DE1643793C3 - Process for the production of alkenyl sulfonates and alkenyl sulfonates - Google Patents

Description

to have. The lower levels of filtration, centrifugation or decantation are particularly advantageous. The ketone, like acetone. If aqueous sodium sultone can be isolated from the solution in various ways hydroxide is used as a base, the lower dissolves. You can cool the solution, ketone the base in sufficient amount to z. B. to a temperature below 15 ° C, namely to facilitate about setting to the sulfonic acid salt. This 5 0 to 10 ⁰ C, and it is in one or more sultone salts in the lower ketone in turn seeded enough crystals to precipitate the sultone, whereupon insoluble to precipitate in high yields. the solvent, which does not yet form small amounts. In addition, the lower ketone can contain precipitated sultons at room temperature, preferably temperature and higher temperatures, but not at _{low temperatures for dissolving further SO 8} -OIeSn, a good solvent for io product is used. A continuous Ver-Sultone, so that the Sultone can then easily be driven, consist, for example, in that one can be separated from the solution. When using an -olefin in one or more stages of continuous water-immiscible solvents, ierlich reacts with SO ₃ , the resulting acids such as hydrocarbons, e.g. B. pentane, it is difficult to achieve a rapid and thorough conversion of the 15 treated and the resulting "acid mixture II" aqueous base with the dissolved sulfonation product to form a precipitate of sodium alkenylduct. and it is usually necessary to continuously stir stronger sulfonate and a <5-sultone solution in the, recovered solvent and wash with Na-

The solvents mentioned can also form triuinhydroxide! «, Whereupon the Sulton

Washing the precipitate after its separation cools ao solution, inoculates and precipitates the sultone

can be used from the solution. the supernatant liquid is returned. The

The solvent is used in an amount of 3 to solvent can also be distilled off, so that

5 parts by weight per part by weight of acid mixture without the sultone remaining. Furthermore, one can see the Sulton

special heating or cooling, e.g. B. use temperature solution as such for reactions, in

ratures between about 15 or 20 to 40 or 50 ⁰ C »5 which the sultone in the presence of the solvent

or above, added. is transferred to other products.

The alkali hydroxide can be in dry form, e.g. B. According to an embodiment of the powder according to the invention or, preferably, as a fairly concentrated process, this can also be added for the production of trated aqueous solution. Excellent results from solid mixtures of other active detergents are obtained , for. B. be applied when using the alkenyl sulfate. For this purpose, sodium hydroxide is used in the form of a 50 ° aqueous an aqueous dispersion of another long-chain solution. Good results have also been achieved with a sodium sulfonate, e.g. B. obtained a higher alkylbenzenesulfonate trium methylate solution in ethanol, which is mixed as a detergent with the base, which leads to the moderate temperatures, e.g. B. at room temperature, solution of the sulfonation product in the organic is not added to a substantial conversion of the sultone 35 solvent. Instead of the alkylin sulfonic acid leads. Other suitable bases are benzenesulfonate, other anion-active sodium alcoholates, e.g. B. sodium ethylate and detergent raw materials, e.g. B. other sulfonates or sulfates, basic salts, e.g. B. carbonates. The temperature such as sodium tallow alcohol sulfate, or suitable not during the treatment with the base, can be used in the ionic detergent raw materials. In addition to about 15 or 20 to 50 ° C. or above, the solution of the base can also be water-soluble. Attempts with non-alcoholic solutions, such as condensed phosphates, z. B. means, such as acetone or pentane, showed that the pentasodium tripolyphosphate and tetrapotassium pyro boiling point of the solvent no essential phosphate, or organic builders such as Na hydrolysis or other conversion of the sultone in trium nitrilotriacetate are mixed in, so that occurs as sulfonic acid. The base is generally used directly containing a builder in an amount that corresponds to the acid content of the detergent. The at least stoichiometric amount of builders added to the reaction mixture in this way can be about 0.5 to 20 and is equivalent. It is often expedient to use approximately 2 to 10 parts per part of organic detergent to ensure complete neutralization.

Excess of base, for example 20%, to be used. The used for the reaction with the SO ₃

turn. A very large excess of base is less olefinic starting material can monoolefins

expedient because the base and entrained water contain the _{general formula RCH = CHR 1 in which}

can be trapped by salt precipitation. R is an alkyl radical and R _{1 is} an alkyl radical or water

It does not necessarily have to be a base, substance, preferably hydrogen, is, the alkyl

which leads to a sodium salt, rather 55 residues 8 to 30 and preferably 12 to 21 carbon

bases are also used which contain other alkali metal atoms. The starting material can

shown as KOH ode _t LiOH, or ammonium small amounts of other ingredients such as se-

salt-forming bases. secondary or internal olefins, diolefins, cyclic olefins

The solution of the acid mixture in the organic fine, aromatic, naphthene and alkane solvent is generally chocolate brown. 60 and through the cracking of petroleum wax, catalytic With the progressive addition of bases, it then suddenly becomes pale yellow, polymerization of ethylene, dehydration, and the desired chain alcohols etc. are produced. The best white precipitation. Before the color change, a few flakes of dispersed precipitate can be obtained with a starting material, of which more than 70% and preferably to form. 65 at least 90%> consisted of α-olefins (R ₁ = H).

Contains a particularly preferred starting material after the precipitation of the alkenyl sulfonate

Treatment with the base leaves about 12 to 21 lower carbon atoms in the olefin molecule

blow easily separate from the solution, z. B. by and gives alkenyl sulfonates with excellent

Washing properties. Particularly good foam and cleaning properties were found in use obtained a starting material whose -olefins essentially contained 15 to 18 carbon atoms.

The sulfonation is preferably carried out at a molar ratio (volume) of inert gas to SO ₃ of 5: 1 to 100: 1 and in particular of at least about 10: 1, e.g. B. 50: 1 to 20: 1.

Suitable inert gases for diluting the sulfur trioxide are air and nitrogen. Furthermore, carbon dioxide, Sulfur dioxide, low molecular paraffinic hydrocarbons, etc. can be used. The gaseous one Sulfur trioxide can either be obtained by evaporating stabilized liquid sulfur trioxide or as converter gas can be obtained from a sulfur burner.

In carrying out the reaction between the _SO3 and the olefin is advantageously maintained in a continuous manner, intimate contact between the gaseous SO ₃ and the olefin, by allowing the SO ₃ act on one or both sides of a thin flowing Olefinfilms, z. B. by introducing _{SO 3} into the middle of a tube, over the inner wall of which a thin olefin film flows down

During this reaction is maintained suitably at a temperature of below 60 ° C, with a temperature of below about 50 ° C and, if possible, (e.g., in the range of about 10 to 4O. ^'; C) of at most 40 ° C is preferred. In general ^; Work should be carried out at a temperature at which the sulfonation product remains liquid. The lowest possible temperature is advantageously used, l. B. a temperature which is 5 ° C or less above the temperature at which solidification or precipitation occurs. Since the reaction between the SO ₃ and the olefins is exothermic, cooling is expedient, e.g. B. using a cooling medium such as water in a jacket surrounding the reaction tube.

A typical "acid mixture I" obtained with a molar ratio of SO ₃ to olefin of 1: 1 contains about 35 mol percent of anionic substance, based on the moles of olefin, as can be determined by titrating the acid mixture with a standard solution of cetyltrimethylammonium bromide. The "acid mixtures I and II" generally consist of dark brown viscous masses that have about the appearance of melted chocolate.

To obtain the "acid mixture II", the sulfuric acid can be used as a separate stream in the form of an aqueous, e.g. B. 60% solution or as lOOVoige sulfuric acid or as oleum, ζ. Β. Add 65% oleum. Excellent results were obtained with 20% oleum and with 90 or 97% sulfuric acid solution. Acid mixtures obtained with sulfuric acid solutions are preferred because they are more economical in material consumption and give lighter products. The optimum amount of sulfuric acid to be introduced into this process stage depends on the reaction conditions in this stage and in the preceding stage. In general, about 2 to 300 parts by weight of sulfuric acid are added to 100 parts by weight of "acid mixture I". In the case of "acid mixtures I" which have been prepared with 0.8 to 1.2MoI SO ₃ per mole of olefin, the sulfuric acid is preferably used in an amount of 2 to 100 parts by weight, e.g. B. from 2 to 50 parts by weight, per 100 parts by weight of "acid mixture I" added Even when using 6O ³ / oiger aqueous sulfuric acid, the amount of water introduced with the added acid is only small, for example less than 10 percent by weight of the "acid mixture I". In the preferred embodiment, less than 5% and generally less than 3% water are introduced in this way. In contrast to treatment in a dilute aqueous medium, the sulfuric acid treatment here takes place under practically non-hydrolyzing conditions.

It is preferably carried out at a temperature at which the mixture remains in a flowable state, ie at about 10 to 100 ° C and preferably at about 25 to 60 ° C. The duration of the sulfuric acid treatment is expediently relatively short and is preferably less than about 1 Lesson. For best results, treatment times of less than about 20 minutes, e.g. B. of 5 minutes or less achieved. Good results are even obtained if the sulfuric acid is added to "Acid Mixture I" less than 1 minute before the treatment with the alkaline neutralizing agent.

The sulfuric acid can be added in any suitable device, preferably one in which the components are mixed with one another quickly and thoroughly. Advantageous in a continuous process is such. B. the introduction of the "acid mixture I" and the sulfuric acid in a circulation loop. Good results are also achieved if the sulfuric acid is introduced into "Acid Mixture I" while it is passing through the sulfonation device. For example, in a process in which the olefin flows down as a film in a vertical pipe about 6 m high and at the same time dilute SO ₃ is introduced into the pipe from above, the sulfuric acid can be introduced about halfway up the pipe. In another way of working, the sulfuric acid and the "acid mixture I" can be fed to a pump at one end of a longer pipe which leads into the neutralization zone without being recirculated.

The invention will now be illustrated by the following examples explained, in which all quantities relate to weight and at atmospheric pressure was worked, unless otherwise noted. Furthermore, all solutions were at around room temperature (e.g. 20 ° C), with a slight increase in temperature due to the heat of neutralization entered. The inventive method can of course not only on alkenylsulfonic acids and Mixtures containing sultones, but rather generally applied to olefin / S0, reaction mixtures which contain components which, when a base is added, water-soluble olefin sulfonate salts form.

example 1

From a practically straight-chain «monoolefin with 18 carbon atoms (produced by anionic polymerization of ethylene) existing starting material was introduced from above into a 6 m high reaction tube at a rate of 18.14 kg / h, so that it flowed down as a film on the inner wall of the pipe.

At the same time, roll the dice in the middle of the reaction tube

1 O tJ I

7 ^ 8

res from above a gas mixture of air and 4 volume could y-sulton by crystallization or

percent SO _{3 can be obtained} at a rate of 6.35 steam,

kg / h SO ₃ introduced. The reaction tube with a, · ι -

Temperature from about 40 to 50 ⁰ C leaving Example 5
"Acid Mixture I" was looped around at 5. Example 1 wunle using 0.5

about 40 ° C for about 2 to 5 minutes with 97% parts of aqueous 30% NH ₄ OH solution in place

Treated sulfuric acid, which is repeated with a speed NaOH solution. The ammonium

speed of 2.27 kg / h was introduced. alkenyl sulfonate formed as a gummy mass,

A part of the chocolate-colored which was obtained in this way was separated from the acetone solution and in "acid mixture II" was very easily dissolved in 3 parts of acetone in hot water,
solves. This solution was, with continued rest. .
Ren slowly with 0.35 parts of aqueous SOVoiger Example 6
NaOH solution added. The color of the brown micro In this example, an "acid mixture II" research beating out suddenly to yellow to, and used for their production as Ausgangsmabildete a snow white precipitate of sodium 15 TERIAL a tube C ₁₅ -C ₂₀ - OIeBn with a boiling tetrium alkenyl sulfonate and sodium sulfate at a range of about 275 to 315 ° C (8% residue) contained 81% of anionic substance. It was found that by cracking paraffin wax no separate aqueous phase was obtained from olefin sulphate and was observed according to the information provided by Herfonatlösung. After discontinuing the steller had the following composition:
Precipitation was the supernatant organic ao

Layer sucked off, cooled to O ^ C and with some acyclic monoolefins 84Vo

Crystals of the corresponding Λ-sultone with 18C-diolefins and naphthenic olefins. 9Vo

Atoms inoculated. Crystals of pure Λ-Sul-Paraffine and Naphthene S · / fell.

sound off. This very pure crystals were abfil- ^r

freezes. The solvent was used to dissolve additional, 5 cyclic diolefins and dicychian

"Acid mixture II" returned. uietine i / o

The sodium alkyl sulfonate obtained also had aromatics IVo

very light color without bleaching. The same result was obtained when using methyl ethyl ketone. The acylic monoolefins passed 92% instead of acetone and 0.5 part of 50Voiger 30 ”monoolefins. The average molecular KOH solution obtained in place of the NaOH solution. weight of the monoolefins was about 240, and the

Distribution of the olefins was as follows: 2VoC ₁₄ , 18Vo

Example 2 _c ^ ₂ q «/" C, _e , 21 Vo C ₁₇ , 18VoC ₁₈ , 16VoC ₁₉ , 5VoC ₂₀ .

A part of the acid obtained according to Example 1 A part of this acid mixture was divided into 3 parts

mixture II "was dissolved in 2 parts of anhydrous ethanol 35 acetone, the solution under reflux to the

solved. This solution was heated with a solution of boiling. The refluxed

0.25 part of sodium methylate in 1 part of anhydrous mixture was added slowly with continued stirring

Ethanol added. The same result was obtained as with 0.35 part of aqueous SOVoiger NaOH solution.

obtained in example 1. puts. The color was the same as in Example 1

40 µm and a light yellow precipitate formed

B is ρ 1 e 1 3 _from sodium alkenyl sulfonate The precipitate had

Example 1 was repeated using a pen, the Klett color number 240 (measured after the error in place of acetone. Because of the thin substance anionic to 5Vo with water). Immiscibility of the NaOH solution with the pentane In contrast to this, neutralization in super-solution resulted in the need to stir more vigorously and longer to achieve the desired volume of aqueous medium without the addition of acetone. Then there is a Velcro color number of over 900.
the same result as in Example 1 was obtained in Example 7

B ei sρ ie 1 4 _Es W _111x Je _n iqo parts of an aqueous 46 percent composition

Example 1 was repeated, but the slurry was largely biodegradable

Refrain from sulfuric acid treatment and the »acidic straight-chain sodium tridecylbenzenesulfonate with 16

mixture I «, the 31 ^e / o anion-active substance and parts of aqueous SOVoiRir NaOH mixed and added

tf ° '"" contained free oil *, dissolved in acetone and treated with Na- a solution of the> acid-

-ϊί-JtmimTwdiTOHdKsHHg treated Bs formed so- arisdnmgll «ia §00 Teüea Aoeft» given. the

* V fattgm snow-white precipitate, the sodium 55 Faifeeder AcetorfösuiigSchlugnachGeftnai, nodes

fjäto-tifistMoeat nnd sen * werag Natrinmsaliat bathed ice cream scämeeweffier Nsäießcnfeg on the Na-

iAcnücm Gefeit of ammonia substance ναα 95.5 · / · trinmalkenyfcoSoffiit
" . Aas <S» tön m & äsM & bdke & Ba solution

'Vj 534 f

Claims (6)

suggested. Thus, the sulfonation mixture obtained in the implementation of patent claims: "SO3 and an olefin can be subjected to vacuum distillation. Even 1. Process for the production of alkenyl for sultones with relatively low molsulphonates and su »tones by converting 5 kular weight, however, a high vacuum of gaseous sulfur trioxide with C ₁₁ -C ₃₀ -S-OIe is required for this. In addition, the material is set in the fine and subsequent neutralization of the erhaj distillation of undesirably high temperatures austenic acid mixture with an aqueous alkali. The yields of sultone achieved are hydroxide solution, which is characterized by relatively low levels, and the distillate is often contaminated by the fact that per part by weight of acid mixture, Cj-Cj alcohols, hydrocarbons, ethers or sulfonic acids. These acids are added to halogenated hydrocarbons and then converted to new barium or sodium salts, from which the acids are neutralized and released again. 2. The method according to claim .1, thereby splitting off at elevated temperature, z. B. 120 bi indicates that a water-soluble ketone is 180 ° C, these are then returned to the sultones. or a water-soluble alcohol is added, which is distilled off under vacuum. 3. The method according to claim 1 and 2, characterized according to the older DT-AS 1240071 has also characterized that with sodium hydroxide already neutralized by sulfonation of olefins and after about 15 to 50 ° C, 20 following treatment with dilute alkalis Only so much water is used that practically no reaction products for removing the sultones are formed in a liquid aqueous solution of the salt. extracted with hydrocarbon solvents. This 4. The method according to claim 1 to 3, characterized in this way of treatment, however, due to the high characterized in that the acid mixture is emulsified before it contains surface-active sulfonates Mixing in the organic solvent * 5 ions that are difficult to separate. Besides that under non-hydrolyzing conditions with the DT-AS at least causes at increased temperature 60% sulfuric acid treated. ratures carried out hydrolysis the formation of 5. The method according to claim 1, characterized ge hydroxyalkanesulfonates, which are used as washing raw materials indicates that the alkali hydroxide solution is less desirable. before adding to the mixture of acid 3 ° According to the process according to the invention, the mixture and organic solvent with separation of the alkenyl sulfonates and sultones in an aqueous solution of another washing extremely simple and economical way thereby active sulfonate added. achieved that one by sulfonation 6. The method according to claim 5, characterized in that the acidic mixture obtained is olefins (hereinafter referred to as indicates that another active washing 35 is called "acid mixture I") with a solution sulfonate Sodium Cg-Cjj-alkylbenzoisulphonate mediated for the sultone mixed and then mixed with one turns. Base mixed with the sulfonic acid of the olefin Forms water-soluble salt, so that a precipitate of the sulfonic acid salt and a solution of the sultone 40 is created. So you get a practically dry one white alkenyl sulfonate which is essentially free of sultone and unreacted olefin and a Solution from which the Sulton can be easily obtained, e.g. B. by The invention relates to a process for the production of crystallization, which can be separated off. The danger of the formation of alkenyl sulfonates and sultones through formation of aqueous emulsions, which are stabilized by the sulfonate conversion of gaseous sulfur trioxide with scrubbing raw material and therefore only C ₈ -C ₃ -ft olefins and subsequent neutralization are difficult to handle and separate leave, the acid mixture obtained does not exist with an aqueous one. Alkali hydroxide solution, which is characterized according to a preferred embodiment of the is that per part by weight of acid mixture 3 to s ° according _{to the invention are added the parts by weight of solution of a lower ketone, C 1} -C ₃ -AlkO- agent and the base to a reaction mixture, the hols, hydrocarbon, ether or halogenated alcohol by treatment of the reaction product from hydrogen is added and then neutralized. SO ₃ and olefin obtained with strong sulfuric acid The production of olefin sulfonates by Um- was. A product which is treated in this way and is subsequently used to settle olefins with a gaseous sulphonic acid, known as "acid mixture II", contains a mixture of sulfur trioxide and a substantially higher proportion of alkenyl sulphone inert gas is known. Usually the SO ₃ in acids is called the "Acid Mixture I". In addition, amounts of about 1 mol, for example 0.9 to 1.4 mol, each "acid mixture II" contains large amounts of rV-sulfons, mol of olefin used. which can easily be derived from the In order to be able to separate the solutions obtained as washing machines from the sulphonation product.
To obtain olefin sulfonates valuable as a raw material, as a solvent for the inventive use, this is done with an aqueous alkali solution or in hydrocarbons or halogenated aqueous acidic solution are hydrolyzed with heating. Hydrocarbons, e.g. B. Pentane and Methylene-The products thus obtained contain considerable chloride. and ethers, such as diethyl ether, are used. Amounts of undesirable, non-surface-active 65 However, preference is given to using "free oil" with water and being dark in color. miscible ketones and alcohols, e.g. B. acetone, There are already various processes for separating methyl ethyl ketone, ethanol, methanol or isoprope the sultones from the sulfonation product panol, the reduced tendency to form emulsions