Title of Invention

PRODUCTION OF 3-(ALKYLTHIO)PROPANAL

Abstract Process for the production of compounds of the general formula in which R signifies H, C1 to C3-alkyl, by the reaction of glycerol, or of a compound from which glycerol is released, with a compound of the general formula R-SH (II) in which R signifies H, C1 to C3-alkyl, or compounds from which this (II) is produced, in the presence of a catalyst, characterised in that an acidic solid catalyst, the H0 value (Hammett acidity function) of which is less than +2, is used.
Full Text Production of 3-(alkylthio)propanal
The invention relates to a process for the production of 3-
(alkylthio)propanal from glycerol using catalysts.
In addition to the industrially important MMP, MMP
analogues of the general form

with R = H, alkyl can also be produced from glycerol.
3-(Methylthio)propanal (MMP) is an important intermediate
and thus of great economic significance for the production
of D,L-methionine and the methionine hydroxy analogue 2-
hydroxy-4-methylthiobutyric acid (MHA). Methionine is an
essential amino acid, which is used inter alia as a
supplement in animal feeds. Nutrition-enhancing feed
additives are now an essential component in animal
nutrition. They are used to improve the utilisation of the
nutrient supply, stimulate growth and promote protein
formation. One of the most important of these additives is
the essential amino acid methionine, which occupies a
prominent position as a feed additive particularly in
poultry rearing. In this field, however, so-called
methionine substitutes, such as methionine hydroxy analogue
(abbreviated to MHA), are also of not inconsiderable
importance, since they exhibit growth-stimulating
properties similar to those of the amino acid known for
this purpose.
According to the prior art, MMP is produced by the
catalysed addition of methyl mercaptan to acrolein. Liquid
acrolein is generally reacted with methyl mercaptan in a
reactor in which liquid MMP and the catalyst are already
present in dissolved form (DT 2320544). The use of gaseous
acrolein with methyl mercaptan is also known (FR 7520183,

FR 7917827, WO 97/00858). The reaction between methyl
mercaptan and acrolein can take place batchwise or
continuously (US 4,225,515, US 5,352,837). Organic bases,
e.g. tertiary amines such as hexamethylenetetramine,
trialkylamines, e.g. triethyl- or triethanolamine,
benzylamines, pyridines, e.g. 2-fluoropyridine and 4-
dimethylaminopyridine, picoline, pyrazine, imidazole and
nicotinamide, but also copper(II) acetate, mercury methyl
mercaptide and organic peroxides, are used as conventional
catalysts.
The use of ion exchangers has also been mentioned (FR
7520183). The actual addition catalyst is conventionally
combined with an auxiliary catalyst, an organic acid, e.g.
acetic acid, citric acid or formic acid, or a mineral acid,
e.g. sulfuric or phosphoric acid, on the one hand to
inhibit the polymerisation of acrolein, i.e. the formation
of undesirable by-products, and on the other hand to
increase the general yield by conditioning of the added
base. The catalyst is not recovered and is lost during
working up.
Typical catalyst concentrations are 0.001 to 0.005 mole%,
based on methyl mercaptan. The quantity of acid, typically
acetic acid, required is between 0.5 and 50 mole %. To
simplify the MMP production process, the catalyst and acid
can be previously combined in a premix and metered in as a
solution. The concentration of catalyst premix in the
liquid MMP reaction medium is generally 0.2 to 0.75 wt.%.
On completion of the reaction, the MMP is separated from
the auxiliary substances and by-products by distillation.
During the purification by distillation of the addition
product thus produced, the catalyst premix is lost and,
depending on its boiling point, it has to be disposed of
via the distillation bottoms or the waste gas. In
principle, parts of the catalyst or the added acid can pass

overhead during the distillation and contaminate the
desired pure MMP.
A disadvantage of this process, besides the consumption of
the catalyst, is the multi-step synthesis of MMP. Thus, the
required intermediate, acrolein, has to be produced in a
complex manner by selective oxidation from propene in the
gas phase and isolated in a multi-step work-up.
According to the prior art, the synthesis of acrolein takes
place by heterogeneously catalysed selective oxidation of
propene on mixed oxide catalysts. EP 417723 describes the
synthesis on complex multi-metal mixed oxide catalysts at
temperatures of 300 to 380°C and pressures of 1.4 to
2.2 bar. In Ullmann's Encyclopedia of Industrial Chemistry,
6th edition, 1999, the entire process is described,
including the work-up, where several by-products are
separated off. After the educt mixture of propene, air and
water has been at least partly reacted on the catalyst,
quenching first takes place to eliminate high-boiling by-
products, such as polymers, acrylic acid and acetic acid.
In the subsequent absorber, acrolein is washed out. After
desorption to recover the absorbent, the crude acrolein
obtained is purified by distillation in several steps.
Up to the present, glycerol has not been used for the
synthesis of MMP. Furthermore, the direct synthesis of MMP
from glycerol is not known. However, it is known that
glycerol can be dehydrated in the presence of acidic
substances to form various products.
According to Organic Synthesis I, 15-18 (1964), by treating
a mixture of powdered potassium hydrogen sulfate, potassium
sulfate and glycerol at 190 to 200°C, acrolein is obtained
in a yield of between 33 and 48%. Because of the low yields
and the high salt loads, however, this process is
unsuitable for an industrial scale.

In the context of investigations into model substances of
biomass pyrolysis oils, the catalytic treatment of glycerol
on H-ZSM5 zeolites at 350 to 500°C has also been
investigated - cf. Dao, Le H. et al. ACS Symp. Ser.: 376
(Pyrolysis Oils Biomass) 328-341 (1988). Hydrocarbons are
formed only in small yields.
In DE 42 38 493, moreover, the acid-catalysed conversion of
glycerol to acrolein in the gas and in the liquid phase is
described. DE 42 38 492 relates to the synthesis of 1,2-
and 1,3-propanediol by dehydration of glycerol with high
yields.
For the direct synthesis of MMP from glycerol, however, in
addition to the involvement of dehydration steps, the
simultaneous selective incorporation of a sulfur-containing
Compound, such as methyl mercaptan, is necessary.
According to the invention, a process particularly for the
production of MMP from glycerol without the isolation of
intermediates is provided, wherein the multi-step synthesis
of MMP according to the prior art can now be carried out in
one step using a suitable catalyst.
The invention provides a process for the production of
compounds of the general formula

in which
R signifies H, C1 to C3 alkyl, by the reaction of glycerol
or of a compound from which glycerol is released, with a
compound of the general formula

in which

R signifies H, C1 to C3 alkyl
or compounds from which this (II) is produced,
in the presence of a catalyst.
The preferred product is MMP, which is produced using
methyl mercaptan.
In this process, for example a glycerol-methyl mercaptan
mixture is reacted, optionally in the presence of a
solvent, either in the liquid phase or in the gas phase, on
a preferably acidic solid catalyst.
If the synthesis takes place in the liquid phase, work is
carried out at a reaction temperature of between 50 and
500°C, preferably between 80 and 3500°C, particularly
preferably between 120 and 300°C. The pressure is adjusted
such that the liquid state of the reaction mixture is
maintained. The pressure is generally between 1 and
300 bar, preferably between 5 and 200 bar, particularly
preferably between 20 and 150 bar. In the liquid phase, the
synthesis can be carried out in the presence of either a
homogeneous or preferably a heterogeneous catalyst.
In the liquid phase, the use of a solvent or diluent is
also preferred. As a result of this, the concentration of
glycerol is reduced and side reactions to oligomers,
polymers and other high boilers are minimised. Solvents and
diluents known to the person skilled in the art, such as
e.g. water, alcohols, such as e.g. methanol and ethanol,
acetone, toluene or methyl isobutyl ketone, are used. MMP
itself can also be employed as a solvent, which has the
advantage that no additional substance is used and thus the
work-up is simplified.
In the reaction mixture, the glycerol concentration is
between 1 and 100 wt.%, preferably between 1 and 70 wt.%
and especially between 5 and 40 wt.%, based on the solvent
or diluent. The molar ratio between glycerol and methyl

mercaptan is adjusted to between 0.2 and 50, preferably
between 0.4 and 30, especially between 0.8 and 10.
In general, a homogeneous solution is advantageous for good
mass transfer, but is not absolutely essential here. This
can even be exploited in a targeted manner through the
principle of two-phase catalysis, in which e.g. exclusively
the product MMP is soluble in the solvent phase. If the
reaction product MMP is insoluble in the reaction medium,
the product can be separated from the reaction medium by
phase separation without a complex work-up and thus the
entire process can be simplified.
If the synthesis takes place in the gas phase, the reaction
is performed at a temperature of between 200 and 550°C,
preferably between 220 and 450°C, particularly preferably
between 250 and 350°C. The pressure is generally between 1
and 100 bar, preferably between 1 and 70 bar, particularly
preferably between 1 and 30 bar. In the gas phase, the
synthesis is carried out in the presence of a solid
catalyst.
The use of a diluent is also preferred in the gas phase.
This reduces the concentration of glycerol to the values
given above, and thus side reactions forming oligomers,
polymers and other high boilers are minimised. Diluents
known to the person skilled in the art are used, such as
e.g. nitrogen, air or water. Diluting media that can be
simply isolated from MMP by phase separation after
condensation are preferred.
Regardless of whether the process takes place in the gas or
liquid phase, by using glycerol as a raw material the
concentration of reactive intermediates, such as possibly
acrolein, allyl alcohol, acrolein acetals, 3-hydroxy-
propanal or radical and ionic compounds with three carbon
atoms, is adjusted to a comparatively low level by further
reaction to MMP, since these intermediates can undergo

rapid further reaction to form MMP. A high concentration of
reactive intermediates would lead to increased formation of
high-boiling residues and is therefore undesirable.
However, according to the prior art, for example, acrolein
is still worked up in a high concentration and used as an
isolated intermediate.
Moreover, through the conversion of glycerol to dehydrated
reactive compounds, which undergo rapid further reaction in
the presence of methyl mercaptan to form MMP, very high
conversions of glycerol are possible without the formation
of high-boiling by-products.
MMP that has formed can then be separated out of the
reaction mixture by a known method, alone or together with
part of the solvent or diluent medium, by stripping,
distillation or extraction. Unreacted glycerol can then be
recycled into the reaction step.
Another advantage of the process lies in the fact that even
glycerol solutions with a content of 5 to 40 wt.% can be
used. Thus, so-called crude glycerols may be employed
directly for the synthesis of MMP without previous
concentration or purification.
The implementation can take place in reaction vessels known
to the person skilled in the art, such as e.g. fixed bed
reactors, stirred vessels, stream tubes or bubble columns.
Methyl mercaptan can be used here in either liquid or
gaseous form. Moreover, it can be employed as a pure
substance or as crude methyl mercaptan with impurities,
such as e.g. methanol, dimethyl sulfide, dimethyl
polysulfides, hydrogen sulfide or dimethyl ether. The use
of crude methyl mercaptan has the advantage that a cheaper
raw material can be employed, requiring no further working
up.

Insoluble substances which, in addition to the dehydration
of glycerol, at the same time selectively accelerate the
incorporation of methyl mercaptan into MMP are generally
used as acidic heterogeneous catalysts. These preferably
have an H0 value of less than +2, especially less than -3.
The H0 value corresponds to the Hammett acidity function
and can be determined by so-called amine titration using
indicators or by adsorption of a gaseous base - cf. Studies
in surface science and catalysis, vol. 51, 1989: "New solid
acids and bases, their catalytic properties", K. Tanabe et
al., chapter 2, especially pages 5-9, chapter 1 (pages 1-3)
of the above document mentions numerous solid acids from
which the person skilled in the art, optionally after
determining the H0 value, can select a suitable catalyst.
Suitable catalysts are preferably (i) natural or synthetic
siliceous substances, such as in particular mordenite,
montmorillonite and acidic zeolites, such as e.g. HZSM-5,
MCM-22, zeolite beta; (ii) support materials, such as
oxidic or silicalitic substances, e.g. aluminium oxide,
titanium oxide, silicon oxide, zirconium oxide or mixtures
thereof coated with mono-, di- or polybasic inorganic
acids, especially phosphoric acid, sulfuric acid or acid
salts of inorganic acids; (iii) oxides and mixed oxides,
such as e.g. aluminium oxides, zinc oxide-aluminium oxide
mixtures or heteropolyacids.
The process can be carried out in the liquid or in the gas
phase. In principle, the same acid catalysts can be used in
both embodiments. However, it has been demonstrated that
some catalysts are preferably suitable for the gas phase
and others are preferably suitable for the liquid phase.
Thus, in the liquid phase, it is preferable to use acidic
zeolites because of their H0 value of less than -3. In the
gas phase, on the other hand, they are subject to more
rapid deactivation, which reduces the space-time yield.

Oxides and mixed oxides, on the other hand, provide the
better yields in the gas phase.
When carrying out the conversion of glycerol to MMP in the
liquid phase, correspondingly acidic homogeneous catalysts,
which are soluble in the reaction mixture, can also be
used. These homogeneous catalysts can be used alone or in
combination with one of the heterogeneous catalysts
described here.
In another embodiment of the invention, methyl mercaptan is
not added to the reaction mixture immediately at the
beginning of the reaction but is fed in only after reactive
intermediates have formed under the conditions stated
above, at least from partial quantities of glycerol. The
reactive intermediates form MMP by further reaction after
methyl mercaptan has been added. On the one hand, this
method facilitates the conversion of glycerol to dehydrated
reactive intermediates and reduces non-selective reactions
between glycerol and methyl mercaptan. As a result, the MMP
yield can be improved. At the same time, moreover, by
carrying out the reaction in this way, the complex
separation of acrolein according to the prior art can be
avoided and the reaction to MMP conducted in one reactor.
This can take place on the one hand in a batchwise process,
the methyl mercaptan being added to the reaction mixture
after a certain reaction period. A stirred vessel, for
example, would be suitable for this implementation. A
further possibility is a semi-continuous method, in which
the glycerol solution and the catalyst are the initial
charge and the methyl mercaptan is metered in continuously.
On the other hand, it is also possible to feed in methyl
mercaptan only at a point removed from the reactor entrance
in the direction of flow or in another section of the
reactor. By the time the glycerol solution and the catalyst
reach this point, part of the glycerol has already been

converted to reactive intermediates. This method can be
implemented industrially e.g. in a staged reactor with
intermediate feed, a stirred vessel cascade or a stream
tube.
Another advantage of the delayed or later addition of at
least a major portion of the methyl mercaptan lies in the
fact that the yield of MMP can be increased, because the
temperature profile or temperature program can be adjusted
so that it is optimised on the basis of the reaction
behaviour of the reactants. Thus, the activation of
glycerol and its first dehydration step require a very high
activation energy and thus high reaction temperatures for
rapid production with high space-time yields. MMP, on the
other hand, has a tendency towards non-selective further
reactions at temperatures higher than approx. 100 to 150°C.
Thus, conducting the conversion of glycerol to MMP by
passing through decreasing reaction temperatures represents
a preferred embodiment.

Examples
Example 1
In an autoclave, 36 g glycerol and 19.5 g methyl mercaptan
were dissolved in 144 g methanol. 3.8 g of zeolite HZSM-5,
modulus 28 (H0 zeolite was calcined for 2 h at 150°C and 4 h at 500°C in
air in a drying oven before charging into the autoclave.
The mixture was then heated to 300°C in the autoclave, with
stirring. During this operation, a pressure of 61 bar was
established. After one hour, a sample was taken from the
mixture and analysed by gas chromatography. Taking into
account the proportion of solvent, the MMP content was
6.0 wt.%. None of the by-products or intermediates acrolein
and allyl alcohol could be detected.
Example 2
In an autoclave, 36 g of glycerol were dissolved in 80 g of
methanol. 3.8 g of zeolite ammonium beta CP 814E (H0 -3.0) from Zeolyst International were added to this
mixture. The zeolite was calcined for 2 h at 150°C and 4 h
at 500°C in air in a drying oven before charging into the
autoclave. The mixture was then heated within 4 h and
stirred at 300°C and 40 bar. After cooling to room
temperature, 19.5 g of methyl mercaptan and 68 g of
methanol were added. This new mixture was then heated to
100°C in an autoclave, with stirring. During this
operation, a pressure of 3 bar was established. After 30
min, a sample was taken from the mixture and analysed by
gas chromatography. Taking into account the proportion of
solvent, the MMP content was 0.8 wt.%.

WE CLAIM;
1. Process for the production of compounds of the general formula

in which
R signifies H, C1 to C3-alkyl, by the reaction of glycerol, or of a compound from which
glycerol is released, with a compound of the general formula

in which
R signifies H, C1 to C3-alkyl,
or compounds from which this (II) is produced,
in the presence of a catalyst, characterised in that an acidic solid catalyst, the H0 value
(Hammett acidity function) of which is less than +2, is used.
2. Process as claimed in claim 1, wherein R in formula II corresponds to methyl and MMP is
produced.
3. Process as claimed in claims 1 to 2, wherein the molar ratio of glycerol to methyl mercaptan
is between 0.2 and 50.

4. Process as claimed in claims 1 to 3, wherein a solvent or diluent is used.
5. Process as claimed in claims 1 to 4, wherein the glycerol in the reaction mixture is used in
dilute form with a content of 1 to 100 wt. %, preferably between 1 and 70 wt.% and
especially between 5 and 40 wt.%, based on the solvent or diluent.

6. Process as claimed in claim 4 or 5, wherein MMP is used as the solvent or diluent.
7. Process as claimed in claim 4 or 5, wherein water is used as the solvent or diluent.
8. Process as claimed in claim 4 or 5, wherein methanol is used as the solvent or diluent.
9. Process as claimed in claims 1 to 8, wherein the process takes place in the liquid phase.
10. Process as claimed in claim 9, wherein this takes place at pressures between 1 and 300 bar
and at temperatures between 20 and 500°C.
11. Process as claimed in claim 9, wherein an acidic zeolite is used as the catalyst.

12. Process as claimed in claims 1 to 2 and 3 to 8, wherein the process takes place in the liquid
phase in the presence of a homogeneous catalyst at temperatures between -10 and 500°C and
pressures between 1 and 300 bar.
13. Process as claimed in claims 1 to 8, wherein the process takes place in the gas phase.
14. Process as claimed in claim 13, wherein this takes place at pressures between 1 and 100 bar
and at temperatures between 200 and 550°C.
15. Process as claimed in claim 13 or 14, wherein a catalyst with an Ho value of less than -3 is
employed.
16. Process as claimed in claims 1 to 15, wherein methyl mercaptan is added to the reaction
mixture in a quantity of > 0% after the conversion of partial quantities of the glycerol to
intermediates, or in that a reaction mixture containing glycerol and glycerol that has been
converted to intermediates is metered into methyl mercaptan.
17. Process as claimed in claim 16, wherein the reaction takes place in at least two spatially
separate zones, glycerol being at least partly converted in the first reaction zone and methyl
mercaptan being fed into the subsequent reaction zone.

18. Process as claimed in claim 17, wherein different temperatures are present in the two reaction
zones, the temperature in the first reaction zone being higher, at 150 to 400°C, than that in
the subsequent zone, in which the temperatures are between 0 and 100°C.
19. Process as claimed in claims 17 and 18, wherein methyl mercaptan or the majority thereof
(>50%) is fed in only after cooling the glycerol, or the reaction mixture containing
intermediates formed therefrom, to 20 to l50°C.


ABSTRACT

Title: PRODUCTION OF 3-(ALKYLTHIO) PROPANAL
Process for the production of compounds of the general formula

in which
R signifies H, C1 to C3-alkyl, by the reaction of glycerol, or of a compound from which
glycerol is released, with a compound of the general formula
R-SH (II)
in which
R signifies H, C1 to C3-alkyl,
or compounds from which this (II) is produced,
in the presence of a catalyst, characterised in that an acidic solid catalyst, the H0 value
(Hammett acidity function) of which is less than +2, is used.

Documents:

02766-kolnp-2007-abstract.pdf

02766-kolnp-2007-claims.pdf

02766-kolnp-2007-correspondence others.pdf

02766-kolnp-2007-description complete.pdf

02766-kolnp-2007-form 1.pdf

02766-kolnp-2007-form 2.pdf

02766-kolnp-2007-form 3.pdf

02766-kolnp-2007-form 5.pdf

02766-kolnp-2007-gpa.pdf

02766-kolnp-2007-international publication.pdf

02766-kolnp-2007-international search report.pdf

02766-kolnp-2007-others.pdf

02766-kolnp-2007-pct request form.pdf

02766-kolnp-2007-priority document.pdf

2766-KOLNP-2007-(04-04-2012)-ABSTRACT.pdf

2766-KOLNP-2007-(04-04-2012)-AMANDED CLAIMS.pdf

2766-KOLNP-2007-(04-04-2012)-DESCRIPTION (COMPLETE).pdf

2766-KOLNP-2007-(04-04-2012)-EXAMINATION REPORT REPLY RECEIVED.pdf

2766-KOLNP-2007-(04-04-2012)-FORM-1-1.pdf

2766-KOLNP-2007-(04-04-2012)-FORM-1.pdf

2766-KOLNP-2007-(04-04-2012)-FORM-2.pdf

2766-KOLNP-2007-(04-04-2012)-FORM-3.pdf

2766-KOLNP-2007-(04-04-2012)-FORM-5.pdf

2766-KOLNP-2007-(04-04-2012)-OTHERS.pdf

2766-KOLNP-2007-(04-04-2012)-PA.pdf

2766-KOLNP-2007-(04-04-2012)-PETITION UNDER RULE 137.pdf

2766-KOLNP-2007-(13-08-2012)-CORRESPONDENCE.pdf

2766-KOLNP-2007-CORRESPONDENCE.pdf

2766-KOLNP-2007-EXAMINATION REPORT.pdf

2766-KOLNP-2007-FORM 13 1.2.pdf

2766-KOLNP-2007-FORM 13-1.1.pdf

2766-KOLNP-2007-FORM 13.1.pdf

2766-KOLNP-2007-FORM 13.pdf

2766-KOLNP-2007-FORM 18.pdf

2766-KOLNP-2007-FORM 3.pdf

2766-KOLNP-2007-FORM 5.pdf

2766-KOLNP-2007-GPA.pdf

2766-KOLNP-2007-GRANTED-ABSTRACT.pdf

2766-KOLNP-2007-GRANTED-CLAIMS.pdf

2766-KOLNP-2007-GRANTED-DESCRIPTION (COMPLETE).pdf

2766-KOLNP-2007-GRANTED-FORM 1.pdf

2766-KOLNP-2007-GRANTED-FORM 2.pdf

2766-KOLNP-2007-GRANTED-SPECIFICATION.pdf

2766-KOLNP-2007-OTHERS.pdf

2766-KOLNP-2007-PA.pdf

2766-KOLNP-2007-REPLY TO EXAMINATION REPORT.pdf


Patent Number 255310
Indian Patent Application Number 2766/KOLNP/2007
PG Journal Number 07/2013
Publication Date 15-Feb-2013
Grant Date 11-Feb-2013
Date of Filing 27-Jul-2007
Name of Patentee EVONIK DEGUSSA GMBH
Applicant Address RELLINGHAUSER STRASSE 1-11, 45128 ESSEN, GERMANY
Inventors:
# Inventor's Name Inventor's Address
1 DR. HUBERT REDLINGSHÖFER STEIGERWALDSTR. 9 91481 MÜNCHSTEINACH
2 DR. KLAUS HUTHMACHER LÄRCHENWEG 18 63571 GELNHAUSEN
3 DR. ACHIM FISCHER WILLIGISSTR. 9 63739 ASCHAFFENBURG
4 DR. JAN-OLAF BARTH ZIEGELHÜTTENWEG 23 60598 FRANKFURT
5 DR. CHRISTOPH WECKBECKER AUGUST-IMMHOF-STR. 25 63584 GRÜNDAU-LIEBLOS
PCT International Classification Number C07C 319/08
PCT International Application Number PCT/EP2006/050132
PCT International Filing date 2006-01-10
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10 2005 003 990.1 2005-01-28 Germany