DE1138385B - Process for the preparation of salts of aliphatic dicarboxylic acids or the free dicarboxylic acids - Google Patents

Description

Process for the preparation of salts of aliphatic dicarboxylic acids or the free dicarboxylic acids are aliphatic dicarboxylic acids or their salts valuable raw materials for the production of plasticizers, plastics, etc. You have so far generally obtained from unsaturated fatty substances, such as. B. azelaic acid by ozonization of oleic acid or sebacic acid by alkali cleavage of ricinoleic acid. In these processes, however, the carbon chain becomes the starting material shortened, and the quantitative yield of dicarboxylic acids is correspondingly lower. Adipic acid is accessible by oxidation of cyclohexanol, with no chain shortening takes place, but here, as with the previously mentioned procedures, one is at the Production of a very specific dicarboxylic acid, azelaic acid, sebacic acid or bound to adipic acid and has no way of starting materials select the production of dicarboxylic acids with any carbon number allow.

It has now been found that the telomerization of low molecular weight aliphatic olefin compounds with cyanogen chloride easily accessible oc, M-chlorofatty acid nitriles can easily be converted into dicarboxylic acid salts if they are basic with reactive substances, preferably in the presence of solvents for these substances, heated. The free dicarboxylic acids can be derived from the salts in a manner known per se Isolate methods. For the sake of simplicity, the dicarboxylic acids Salts are usually no longer explicitly mentioned, but the expression becomes general "Dicarboxylic acids" are used, even if, according to the situation, the appropriate Salts should be present.

In this reaction, the nitrile group becomes a carboxyl group converted. This can be done in stages, e.g. B. via the amides or esters. Man can therefore also replace the chlorofatty acid nitriles with their saponifiable derivatives such as their amides, esters or finally the chlorofatty acids themselves or their salts as Use raw materials.

If you use telomerizates of ethylene as the starting material, so straight-chain dicarboxylic acids are obtained, while telomerizates are processed of the propylene contains branched-chain dicarboxylic acids. Of particular technical Of interest are the telomerizates in which at least 2, preferably 3 to 9 mol of an olefin have reacted with 1 mole of cyanogen chloride. In the case of ethylene, one obtains in this way chlorofatty acid nitriles with at least 5, preferably with 7 to 19 Carbon atoms, and in the polymerization of propylene in the presence of cyanogen chloride chloronitriles with at least 7, preferably 10 to 28 carbon atoms are obtained.

As already mentioned, the -chloronitriles can be used as such ; however, it is advisable to first convert the chlorocyanes to the chlorocarboxylic acids in a known manner to saponify, whereby it is advantageous to saponify acidic, because in this way one is nitrogen-free Products received. If the nitriles are used directly, nitrogen-containing ones are occasionally obtained End products from which the nitrogen can be removed by acid re-saponification leaves.

It has surprisingly been shown that in the inventive Process other than the dicarboxylic acids having the same carbon number as the starting material can also form dicarboxylic acids that contain twice the carbon number, and according to the key figures of these dicarboxylic acids, it can be assumed that this is the case to ether dicarboxylic acids of the general formula HOOC-RI-O-R2-COOH, in which Ri and R2 represent the hydrocarbon radicals of the starting compound. One goes assuming a uniform starting material, then Ri and R2 are the same; goes if, on the other hand, starting from mixtures of homologues, mixtures of ether dicarboxylic acids can arise, which contain asymmetrical dicarboxylic acids. This finding is particularly technical Interest, because long-chain ether dicarboxylic acids so far only on relatively cumbersome, technically hardly interesting ways were accessible, such as the one after the information from the German Patents 919 167, 836 936 and 759 483 ether dicarboxylic acids obtainable from lactones.

In the case of those required for carrying out the method according to the invention Basically reacting substances are inorganic, in water with alkaline ones Reaction soluble compounds.

These include primarily the oxides, hydroxides and carbonates the alkalis, especially sodium and potassium, alone or in any Mixture can be used with each other. Instead of alkalis you can also with the oxides or hydroxides of the alkaline earths, especially magnesium and calcium, Strontiums or bariums, mixed with the alkali compounds mentioned above, work can be, however, the formation of precipitation products, which the water does not give an alkaline reaction should be avoided.

For the conversion of the chloronitriles or chlorocarboxylic acids into the Ethereal dicarboxylic acids are theoretically 2 equivalents of a basic substance required per mole of chloronitrile or chlorocarboxylic acid.

However, it has proven to be useful to use the basic reacting Use substances in excess, in an amount of at least 2, 2, preferably 2.5 to 5 equivalents per mole of starting material. It can also be larger Amounts, e.g. 8 or 10 equivalents, can be used. One can also proceed like this that the carboxyl group is first converted into the salt form and used in this way.

It is advisable to carry out the reaction in the presence of solvents to be carried out, with water primarily being used as the solvent but partly or completely by water-soluble organic solvents, in particular can be replaced by alcohols having preferably 1 to 4 carbon atoms. The monoethers can also be used as water-soluble organic solvents from monohydric alcohols with 1 to 4 carbon atoms and glycols or polyglycols, derived from glycols with 2 or 3 carbon atoms. The amount of the solvent is at least 5, preferably 10 to 75 percent by weight of the entire reaction mixture.

A temperature of from 200 to 400 ° C. is preferred for the reaction from 220 to 350 ° C, in question, it is advantageous to work in an autoclave.

The yields of ether dicarboxylic acids increase with increasing solvent content lower in the approach. The temperature range is still used for the formation of the ether dicarboxylic acids from 220 to 300 ° C particularly favorable. If the amount of alkali is reduced below 2, 2 Equivalents reduce the yields of dicarboxylic acids in general, i.e. H. as well as the yields of ether-free dicarboxylic acids and ether dicarboxylic acids. It Oxyacids and other by-products then occur in larger quantities.

Accordingly, ether-free dicarboxylic acids are preferably obtained if works in the temperature range from 250 to 350 ° C, the water content of the reaction mixture is at least 35 percent by weight and the basic reacting substances, in particular the alkalis, in an amount of at least 3.5 equivalents, preferably at least 4.5 equivalents per mole of starting material are used. Good yields Ether dicarboxylic acids are preferred when working in the temperature range above 200 ° C at 220 ° C, with a water content of 10 to 35 percent by weight, preferably up to 30 weight percent, and in the case of an amount of basic reacting substance, in particular Alkali obtained from 2, preferably 2.2 to 5 equivalents per mole of starting material. It has also been shown to reduce the formation of by-products and the purity of the ether dicarboxylic acids obtained and their yield are improved is, if one uses mixtures of alkali compounds, at least in part consist of alkaline compounds of potassium. Such an effect is for example when using a mixture of sodium and potassium hydroxide already recognizable when 7 to 10 mol percent of the total alkali is potassium hydroxide exist. Of course, you can also use larger amounts of caustic alkali and use this alone if necessary.

It has also been shown that the ether-free resp. Ether dicarboxylic acids in the work-up of the reaction mixture easily by fractionated Let precipitates of the free acids separate from the solution of their water-soluble salts. Dissolve the reaction mixture, which is in the form of the water-soluble salts or has been converted into this form, in water, then one can by gradual acidification first precipitate the weaker acidic compounds. Mostly there is a difference here first of all the ether dicarboxylic acids. After separating the same, the Solution of the acids still present precipitated by further acidification. For acidification a mineral acid is preferably used, in particular hydrochloric acid or sulfuric acid.

If the reaction has been carried out in the presence of alkaline earth compounds, so the dicarboxylic acids formed are mostly in the form of their water-insoluble salts before. You can now do this from the water-soluble components of the reaction mixture separate and the alkaline reacting liquor obtained in the process lead back. The dicarboxylic acids formed can be obtained from the insoluble alkali salts can be obtained directly by treatment with acids, or they can first be obtained in transfer water-soluble salts and then separate in the above-mentioned manner.

However, the separation of the dicarboxylic acid mixtures can also be applied to others Way, for example by extraction with hot water, optionally under pressure, by solvent extraction or other methods. in the By-products present in the reaction mixture, for example oxyacids, can be also separate by such methods.

Although it is known to base chloroacetic acid by treatment to convert reacting substances into diglycolic acid, an ether dicarboxylic acid (cf. Beilstein, "Handbuch derorganischen Chemie", IV. Edition, Vol. III, p. 234). The -bromo derivative of the next higher homologue, propionic acid, replicates References in the literature for treatment with aqueous alkalis no ether dicarboxylic acid, but p-oxypropionic acid ("hydracrylic acid") or acrylic acid, so that the formation an ether dicarboxylic acid from chloroacetic acid on the labilization of the halogen atom due to the neighboring carboxyl group. When this reaction If the p-bromopropionic acid is absent, it was the case with the long-chain α, -chlorocarboxylic acids or chloronitriles, as they are to be processed according to the invention, no longer expected.

Examples 1 to 13 The experiments were carried out according to following general job description; any deviations from this description are specially indicated in the table.

# -Chloropelargonic acid was used as the starting material, which is obtained from the corresponding, nitrile produced by reacting ethylene with cyanogen chloride by acidic saponification had been received. The acid was combined with the alkali and water in one Stirring autoclave heated. The stirred autoclave remained closed during the entire experiment, so that the reaction proceeded under pressure. Quantities, temperatures and reaction times are given in the table.

The heating-up time is not included in the reaction time, i. h., it only the times are given during which the reaction product is on the mentioned Temperature rature was. After cooling the autoclave, the reaction mixture became so a lot of hot water dissolved that an about 20% solution of the reaction mixture originated. Then slowly with dilute hydrochloric acid up to a pH of 5, 8 to 6 acidified. The oil which separated out was replaced by the clear aqueous solution in the heat Separated solution, and then the aqueous solution was diluted by adding more Hydrochloric acid brought to a pH of about 2 to 3. If there is another 01 retired, this was combined with the first separated. The Ö1 was then washed again with hot water and the wash water with the pH 2 to 3 acidified solution of the reaction mixture combined. When this solution cools down The azelaic acid crystallized from it. The table gives the yields and the key figures of the reaction products.

Table I. Approach yields chlorine- NaOH KOH H2O ether indicators pelar- azelaine- At- reaction dicarbon- gon- mole mole acid game acid acid per azelaic acid ether dicarboxylic acid 11 moles 1 mole vs.% ° / o gg acideg acideg ° C hours of theory of theory SZ VZ OHZJZ SZ. VZOHZ! JZ 1 192.5 200 5 - - 131 25 280 4 96 51.2 63.0 38.3 582 583 - - 321 322 4.0 9.0 2 192.5 200 5 - - 69 15 320 4 103 54.9 22.0 13.3 593 594 - - 380 383 - 7.0 3 192.5 200 5 - - 131 25 150 to 5 100 53.2 55.0 33.4 571 573 - - - - - - 300 4 (a) 173, 5 200 5 -'- 125! 25300. 4, 580 --- 467 494 14, 0 ----- 5 192, 5 200 5-131 i 25 250 4, 5 91 48, 4 60, 5 36, 7 577 577, - 353 356'-16, 3 6 192, 5 200 5-392'50 250 to 7, 5 156 83, 1 10, 7 6, 5 564 565--346 348-16, 3 300 7 96.3 100 5 - - 196 50 250 6.5 76 80.4 5.5 6.7 554 555 10.0 5.0 344 347 - - 8 96, 3 100 5 -22 10 250 5, 5 55 58, 5 25, 0 30, 3 552 557 0, 0, -334 339 6, 7 23, 5 9 96.3 10 5 - - 97 33 280 5.25 60 64.0 20.0 24.3 580 580 - - 344 344 0.0 6.7 10 96.3 85 4.3 15 0.5 22 10 280 4.25 48 51.0 30.0 36.4 564 564 0.0 0.0 344 345 0.0 4.3 11 96.3 75 3.8 25 0.9 22 10 280 6.25 51 54.3 24.0 29.2 560 562 - - 344 346 7.0 4.0 12 96.3 85 4.3 15 0.5 49 20 280 6.25 53 56.4 26.0 31.6 583 584 - - 344 344 0.0 4.6 13 (b) 96.3 85 4.3 15 0.5 22 10 280 4.25 57 60.8 18.0 21.8 567 568 - - 337 339 6.0 8.3 (a) In Example 4, it was not the free acid but the nitrile that was converted.

(b) In Example 13 was not with water, but with ethanol as Solvent worked.

Examples 14 to 16 Examples 14 and 15 describe the use of s1a-chloropelargonic acid, Example 16 that of o-chlorovaleric acid under normal pressure. The alkali to be used was dissolved in water and the alkali solution thus obtained mixed with the chlorocarboxylic acid in a kneader. The kneader had one with) "Wood's alloy" filled heating jacket and its contents were heated by gas heated as quickly as possible. The temperature was low because of the rotating kneading arms not measured in the reaction mass itself, but the temperature the "Wood's alloy" found. Experience has shown that the temperature is the Reaction mass 50 to 80 ° C lower; in the table is the temperature range indicated in which the implementation probably took place. During the reaction some of the water present in the approach evaporated. The water vapor could after escape outside; but in order to prevent the ingress of atmospheric oxygen with certainty, From the beginning of the experiment, water vapor slowly passed through the gas space of the kneader directed.

The passage of water vapor was only immediately bar before emptying of the kneader interrupted. After turning off the heating, the kneader was blown on cooled with compressed air from the outside.

When using chloropelargonic acid as a starting material it was used the reaction mixture was worked up as described in Examples 1 to 13. at the processing of chlorvaleric acid could easily dissolve the resulting in water soluble glutaric acid not by acidification, but by exhaustive ether extraction and distilling off the ether can be obtained.

Examples 17 to 21 In Examples 17 and 18 # -Chlorvaleric acid, in example 19 cs-chlorovaleric acid nitrile and in examples 20 and 21 co-chloropelargonic acid used. In example 20 the reaction mixture was cadmium oxide and in the example 21 lead oxide added; both oxides were in an amount of 3 percent by weight, based on chlorocarboxylic acid applied.

The details of the results of Examples 14-21 are from can be found in the following table.

Table II Approach yields From NaOH KOH H2O ether indicators Dicarbon By- reaction dicarbon- Mole mole acid game sum acid each per dicarbon- etheric carbon- 1 mole 1 mole g% g% acid acid gg acid g acid g ° C hours of theory of theory SZ VZ OHZ JZ SZ VZ OHZ JZ 14 P 192.5 170 4.3 30 0.5 167 30 300 to 330 3 29 15.4 100 60.8 574 573 - - 338 340 0.0 - 15 P 192.5 200 5.0 - - 167 30 270 to 300 3 14.0 - 112 66.6 227 433 0.0 7.4 305 342 0.0 1.0 16 V 136.5 170 4.3 30 0.5 175 34 20 to 310 2 102 77.5 - - 804 814 0.0 - - - - - 17 V 136.5 170 4.3 30 0.5 37 10 230 6 110 83.2 - - 833 841 0.0 - - - - - 18 V 136.5 150 3.8 50 0.9 144 30 200 6 98 - - - 342.5 617 52 0.0 - - - - 19 VN 117.5 170 4.3 30 0.5 35 10 170 to 175 6 58 - - - 637 667 11 - - - - - 20 P 96.3 85 4.3 15 0.5 22 10 280 71/4 45 48 25 30.3 576 576 - - 346 346 3.0 4.7 21 P 96.3 85 4.3 15 0.5 22 10 280 51/4 55.5 59.2 20 24.2 563 564 - - 346 349.5 7.5 4.5 The letters after the number of the example mean: P = chloropelargonic acid; V = chlorovaleric acid; N = It was not the free acid but the nitrile that was converted.

Claims (8)

PATENT CLAIMS: 1. Process for the preparation of aliphatic salts Dicarboxylic acids or the free dicarboxylic acids, characterized in that x, co-chlorine fatty acid nitriles, amides, esters, free oj-chlorofatty acids or their salts, which contain at least 5 carbon atoms, preferably in the presence of a solvent, heated with inorganic compounds with a basic reaction in aqueous solution and optionally the dicarboxylic acids, preferably de by fractional acidification Solution of their salts, isolated. 2. The method according to claim 1, characterized in that the Reaction at a temperature of 200 to 400 ° C, preferably at 220 to 350 ° C, carried out. 3. The method according to claim 1 and 2, characterized in that one an alkali or alkaline earth oxide or hydroxide as the basic compound or an alkali carbonate is used. 4. The method according to claim 1 to 3, characterized in that one the basic reacting substance per mole of chloronitrile or per mole of free chlorine fatty acid in an amount of at least 2.2, preferably 2.5 to 5 equivalents. 5. The method according to claim 1 to 4 with preferred formation of ether-free dicarboxylic acids, characterized in that the reaction with a Alkali amount of at least 3.5, preferably at least 4.5 equivalents per mole Starting material, with a water content of the reaction mixture of at least 35 Percent by weight and at a temperature of 250 to 350 ° C. 6. The method according to claim 1 to 4 with preferred formation of Ether dicarboxylic acids, characterized in that the reaction is carried out with an amount of alkali from 2 to 5, preferably 2.2 to 5 equivalents per mole of starting material, with one Water content of the reaction mixture of at most 35 percent by weight, preferably from 10 to 30 percent by weight, and at a temperature from 200 to 280 ° C, preferably from 220 to 280 ° C. 7. The method according to claim 6, characterized in that mixtures alkaline compound is used, which is 7 to 10 mole percent of the total amount of alkali consist of potassium hydroxide. 8. The method according to claim 1 to 7, characterized in that one as a solvent, at least 5, preferably 10 to 75 percent by weight of the total Reaction approach to water used, the whole or in part by water-soluble organic solvents, especially alcohols with 1 to 4 carbon atoms can be replaced.