvaporized hydrocarbons as well as the light reflux
condensate. Since these heavy hydrocarbons have the greatest
tendency to form still heavier oils and to deposit carbon, their
withdrawal from the apparatus was an important advance. The
continuous feed system of the Dubbs apparatus was also regarded as
an
Page 322 U. S. 478
improvement on Burton's batch process. Burton-Clark circulated
through the heating tubes the heavy oils formed during cracking;
Dubbs permitted only a mixture of fresh oil and reflux condensate
to pass through his furnace coil.
The Egloff patent covers an improvement on the Dubbs
process.
As we pointed out at p.
322 U. S. 474,
supra, the initial step in the
separation of gasoline from crude oil is fractional distillation;
then gas oil, the fraction next below gasoline and kerosene, is
subjected to cracking in a special apparatus. The fuel oil fraction
has such a strong tendency to form very heavy hydrocarbons and coke
that it is undesirable as a charge for the high temperature heating
coil in the cracking systems. [
Footnote 6] What Egloff proposed was a relatively mild
heating of the heavy oils in a separate furnace -- thus, fuel oil
or topped crude might be used as a charge. The temperature and
pressure would be sufficient to occasion a mild cracking; the
vapors might then be delivered to the same vapor separation tank
used with the high temperature heating tubes, and the reflux
condensate from these vapors might be used as the charge for the
high temperature tubes. The substantial effect is to subject fuel
oil or topped crude, from which the charge for a Dubbs plant was
often separated by separate distillation, to a distillation and
mild cracking operation, using the vapor separating tank and the
condenser apparatus of the Dubbs plant instead of using separate
apparatus to prepare the Dubbs charge.
The apparatus of respondent's Winkler-Koch process closely
resembles the apparatus of the Dubbs-Egloff system. Oil is heated
in either the high temperature or low temperature furnace,
depending on the kind of oil used;
Page 322 U. S. 479
the heated oil is delivered to a vapor separation tank; the
reflux condensate flows back to the high temperature coil for
further cracking.
The differences between the processes, as distinguished from the
apparatus, are more marked. Dubbs taught the heating of the oil
charge in the B tubes "without substantial vaporization." Thus, the
illustrative run in the patent suggests the heating of oil to a
temperature of 750 to 860 F. with a pressure of about 100 pounds to
the square inch, resulting from vaporization, maintained in both B
and C tubes. In the respondent's process, oil enters the heating
coils at a temperature of 590� and leaves at a temperature
of 940�; a pressure of 500 pounds to the square inch is
maintained in the heating coil. Some 85% of the oil by weight and
95% by volume reaches a vapor phase in the heating coils. The oil
in mixed liquid and vapor phase enters the vapor separation tank
through a pressure reduction valve, so that the pressure in the
tank is 26 pounds, as compared to the 500 pounds of the heating
coil.
The courts below believed that these differences were sufficient
to prevent the respondent's process from infringing the claims of
the Dubbs patent. A typical claim is Claim 5, as follows:
"5. A continuous process for cracking hydrocarbons consisting in
passing the same in a stream in an advancing direction from an
inlet point to a discharge point separated and entirely
disassociated from the inlet point, subjecting the material in the
first stage of its travel to a cracking temperature while
preventing substantial vaporization, affording a vaporization space
above the stream during the second stage of the travel thereof to
said discharge point, taking off the vapors from said vapor space
and subjecting them to a condensing action, discharging into the
stream at a point remote from that, where vaporization occurs a
portion of the condensates and maintaining
Page 322 U. S. 480
a vapor pressure on the material under treatment during
distillation and condensation."
It is apparent that the issue of infringement of the Dubbs
patent turns on the construction to be given the words, "without
substantial vaporization," as they are used in the claim. The
petitioner argues that what is claimed is that there is no release
of vapors from the liquid in the B tubes; the respondent argues
that it is meant that no liquid oil passes into a vapor phase in
the B tubes -- that is, that there is no vapor generation in the B
tubes.
Either construction would be consistent with the operation of a
cracking process. By applying sufficient pressure, it is possible
to prevent the generation of vapor from oil even at the relatively
high cracking temperatures. The gasoline yielded by cracking oil in
liquid phase is chemically different from that yielded by vapor
phase cracking, and at the date of the patent, the liquid phase
product was preferred. The yield of vapor cracking was a malodorous
yellow mixture requiring additional refining operations to make it
marketable; however, since 1919, gasoline formed by vapor cracking
has become more highly regarded because of its superior anti-knock
characteristics.
The parties are wholly at odds as to the nature of the process
taught by Dubbs in his patent specifications. The petitioner
contends that cracking takes place in the B tubes, with resultant
generation of vapor, and that, in the C tubes, the vapor is merely
set free from the liquid oil. The respondent argues that the only
function of the B tubes is to furnish enough heat to cause
cracking, and that the oil actually cracks while it is in the C
tubes. The cracking process, it will be remembered, requires that
the oil be kept at a high temperature for some time if substantial
gasoline is to be formed, and the respondent compares the process
taught by Dubbs to the familiar fireless cooker, in which a vessel
with heat-keeping qualities is
Page 322 U. S. 481
first heated and then removed from the flame while cooking goes
on with the heat first supplied.
The patent several times refers to the B tubes as "cracking
tubes," or as the "cracking zone." In its relevant parts, the
patent describes the process in the following terms:
"Describing the operation of the process, the material to be
treated is drawn from any suitable source by means of the pump J
and discharged therefrom through line J into and through tubes B
and during the time they (
sic) are passing through said
tubes, they (
sic) are subjected to sufficient heat to
cause the desired amount of cracking. Said oil is then passed into
the tubes C, which are only partially filled with the oil, and, as
the oil passes through these tubes, there is a liberation of vapors
from same and which vapors pass up through the vapor tubes D, E. .
. ."
"A light fire may be maintained under the tubes C as shown in
the drawings, or said tubes may be heavily insulated . . . to
prevent loss of heat by radiation and thereby dispense with the
fire under the tubes C. . . . The percent of vapors generated from
the oil as it passes through the tubes C will depend on the amount
of heat acquired by said oil while passing through the 4'
coils."
The petitioner refers also to Claim 5, which specifies "a
vaporization space above the stream" in the C tubes. These words,
we are told, must necessarily refer to a space in which vapors are
released, not generated. This does not advance petitioner's
argument, however, as the space referred to, as shown by the
subsequent words of Claim 5, is simply space to hold released vapor
-- that is "vapor space." Neither vapor separation nor vapor
generation takes place in the space above the stream.
Respondent, too, supports its argument that not even generation
of vapors was envisaged by the Dubbs patent limitation against
"substantial vaporization" by reference to the patent. It points
out that, as the patent does not define "vaporization," the word is
used in the accepted
Page 322 U. S. 482
sense of chemical nomenclature. The use of the word
"vaporization" in the patent to show what takes place in the C
coils is stressed by respondent as indicative of the meaning with
which the word was used by Dubbs. [
Footnote 7] The respondent says this means generation, as
well as release, of vapors because the patent says,
"The percent of vapors generated from the oil as it passes
through the tubes C will depend on the amount of heat acquired by
said oil while passing through the 4(B) coils."
It is said that the patent consistently describes the charge in
the B tubes as "oil," and never as vapor or mixed oil and vapor or
foam.
The petitioner argues that the reading of the patent which
respondent asks would result in an inoperative process under the
conditions of the illustrative run. It seems to be conceded that
oil heated to 750� at 100 pounds pressure would not
vaporize, but, in order for cracking to take place in the C tubes,
it would be necessary to furnish some additional heat to replace
that consumed in the cracking reaction. At the higher temperature
suggested in the illustrative run, much higher pressures than the
100 pounds called for become necessary to preclude vaporization,
although the heated oil would, in cooling from the higher
temperatures, provide the heat necessary for the cracking reaction
in the C tubes. But even though experimentation at low pressures
would show generation of vapor in the B tubes, this will not
control the language of the claim.
We agree with respondent's position as to the teaching of the
patent. We are of the view that "without substantial vaporization,"
as used in the patent, means that the generation and release of
vapors in the B tubes is to be avoided, so that the charge will
enter the C tubes for
Page 322 U. S. 483
cracking as nearly as may be in the liquid phase. It clearly
appears from the history of Dubbs' application in the Patent Office
that the use of the phrase was purposeful. It was inserted after
the Patent Office had disallowed claims without the phrase, and it
was evidently added to clarify the description of the steps of the
process and the claims of novelty.
Cf. Exhibit Supply Co. v.
Ace Corp., 315 U. S. 126,
315 U. S. 136.
The importance is evident from the history of the trade, since, as
pointed out above, at the time of Dubbs' application, gasoline
obtained by cracking the charge in liquid phase was more desirable
than the gasoline obtained from vapor phase cracking. [
Footnote 8]
The distinction made by the controverted phrase is of practical
importance. Dubbs patented a process for converting hydrocarbons
through cracking. The difficulty in the prior art was carbon
deposit or coking. If, in this process, the cracking operation is
pressed to substantial completion in the B tubes, the patent seems
to fail to teach a method of preventing coking in those tubes. Coke
there will certainly be as a result of the cracking; what would
prevent its deposit? It may be possible to prevent the deposit of
carbon by maintaining a rapid turbulent flow; indeed, we are told
that this is the device used in the commercial application of both
parties' processes, and Behimer, another engineer working in the
cracking field, attributed the failure of a similar apparatus
(
see Patent No. 1,883,850) to the want of a pump of
sufficiently high pressure to maintain the necessary velocity of
flow. But the patent, while it calls for a pump to inject the
charge into the B tubes, does not point out the need of using rapid
flow for this purpose; the pressure within the apparatus is
expressly referred solely to vaporization. One building a device
according to Dubbs' teaching might, if he read
Page 322 U. S. 484
the patent as teaching that cracking was to occur in the B
tubes, content himself with using relatively short B tubes and a
correspondingly slow flow to furnish cracking time. That procedure
would presumably lead to coking; the patent, however, does not
describe how that result may be avoided.
There is a reason of controlling importance why the protection
of the Dubbs patent must be limited to a process in which cracking
takes place largely in the C tubes.
As a reward for inventions and to encourage their disclosure,
the United States offers a seventeen-year monopoly to an inventor
who refrains from keeping his invention a trade secret. But the
quid pro quo is disclosure of a process or device in
sufficient detail to enable one skilled in the art to practice the
invention once the period of the monopoly has expired, and the same
precision of disclosure is likewise essential to warn the industry
concerned of the precise scope of the monopoly asserted.
Bene
v. Jeantet, 129 U. S. 683,
129 U. S.
685-686;
General Electric Co. v. Wabash Corp.,
304 U. S. 364,
304 U. S.
368.
In a process patent in the refining of oil, preciseness of
description is essential. It is a crowded art. Hope for success for
new patented processes with slight variations from those in use
caused large expenditures in testing their efficiency by important
companies with staffs of specialists who were skilled in the art.
Among the processes cited to us as prior art advances on
Burton-Clark, those of Hall Patent No. 1, 175,910, Alexander Patent
No. 1,407,619, and Behimer Patent No. 1,883,850, were embodied in
experimental plants, and the testimony is replete with references
to such other contemporary experimental or working cracking systems
as the Holmes-Manley, Fleming, and Cross processes. The claim is
the measure of the grant.
Smith v. Snow, 294 U. S.
1,
294 U. S. 11. The
claim is required to be specific for the very purpose
Page 322 U. S. 485
of protecting the public against extension of the scope of the
patent.
White v. Dunbar, 119 U. S. 47,
119 U. S. 52;
Minerals Separation v. Butte Mining Co., 250 U.
S. 336,
250 U. S. 347;
Knick v. Bowes "Seal Fast" Corp., 25 F.2d 442, 443. The
applicants for the patent thought the phrase "without substantial
vaporization" in the B tubes important. While varying the details
of a process does not avoid infringement,
Tilghman v.
Proctor, 102 U. S. 707,
when the accused process does not substantially follow the mode
taught in the patent, there is no infringement. In view of the
importance of the direction as to the nongeneration of vapors in
the B tubes, as hereinbefore pointed out, we do not think a process
which relies on vaporization in the B tubes can be said to infringe
the patented process.
The Egloff patent does not require extended consideration. It
may fairly be said that the Egloff patent, described above at p.
322 U. S. 478,
was an improvement on the Dubbs system. The improvement consisted
in providing a clean charging stock for the B tubes by heating
crude or fuel oil in coils which are contained in a separate
heating apparatus from the one used to heat the cleaned stock, and
discharging it in a liquid phase into an expansion chamber. The
unvaporized oil is withdrawn from the expansion chamber, and does
not reenter the system. The vapor is liquefied in a partial
condenser or dephlegmator, and the reflux condensate is pumped as a
charge into the B tubes of apparatus substantially similar in form
and operation of the Dubbs patent. The reflux condensate, after
passing through the B coils, reenters the same expansion chamber
that is used for its preparation. [
Footnote 9] Nothing
Page 322 U. S. 486
is said in the Egloff patent as to vaporization in the B
tubes.
It seems obvious that the Dubbs patent anticipated all the steps
of the process except the separate treatment of the heavy oil. The
clean charge of the reflux condensate was brought about by the
withdrawal of the residue of unvaporized oil, and this withdrawal
was old in the art. [
Footnote
10] As there is nothing in the claims or specification to show
any reliance upon where vaporization, whether by generation or
liberation, takes place, such difference as there may be between
this patent and Dubbs as to that phenomenon is not significant. But
we see nothing in the addition of the extra still that involves
invention. In retrospect, it appears almost inevitable that, once a
satisfactory continuous feed cracking apparatus was developed,
chemical engineers would promptly design equipment for integrating
the initial distillation of crude or fuel oil, with whatever
cracking might be practicable, with the gas oil cracking process to
form a continuous operation. Retrospective simplicity is often a
misleading test of invention where it appears that the patentee's
conception in fact solved a recognized problem that had baffled the
contemporary art; but, in this case, Egloff advanced his
improvement shortly after Dubbs disclosed the underlying process
and before Dubbs' system had had wide commercial use; hence,
contemporary workers had no occasion to deal with whatever
Page 322 U. S. 487
engineering problems might have been involved. We have therefore
a conception which is on its face too obvious to constitute
patentable invention, and which was advanced shortly after any need
of it arose. We think the district court was right in finding the
Egloff patent invalid.
Affirmed.
[
Footnote 1]
Universal Oil Products Co. v. Globe Oil & Refining
Co., 40 F. Supp. 975.
[
Footnote 2]
Universal Oil Products Co. v. Globe Oil & Refining
Co., 137 F.2d 3.
[
Footnote 3]
This case does not require consideration of any theory as to the
internal character of the atom.
[
Footnote 4]
See Standard Oil Co. v. United States, 283 U.
S. 163,
283 U. S.
167.
[
Footnote 5]
It has been stated, however, that cracking is an almost
instantaneous reaction in the vapor phase processes carried out at
temperatures above 950� F.
See de Florez, Profits
from Cracking in Vapor Phase, XIX National Petroleum News No. 49
(Dec. 7, 1927), pp. 32, 33.
[
Footnote 6]
Fuel oil can be directly charged to a Dubbs system, but the run
must be greatly shortened.
[
Footnote 7]
"The heated oil then passes to the 10 inch C coils which are
maintained about half full of oil and wherein vaporization takes
place."
[
Footnote 8]
But see Universal Oil Products v. Globe Oil & Refining
Co., 40 F. Supp. 975; 137 F.2d 3.
[
Footnote 9]
A typical claim (5) reads as follows:
"5. A process of oil conversion, consisting in maintaining a
body of heated hydrocarbons in an enlarged zone where substantial
vaporization occurs, in subjecting the vapors to reflux
condensation to condense the heavier vapors, in passing the reflux
condensate in an advancing stream through a heating zone where it
is subjected to cracking conditions of temperature and pressure, in
delivering heated condensate to said enlarged zone, and
simultaneously heating an independent stream of charging oil for
delivery to said enlarged zone to a temperature sufficient to cause
a substantial vaporization thereof in said zone, in introducing
said heated charging oil to the enlarged zone, and in withdrawing
unvaporized oil from said enlarged zone without permitting the same
to again enter either of said oil streams."
[
Footnote 10]
Egloff was not the first patentee to realize the advisability of
withdrawing the heavier oils; Dubbs certainly anticipated him, as
did Behimer, No. 1,883,850; Greenstreet, No. 1,740,691; Alexander,
No. 1,407,619, and Hall, No. 1, 175,910.