Ernst Berl: Protoproduct from vegetable waste; synthetic
bitumen

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**Ernst BERL**

**Protoproduct**

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***Popular Science*** (1943-44 ?)

![](berl-psci.jpg)

Growing our own gas may be the answer to the
problems posed by the demands of war and increasing industrial
and personal needs. Startling results have been achieved by
Dr. E. Berl, a research professor at the Carnegie Institute of
Technology, from his experiments in converting plants into
gasoline, coal, and other hydrocarbons. By carefully
controlled internal combustion, plant material such as sugar
cane, wood, sorghum, potatoes, cornstalks, or even grass, is
transformed into a substance known as protoproduct.

A gummy semiliquid at ordinary temperatures,
this protoproduct is itself a highly efficient fuel.
Hydrogenation converts it in turn into gasoline, kerosene, or
lubricating oil. Or by another process it can be changed into
coal that is said to be in some respects superior to natural
coal. If Dr Berls method proves practical on a commercial
scale, it may be of world-changing importance, for vast
agricultural areas might easily produce their own fuel for
industrial power.

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***Time Magazine*** (Monday, Sept. 23,
1940)

**Recipe for Fuel**

To the American Chemical Society convened in
Detroit last week, Professor Ernst Berl of Pittsburgh's
Carnegie Institute for Technology made an astonishing
announcement. He said he had made, experimentally but
successfully, oil, coal, coke and asphalt from grass, leaves,
seaweed, sawdust, scrap lumber, corn, cornstalks, cotton.

The earth's supplies of coal and oil were laid
in, once for all, during the Carboniferous Age, 200 to 300
million years ago. Using them is like spending capital. But
using coal and oil made from plants would be like spending
income, since plants grow prodigally and all the time.

One difference between wood and oil is that wood
is mostly carbohydrates (composed of carbon, hydrogen and
oxygen) whereas oil is mostly hydrocarbons (composed of carbon
and hydrogen only). Chemically these two great classes of
compounds behave very differently. But economically the really
important difference between wood and oil is that wood-burning
locomotives are obsolete, whereas oil-burning Diesel trains
are the height of modernity.

Apparently, converting the carbohydrate
vegetable matter into hydrocarbons is the most ticklish part
of Dr. Berl's process, and he did not talk about it too
freely. He heats the carbohydrate under pressure with
limestone and "similar substances." Probably one or more
catalysts (chemical activators) are involved. The time
required is only one hour --- considerably less than the
millions of years that nature needed. The *New York Herald
Tribune* gulped with excitement: "What the Wrights did to
distance, he [Professor Berl] has done to geologic time. One's
imagination gags at the possibilities."

Dr. Berl did not say how much or what fuel would
be needed to run his fuel factory (if coal or oil were used,
the amount consumed would certainly have to be less than the
amount manufactured). He did say that, with natural coal and
oil still plentiful and prices low, the cost would be too high
to undertake commercially now. But he believes the chemist's
job is to be ready for future shortages.

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**US Patent # 2,551,579**

**Production of Valuable Organic
Compounds from Plant Material**

(Cl. 260-125)

Ernst Berl, Walter G. Berl, executor of said
Ernst Berl, deceased.

This invention relates to the production of
hydrocarbons from plant material.

The production of liquid hydrocarbons is now
carried out on a large scale with lignites and younger
bituminous coal as the starting materials. In one known
process, hydrogenation of the older lignites or the younger
bituminous coal proceeds directly, with or without the
addition of appropriate catalytic material, whereby through a
combination of cracking and hydrogenation liquid hydrocarbons
result, which contain alipathic, hydroaromatic, and aromatic
hydrocarbons and which, therefore, have a rather high
anti-knock value. Another known process converts fuels
directly or indirectly from a mixture or carbon monoxide and
hydrogen. This water-gas mixture can be converted by means of
appropriate catalysts into alipathic hydrocarbons, mostly of
the straight chain character. This process can be carried out
like the aforementioned process under pressure or without
pressure. The liquid hydrocarbons obtained exhibit a rather
low anti-knock value and have to be modified by the formation
of branched alipathic hydrocarbons possessed of a higher
anti-knock value. The same process makes possible the
production of solid paraffins of very high molecular weight.

Both processes use raw materials prepared by
nature at former geological periods. In view of the fact that,
for the production of one part by weight of liquid or solid
hydrocarbons, about four or five parts in weight of coal are
necessary, the consumption of those valuable raw materials is
rather high.

In a previous publication (Annalen der Chemie,
Vol. 504, p. 38-71) I disclosed the conversion of pure
cellulose  in the form of cotton linters  first into a
protoproduct and then by hydrogenation or by cracking into a
liquid oil. Prior to the invention to be disclosed herebelow
it was impossible to convert plant lignin by simple means into
liquid or semi-liquid materials. Conversion was possible only
by very expensive processes requiring the use of costly
apparatus. The process of the publication aforesaid was
relatively simple insofar as process steps are concerned, but
was expensive insofar as raw material is concerned. Prior to
the present invention, I believed, in common with the rest of
the scientific world, that the only suitable raw material for
such a process was pure or substantially pure cellulose. All
scientific experience with the treatment of plant lignin
indicated that it could not be converted into useful products
in such a process, because such work as had been done on plant
lignin had been done after isolation of the lignin by the
saccharification or other conversion of the carbohydrates, and
when so treated it had been found, as stated above, that the
processing gave no practical results.

It is an object of this invention to provide an
economical process whereby liquid or semi-liquid fuel and
other valuable hydrocarbon products can be produced from
inexpensive plant material.

Another object of the invention is a process
whereby hydrocarbon fuel displaying high anti-knock properties
can be produced from plant material.

Still another object of the invention is the
conversion of inexpensive plant material into artificial
bituminous asphalt as in intermediary product in the
production of valuable end products.

Other objects of the invention will become
readily apparent from the following description.

In accordance with the present invention, liquid
hydrocarbons and asphalts, also phenols, can be formed easily
from carbohydrates and carbohydrate and lignin containing
materials such as plants, algae, seaweed, grasses, leaves,
wood, peat, corn stalks, straw, bagasse, molasses or the like.
The conversion of such material, produced continuously by
nature on a large scale, can be effected discontinuously or
continuously by heating the aforementioned raw materials with
aqueous solutions or suspensions o alkaline reacting
substances such as lime, magnesia, sodium-, potassium-,
calcium-, magnesium carbonate, sodium hydroxide, ammonium
hydroxide, sodium, potassium-, ammonium sulpide, zeolites,
iron hydroxide, iron carbonate, iron sulphide, or mixtures
thereof, etc., at an elevated temperature. Under these
conditions the carbohydrate and lignin content of the plant
matter are attacked and both constituents contribute to the
final product. Under the influence of these alkaline reacting
materials on the plant material at the elevated temperatures
of between 150 C and 370 C (377 C is the approximate critical
temperature of water) in presence of water a bitumen-like
material is produced, which is composed of alipathic,
hydroaromatic and aromatic compounds together with large
amounts of phenol compounds and phenol carbonic acids which
latter can be separated easily from the neutral substances by
formation of phenolates, which when acidified form free
phenols and phenol carbonic acids. The bitumen-like material
reacts easily with oxygen. It can be converted by
hydrogenation or cracking into liquid hydrocarbons, containing
alipathic, hydroaromatic and aromatic hydrocarbons. They
possess a rather high anti-knock value. The carbon content of
the original carbohydrate material is about 40 to 44%, that of
the lignin is 62 to 65%. Carbohydrates and lignin are
converted by the process of my invention into bitumen-like
material with about 75 to 80% of carbon and 14 to 19% of
oxygen. When the said bitumen-like material is subjected to
complete hydrogenation or cracking, it loses its oxygen and
yields a crude oil, containing between 86 and 91% of carbon.
Incomplete hydrogenation or cracking results in an
asphalt-like intermediate material with about 82 to 86% of
carbon and about 10 to 12% of oxygen. The liquid hydrocarbons
referred to are found to possess boiling points of between 40
and above 250 C at normal pressure and are practically free
from oxygen.

From my previous publication, dealing with the
conversion of pure cellulose or carbohydrate. It appears that
55.2% of their original carbon content is contained in the
protoproduct. In contrast with this, repeated experiments
according to the process of my present application reveal that
64.5% of the original carbon in sugar cane appears in the
protoproduct.  In contrast with this, repeated
experiments according to the process of my present application
reveal that 64.5% of the original carbon in sugar cane appears
in the protoproduct. Water-free sugar cane contains
approximately 16.65% lignin with 28.2% of the sugar cane
carbon and 83.35% carbohydrates with 71.8% of the sugar cane
carbon. Applying to the carbohydrate constituent the yield
figure of 55.2% of my previous publication, there should be
obtained in the protoproduct, there should be obtained in the
protoproduct 71.8 x 0.552 = 39.6% of sugar cane carbon. The
following table, based upon more than 50 experiments covering
a period of years, shows the average yields in carbon from
sugar cane, the carbon content of the sugar cane being 100:

In the protoproduct 64.5% of original carbon.   
In hydrogenated bitumen containing gasoline, kerosene, asphalt
and residue 61%   
In gasoline, kerosene, lubrication oil and residue 59.9%   
In gasoline, kerosene and lubrication oil 44.7%

It is obvious from the foregoing that the lignin
constituent has furnished a material amount of the liquid and
semi-liquid material. Otherwise, the increased yield above the
figure of 35.9% postulated on my previous publication would
not be possible.

It is also important to note that a very large
part of the carbon recovered in the protoproduct appears
ultimately in the commercially desirable fractions, gasoline,
kerosene and lubrication oil. This further serves to show the
importance of the invention and the valuable part which the
lignin constituent contributes to the final result.

Further proof of the fact that the lignin
constituent contributes to the valuable end products is found
in the fact that a substantial percentage of CH3O
(methoxy) is present in the conversion products of
lignin-containing plant material but is not found in the
conversion products of carbohydrates alone.

The discovery that lignin-containing plant
materials may be used has great commercial significance. This
is best shown by a cost comparison. From the Statistical
Abstract of the United States for the year 1941, p. 755, it
appears that the average yield of cotton per acre for the
years 1936-1940 was 239 pounds and that the average price per
ton was $191.20. Production figures for sugar cane in the same
period show an average annual production of 18.55 tons per
acre in the continental United States and 36.5 tons in Hawaii.
The figures for Cuba, Puerto Rico and the Philippines compare
closely with the figures for Hawaii. The average price of the
sugar can (wet weight) was $2.97. In the other countries
mentioned the price is undoubtedly much lower.  In
comparison, therefore, it is seen that the production per acre
per year in cotton is 0.12 tons and in green sugar cane is 18
to 36 tons, and that the price for sugar cane (dry weight) is
$15.85 (or $11.85 based on 8-% or 75% water content in green
sugar cane) per ton as against $191.20 for cotton. These vast
differences in yield and cost open up, at a price which is
well within commercial possibilities, sources of raw material
which were not available according to my old publications.

In the foregoing comparison of raw material
costs, I have referred to green sugar cane on a dry weight
basis, however, bagassse, which is sugar cane from which about
10 to 15% of its weight has been extracted, may be used.
Bagasse finds no use at the present time except for burning
under boilers and, to a very limited extent, for use in
wall-board. Consequently, my invention makes it possible to
utilize a material that has been, to all intents and purposes,
a waste material, and thereby to conserve a product, mineral
oil, which is rapidly becoming exhausted. As pointed out
above, other waste materials available in very large
quantities, e.g., seaweed, sawdust, corn stalks or straw may
also be used.

By the process disclosed herein, I start with
plant material where in the cellulose and the lignin are both
present. I have made the surprising discovery that in these
circumstances the lignin behaves differently from plant lignin
which has been separated from the carbohydrates, so that it is
susceptible to processing at relatively low cost and with a
yield of solid semi-liquid and liquid material from the lignin
constituent of the plant material. Prior to the making of the
present invention it was my belief that substantially pure
carbohydrates are the only suitable source materials for such
a process and that lignin, far from contributing
advantageously to the process, would probably interfere with
its function.

A fundamental part of my present invention,
therefore is that the pant lignin, if connected with
carbohydrates in the original plant material, behaves
differently from lignin which has been isolated by the
saccharification or other conversion of the carbohydrates.
Isolated lignin can hardly be converted into semi-liquid or
liquid material, whereas, by the present process, using as
starting substances plant material containing both cellulose
and lignin, the lignin constituent responds t the treatment
and contributes to the final result.

As already stated, the processes of the present
invention can be carried out discontinuously or continuously.
Then working discontinuously, the plant material containing
carbohydrates and lignin, water and alkaline reacting
material, e.g., limestone, are heated to temperatures of
between 150 deg C and 370 deg C. Instead of limestone, I may use
dolomite, magnesite, or the corresponding hydroxides, or
alkali-, or ammonium hydroxides or carbonated or iron
hydroxide or iron carbonate, or sulph-hydrates, or sulphides.
Under these conditions, the carbohydrates and lignin are
converted into a bitumen-like material, containing from
between 14% to 19% of oxygen. At the same time, gases are
produced which contain, besides carbon dioxide, alipathic
hydrocarbons, mostly methane. In the aqueous solution are
found a great number of compounds, from which can be isolated
phenols and phenol carbonic acids and esters, like formic acid
methyl ester, and other substances, like acetone and lower
fatty acids. In order to recover these rather valuable
substances from the aqueous liquid, well-known chemical and
physical methods should be resorted to. The resulting watery
liquid after addition of new amounts of alkaline reacting
material may serve for the next operation.

The bitumen-like material has a rather low
viscosity and a brownish-black color. In contact with air,
polymerization takes place with the formation of substances
which are more viscous and ultimately become more or less
solidified. Known methods permit the extraction from this
bitumen-like material of any acid-reacting substances, such as
phenols and phenol carbonic acids. The bitumen, called
protoproduct, contains oxygen bound in different forms, for
instance in form of ketones and complex phenols or phenol
carbonic acids with alipathic side chains. The protoproduct
has a thermal content of about 140,000 BTU per gallon as
compared to 105,000 for gasoline.

This bitumen-like material can be used as a
source for phenols by treating it with alkali or with liquid
water at high temperatures and pressure. Phenols then are more
soluble than in cold water. Furthermore, phenol anhydrides are
hydrated under formation of phenols. One can, furthermore, get
increased yields of these phenols by carrying out an
incomplete hydrogenation which splits of alipathic side chains
without eliminating the phenol group oxygen. In this way
phenols are obtained which can be used for those purposes
where phenols find normal use, for instance for explosives,
plastics, disinfectants, etc.

In order to get oxygen-free hydrocarbons, this
bitumen-like material, the protoproduct, has to be
hydrogenated under conditions whereby practically all oxygen
present is removed. This can be done with hydrogen or
hydrogen-containing gases, e.g., water gas under pressure
(50-500 atmospheres) at elevated temperature (325 deg-475 deg C) and
the use of appropriate hydrogenation catalysts, for instance
molybdenum, tungsten or tin compounds. If the hydrogenation is
practically complete, then hydrocarbons free of or with small
amounts of oxygen with boiling ranges from 30 deg C up to 250 deg C
(at pressures of 3-4 mm mercury) are obtained. Analysis shows
that the resulting hydrocarbons are of alipathic,
hydroaromatic and aromatic nature. The higher boiling
fractions which give an excellent lubrication oil contain OCH3-methoxyl
groups. This is proof that they derive from the lignin
content. Because carbohydrates alone give compounds free of
methoxyl.

The production of those hydrocarbons can be
accomplished in different ways. One can treat the plant
material containing carbohydrate and lignin, preferably in the
presence of alkali and moisture, first at temperatures up to
370 deg C in order to produce the protoproduct. Hydrogenation
catalysts have to be added to the plant material. The
conversion and hydrogenation processes are carried out in a
one-step process during and after the bitumen-forming process
with hydrogen or hydrogen containing gases, e.g., water gas
under pressure. In order to carry out the hydrogenation the
temperature has to be kept at between 325 deg and 450 deg C. When
oxygen-free hydrocarbons result besides compounds which
contain OCH3 groups. About 45% of the carbon of the
plant material used can be converted into these liquid
hydrocarbons.

One can carry out the conversion separately from
the hydrogenation. The production of the protoproduct takes
place at temperatures up to 370 deg C. Then to the resulting
protoproduct hydrogenation catalysts are added and the
hydrogenation is carried out at elevated temperatures
(350-475 deg C) and initial hydrogen pressures (at room
temperatures) up to 500 atmospheres. The processes can be
carried out continuously or discontinuously.

In those cases where the hydrogenation of the
protoproduct is not intended, the elimination of the bound
oxygen can be carried out by a cracking process. The
oxygen-containing protoproduct has to be heated to
temperatures between 250 deg and 600 deg C without catalysts or in
the presence of substances with highly developed internal
surfaces, i.e., activated carbon, silica gel, aluminum
silicates, zeolites, permutites, copper compounds and
asbestors, or colloidal silicic acid, etc., under pressure.
Then an intramolecular combution takes place. The oxygen
present is removed, mostly in the form of carbon dioxide and
water, alcohols, ketones, and fatty acids. Oxygen-free
hydrocarbons result, containing besides alipathic and
hydroaromatic hydrocarbons and consequently these hydrocarbons
produces from plant material containing carbohydrates and
lignin in accordance with the process of my invention exhibit
a high anti-knock value. Coke is produces besides low-boiling
hydrocarbons and higher-boiling or melting residues. In all
cases they contain alipathics, aromatics and hydroaromatics.
If this cracking process is carried out at temperatures above
500 deg C, the amount of aromatic hydrocarbons is greatly
increased. When the hydrogenation or cracking is not carried
out completely, then the higher-boiling fractions show the
presence of asphalt-like material, which can be used for the
same purposes as natural asphalt.

In order to carry out the aforementioned
conversion process, the pant material containing carbohydrate
and lignin is preferably disintegrated and ten mixed with the
alkaline reacting substances in solution or in suspension. The
resulting mass is conducted through heated tubes with the help
of pumps. The heating of the tubes is effected from the
outside to the desired temperature, at which the conversion of
the plant material proceeds. After having converted the
carbohydrate and lignin of the plant material into a
bitumen-like material, the reaction product is removed from
the heating zone by passing either through a reduction valve
or into reservoirs, which after having been filled
alternately, press the converted material through a cooling
device so that a separation of the reaction products can be
effected into gas, aqueous liquid and bitumen. The gas, liquid
and semi-liquid reaction products can then be utilized.

The bitumen separated from the gas and the
aqueous liquid can be converted with small lost of
carbon-containing material into liquid hydrocarbons by
hydrogenation, whereby appropriate catalysts, like molybdenum,
tungsten, or tn compounds, not subject to being poisoned by
sulphur compounds, can be employed.

Nitrogen-containing substances can be produced
by reacting the plant material or the bitumen with a source of
reactive nitrogen, such as ammonium hydroxide.

Sulphur-containing compounds can be formed by
reacting the plant material or bitumen with a source of
reactive sulphur, such as sulphides like Na2S or
FeS or sulph-hydrates by reacting it with substances
containing the SH group such as NaHS.

Valuable products containing bound sulphur and
nitrogen in the molecule are obtained from plant material
containing carbohydrates and lignin by reaction with a source
of reactive sulphur and nitrogen, e.g. (NH4)2S
or NH4HS.

In the accompanying drawings I illustrate two
arrangements for carrying out the process described above.
They are merely by way of example and are not intended to
limit the scope of the present invention in any way.

Figure 1 diagrammatically shows an arrangement
whereby the formation of the protoproduct and its
hydrogenation are carried out at the same time in the same
apparatus.

![](fig1.jpg)

Figure 2 shows an arrangement in which the
conversion into protoproduct is carried out before its
hydrogenation.

![](fig2.jpg)

In the arrangement shown in Figure 1 a mixture
of plant material containing carbohydrates and lignin with
water and alkali in container 1 is fed by pressure pump 2 into
the pipe still 3. In pipe still 3 the mixture is subjected to
an elevated temperature in accordance with the above
disclosure. From there it goes to the reaction tower 4
(preferably insulated). Such gaseous products as are already
formed at this stage, as well as unused hydrogen or hydrogen
containing gas (see later), are drawn off through valve 5 and
sent through a condenser 6. The liquids formed in that
condenser are collected in tank 7, and may be drawn therefrom
through valves 8, 81. Those gases that were not
condensed in condenser 6 are drawn off by reduction valve 9.

The liquid part of the mixture emerging from
pipe still 3 is allowed to flow downwardly in reaction tower 4
which may be filled with packing material 10 (preferably the
packing material described in my US Patent # 1,796,501).
Baffle plates (not shown) or other conventional means to slow
down the descent of the mixture may be utilized in addition to
or instead of the packing material 10.

Hydrogen or hydrogen containing gases, e.g.
water gas are fed into the system by compressor 11 through
pipe 12. A valve or other suitable connection at 13, which
divides the hydrogen stream, permits part of the hydrogen
stream to mix the disintegrated plant material prior to it
entry into the pipe still 3, while the other part of the
hydrogen stream proceeds to the bottom of reaction tower 4.

By the time the mixture reaches the bottom of
reaction tower 4 it has been converted into practically
completely hydrogenated material. It moves through condenser
14. The end product goes through valve or valves 15a and 15b
into tank or tanks 16a, 16b, from where it may be drawn off by
valves 17a, 17b. Valves 18a and 18b allow the release of
pressure in the tanks 16a and 16b.

A suitable catalyst is added to the mixture in
container 1 when carbohydrate and lignin conversion and
hydrogenation are carried out in accordance with the
above-described process.

The above-described process may be used without
parts 11, 12 and 13 if conversion without hydrogenation is
desired. Protoproduct and artificial bituminous asphalt are
then obtained as intermediary products which may be used as
source material for penol compounds or may be converted into
valuable end products by hydrogenation or cracking separately
carried out.

An apparatus for carrying out the hydrogenation
separately is shown in Figure 2.

The mixture of plant material, water and
alkaline reacting material is led from container 19 by
pressure pump 20 into pipe still 21. From pipe still 21 the
mixture goes to the top of the reaction tower 22 and flows
therein downwards. It is kept there at the conversion
temperature. The converted material lows through a condenser
23 into a receiver 24, which can be emptied through valve 25.

The gasified part of the mixture composed mostly
of CO2, H2O and CH4 is drawn
off through condensers 26 and 27 and into tank 28. From this
tank 28 condensed material may be drawn off to the outside
through valve 29. The gases CO2 and CH4
proceed to the absorption and conversion tower 31 through
valve 30. CO2 is absorbed and CH4
converted into hydrogen. This hydrogen together with
unconverted hydrogen from a hydrogenation tower 34 and
hydrogen freshly added at 32 are transported by compressor 33
into the bottom of the tower 34 which may be provided with
packing material or baffle plates (not shown). The unused
hydrogen together with CH4 produced during
hydrogenation leaves 34 at 39 and enters the CH4
conversion apparatus 31.

The protoproduct collected in 24 leaves at 35.
At 35 the hydrogenation catalyst may be added. The mixture
with the help of pump 37 is pumped through the pipe still 38
and enters at the top f hydrogenation tower 34. There it is
hydrogenated. It leaves the tower 34 at 39, goes through a
condenser 40 and enters through valves 41a and 41b into the
storage vessels 42a and 42b. Those can be emptied through
valves 43a and 43b by closing 41a or 41b and opening 44a or
44b.

By subjecting to these discontinuous or
continuous processes in accordance with my invention all kinds
of plant material containing carbohydrate and lignin, phenols,
bitumen, asphalts and finally oxygen-free hydrocarbons of high
anti-knock value are obtained. The great advantage of my
processes can be seen in the fact that valueless material,
like algae, seaweed, peat, grass, leaves, corn stalks,
bagasse, wood, molasses, etc., which are produced continuously
by nature and which otherwise would be converted by slow
combustion into valueless CO2 and H2O,
can be utilized to good advantage. It follows that it is no
longer necessary to resort to lignite and bituminous coal for
artificial production of hydrocarbons.

Modification of the process and apparatus
described above, all within the scope of the present
invention, will readily occur to the expert. The scope of the
invention therefore is deemed to be limited by the appended
claims only. [Claims not included here\

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