DED0017357MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: March 20, 1954. Advertised on October 31, 1956

GERMAN PATENT OFFICE

PATENT APPLICATION

CLASS 12ο GROUP 27 INTERNAT. CLASS C 07c

D 17357 IVb / 12 ο

Bernard Hammond Markham Thompson, Great Burgh, Epsom,

Surrey (Great Britain)

has been named as the inventor

The Distillers Company Limited, Edinburgh (Great Britain)

Representative: M. M. Wirth, Dr. W. Schalk and Dipl.-Ing. P. Wirth, patent attorneys, Frankfurt / M.

Process for the production of oxyhydroperoxides

The priority of the application in Great Britain of March 28, 1953 has been claimed

The invention relates to a method of manufacture

of new oxyhydroperoxides, which have a hydroxyl radical and a hydroperoxide radical in the same Molecule included. These residues are attached to different carbon atoms.

α-Oxyhydroperoxides are known. you will be represented by the action of hydrogen peroxide on ketones. These oxyhydroperoxides are very volatile Compounds which ίο explode violently when heated. This behavior is not surprising considering that the hydroxyl group is attached to the same carbon atom like the hydroperoxide group.

The invention now relates to a process for the preparation of oxyhydroperoxides, in which the Hydroxyl group and the hydroperoxide group are bonded to different carbon atoms, which in turn, in turn, with one or two benzene rings of an aromatic hydrocarbon are linked by at least 3 carbon atoms of the aromatic hydrocarbon from each other are separated.

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The process according to the invention for the preparation of oxyhydroperoxides is characterized in that that one is a monocarbinol of the general formula

R ₃ .. R ₁

HO-C-Ar-CH

treated with molecular oxygen in the liquid state at elevated temperature. In this formula, R _{1 denotes} a hydrogen atom, an alkyl group or an alicyclic group, R ₂ , R ₃ and R ₄ denote alkyl groups or alicyclic groups, and Ar denotes an aromatic hydrocarbon group. Alkyl radicals are z. B. the methyl, ethyl, propyl, isopropyl, butyl, isobutyl, secondary butyl radical; alicyclic residues,

ao z. B. the cyclopentyl and cyclohexyl radical. The rest Ar can e.g. B. the benzene, naphthalene, anthracene or phenanthrene radical or their alkyl-substituted Be a derivative. The rest

R ₃ -CR ₄ and R ₁ -C- R ₂

OH

are bonded to non-adjacent carbon atoms in such a way that they are not in the o-position to one another stand.

The monocarbinols from which the oxyhydroperoxides are produced according to the invention can be advantageously from the corresponding monohydroperoxides by treatment with hydrogen or produce other chemical reduction processes. The hydrogenation can be carried out with the help of catalysts, such as Raney nickel or Adams catalyst (platinum oxide). The monocarbinols are also formed as by-products in the oxidation of aromatic hydrocarbons of the following Formula:

^R l

H-C-Ar-C

in which R ₁ , R ₂ , R ₈ and R ₄ as well as Ar have the same meaning as above, with molecular oxygen. In addition to the hydroperoxides, the mixture formed during the oxidation contains certain amounts of monocarbinol, which is separated off from it.

The oxidation of the monocarbinol can, if

this is liquid at the reaction temperature, take place directly or in the presence of inert ones Solvents are carried out, ζ. B. in water, or in the presence of solvents which can themselves be oxidized. The application of such Solvent is necessary when the monocarbinol is solid at the reaction temperature. Such solvents are e.g. B. the original ones aromatic hydrocarbons from which the monocarbinols are derived.

The temperatures at which the monocarbinol can be oxidized are between 60 and 150 ^° , preferably between 90 and 130 ^° . The choice of the most suitable temperature for the process depends on the one hand on the reaction rate and on the other hand on the yield of oxyhydroperoxide. However, the temperature should be chosen so that decomposition of the oxyhydroperoxide formed is avoided as far as possible.

The oxidation of monocarbinol can be with molecular oxygen in the form of pure or almost pure or in the form of oxygen-containing gas mixtures, such as air. Mixtures containing ozone can also be used if necessary.

The use of pressures in excess of atmospheric pressure can be advantageous, especially when you use a gas mixture with a low oxygen content 'or when you use a high one Want to achieve oxidation rate.

The rate of oxidation can be increased at a given temperature by they are carried out in the presence of oxidation catalysts. Such catalysts are for example Compounds of cobalt, manganese, copper and other catalytically active metals. In this In this case, however, it is necessary to precisely control the amount of the catalyst to prevent excessive decomposition of the oxyhydroperoxide formed and an associated decrease in the yield avoid.

The amount of catalyst that can be used depends on the effectiveness of the particular catalyst both in terms of increasing the rate of oxidation and promoting decomposition of the already formed oxyhydroperoxide. The amount of the catalyst added therefore becomes preferably limited in such a way that the degree of conversion of the monocarbinol into the relevant Oxyhydroperoxide is not less than that which results from the same rate of oxidation an increase in temperature in the absence of the catalyst would have been brought about. the The most favorable amount of catalyst can be determined by a preliminary test. The oxidation can be done through set in motion the addition of compounds that produce free radicals. Such connections are z. B. peroxides, hydroperoxides or azo compounds.

The oxidation is expediently carried out in the presence of sufficient quantities of basic substances, to prevent the formation of .free acids in the reaction mixture. It will therefore Alkali or alkaline earth oxides, hydroxides, carbonates or bicarbonates or their salts with weak organic or inorganic acids added to the oxidation mixture. The addition can be in solid In the form or in the form of, for example, aqueous solutions. Basic nitrogen compounds such as ammonia or amines, can also be used for this.

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The oxyhydroperoxides can be from the reaction mixture by various methods, for. B. by fractional distillation under reduced pressure, eliminating the unreacted starting materials be removed, or by extraction with water, aqueous alcohol or aqueous alkali solutions, such as Caustic soda, win. The oxyhydroperoxides can be extracted from the alkaline solutions with a suitable one that is immiscible with water

ίο Separate solvents or through precipitation after neutralization or acidification of the solution. If the extraction is done z. B. with caustic soda, it is advisable to use a solution which is at most g normal (= 36 percent by weight), since more concentrated caustic soda tends to mix the alkali salt with unreacted monocarbinol, which is not easy to remove from it, to fail. An aqueous ι to 2 N alkali metal hydroxide solution is preferably used. Another possibility is to extract only part of the oxyhydroperoxide formed and to further oxidize the extracted oxidation mixture, preferably after adding fresh monocarbinol. The oxidation can be carried out batchwise or continuously.

In the continuous mode of operation, the aromatic corresponding to the monocarbinol is oxidized Hydrocarbon in liquid state with molecular oxygen, being a mixture of monohydroperoxide with some monocarbinol and some oxyhydroperoxide in solution in unchanged aromatic Hydrocarbons are produced. The oxidation is expediently conducted so that in the main the monohydroperoxide and very little dihydroperoxide is formed. The oxidation mixture will then extracted with a not more than 9 N, expediently 1 to 2 N aqueous alkali metal hydroxide solution, whereby the resulting oxyhydroperoxide with. also formed dihydroperoxide in the form of their alkali salts, which are soluble in the aqueous alkali hydroxide solution, are removed. This solution then becomes that Oxyhydroperoxide by adding acid, e.g. B. carbon dioxide, obtained. The one after the removal of the oxyhydroperoxide remaining mixture, which is still unchanged, aromatic hydrocarbon, Contains monohydroperoxide and monocarbinol

, then reduced in another reaction vessel, for example with sodium sulfite or with hydrogen, in the presence of Raney nickel as a catalyst, whereby the monocarbinol from the monohydroperoxide arises. The monocarbinol solution is then circulated back into the oxidation vessel. where it is expedient to add fresh aromatic hydrocarbon.

The oxyhydroperoxides produced by the process according to the invention are not yet available has been described. In general they are water soluble and form alkali salts, e.g. B. sodium salts, when treated with dilute alkali hydroxide solutions. However, these salts become such Solutions by concentrated alkali hydroxide solutions, e.g. B. with more than 9 N sodium hydroxide solution, failed. The free oxyhydroperoxides dissolve in alcohols, e.g. B. methyl alcohol and ethyl alcohol, in ketones, ζ. B. acetone and methyl isobutyl ketone, in ethers, e.g. B. diethyl ether and diisopropyl ether, in Esters, e.g. B. ethyl acetate. They're little in cold benzene and toluene and very little in Petroleum ether soluble. Their solubility in water allows them to be used with particular advantage used with good effect as catalysts in emulsion polymerization.

By treatment with acidic catalysts, for example mineral acids such as sulfur, acid, acid-treated mineral active earths, e.g. B. Fuller's earth, with hydrogen ion exchangers and with Friedel-Crafts catalysts, ζ. Β. Aluminum chloride and boron trifluoride, becomes the aryl group with the hydroperoxide group linked to it into the corresponding phenol at the same time Formation of ketones, such as acetone, or aldehydes, such as acetaldehyde, are converted. the The resulting phenols contain an alcoholic hydroxyl group in addition to the phenol hydroxyl group. Because of these two hydroxyl groups, the phenols are valuable intermediates, e.g. B. to Manufacture of plasticizers and esters as high-boiling solvents.

The oxyhydroperoxides which can be prepared according to the invention are new compounds. It was by the way not foreseeing how the corresponding carbinols would behave during oxidation, so at which point the oxygen attack would take place or whether oxidation would take place at all (cf. Ind. and Eng. Chem., Vol. 34, 1942, p. 189; Trans. Farad. Soc, Vol. 42, 1946, p. 203; Chemie. Res. Vol. 1950, p. 153). In addition, it was not certain whether the oxyhydroperoxides which can be prepared according to the invention are not unstable in the same way as the α-oxyhydroperoxides mentioned at the outset.

The process according to the invention is illustrated in the following examples. The specified Unless otherwise stated, parts relate to parts by weight. Parts of space are in the same ratio to parts by weight as liters to kilograms.

example 1

189 parts of pure m-isopropylphenyldimethylcarbinol, which had been prepared by reducing m-diisopropylbenzene monohydroperoxide and fractional distillation of the product obtained, were mixed with 4 parts of calcium hydroxide and 0.5 part of 2-azobisisobutyronitrile as a catalyst to start the oxidation. The mixture was kept in a thermostatically controlled oil bath at 90 ^0th Pure oxygen was passed through the mixture, the uptake of which was very slow at the beginning, but later was about 400 parts per hour. The rate of oxygen uptake and peroxide formation began to decrease as soon as the concentration of peroxide in the mixture reached 34 percent by weight. The oxidation was stopped when the peroxide concentration was about 36 percent by weight and at a time when the rate of peroxide formation reached about 0.7 percent by weight per hour.

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The oxidation mixture was cooled, then diluted with approximately the same volume of benzene and the calcium hydroxide filtered off. After analysis, the benzene solution contained 100 parts by volume about 16.34 parts of m- (2-oxy-2-propyl) -. A, a-dimethylbenzyl hydroperoxide. Most of the solution was extracted twice with the same volume of 2N sodium hydroxide solution, and the alkali solution obtained was washed with a small amount of benzene after each extraction. The combined alkaline aqueous solutions were then neutralized with carbon dioxide to give a white crystalline precipitate was precipitated, which after filtration and drying had a melting point 71-72 ^0th

It was cleaned and freed from the simultaneously precipitated sodium carbonate by putting it in benzene dissolved, the solution filtered and the oxyhydroperoxide precipitated with petroleum ether. The purified, peroxide had the. Melting point .71.5 to 72 ° and was 99.3%.

Only 80 ° / ₀ of the Oxyhydroperoxyds were extracted in this' manner from the oxidation mixture with 2 N sodium hydroxide. The remainder was precipitated as the sodium salt by stirring the solution with a 50% sodium hydroxide solution. After filtering, washing thoroughly with benzene and drying, the sodium salt was suspended in water and acidified with solid carbon dioxide as already described. In this way five more parts were obtained so that the total yield of oxyhydroperoxide was 58 parts; a total of 72.2% of the absorbed oxygen was converted into the oxyhydroperoxyd.

Example 2

500 parts of p-Isopropylphenyldimethylcarbinol were stirred with 20 parts of calcium hydroxide and 0.5 parts of bis-2-azobutyronitrile agile and 90 ^{the 0th} oxidized with oxygen. The hourly oxyhydroperoxide formation was 0.9 percent by weight, with 70% of the oxygen taken up being converted into the oxyhydroperoxide. Once the hydroperoxide. concentration reached 34 weight percent of the reaction mixture, formation began to decrease.

The oxidation mixture was cooled somewhat, then diluted with 500 parts by volume of benzene and the calcium hydroxide filtered off. The filtrate solidified on cooling. The solid mass was filtered off with suction and petroleum ether was added to the filtrate. The resulting precipitate was filtered off and combined with the first, and then washed with petroleum ether. Thus a total of 170 parts became white crystalline. Oxyhydroperoxide obtained with a melting point of 83 to 85 ⁰ , which, according to iodometric determination, contained 87 percent by weight of oxyhydroperoxide. This corresponded to a yield of 68%. The filtered solution was freed from the solvent by distillation. The residue contained about 12 percent by weight of oxyhydroperoxide and was returned to the oxidation vessel.

The crude p- (2-oxy-2-propyl) -a, a-dimethylbenzyl hydroperoxide was recrystallized from a mixture of benzene and petroleum ether. The melting point was then 91.5 to 92.5 °, the degree of purity 98%.

Example 3

48 parts of largely purified p-isopropylphenylethylmethylcarbinol, which had been prepared according to Grignard from p-bromoisopropylbenzene and ethyl methyl ketone and had a melting point of 24 ⁰ _{and b.p. 0> 2} = 72 to 73 °, were in 12.5 parts of an aqueous 0.25 parts of sodium carbonate-containing solution containing 0.2 parts of azobisisobutyronitrile were added as Anspringkatalysator, heated to 90 ⁰ and oxygen was bubbled through the mixture with vigorous stirring. After a fairly constant uptake of oxygen for 9 hours, the reaction mixture contained 46% peroxide.

The oxidation mixture, which consisted of an oil and an aqueous layer, was cooled and then extracted ten times with 20 parts by volume of benzene each time. The benzene extracts were combined and extracted ten times with 50 parts by volume of a 30% sodium hydroxide solution. These alkaline extracts were combined, washed with benzene to remove unoxidized organic material, and the oxyhydroperoxide was liberated from the sodium salt with carbon dioxide. The Oxyhydroperoxyd was then extracted with benzene, the benzene solution over anhydrous sodium sulfate, 'dried, the benzene under reduced pressure at approximately 20 to 30 ⁰ evaporated and the residue finally liberated at 0.5 mm Hg of the residues of the solvent.

In this way 15.2 parts of m- (2-oxybutyl) - a, a-dimethylbenzyl hydroperoxide were obtained as a very viscous liquid with a refractive index of n ² g - 1.5292 and a peroxide content of 83%.

The benzene solution extracted with caustic soda still contained considerable amounts of oxyhydroperoxide. The benzene was therefore distilled off, 17 parts of viscous material of lower purity being obtained, as can be seen from the lower refractive index of M ² D = 1.5282 and the peroxide content of 71%.

Example 4

5 parts by volume of an aqueous 5 percent strength by weight sodium carbonate solution were added to 1036 parts by weight of m-diisopropylbenzene. The mixture was oxidized with commercial oxygen at 90 ^0th The amount of oxygen was measured before and after passage through the oxidation tank and the uptake of the oxygen gave an "approximate indication of the progress of the oxidation. Samples taken from the oxidation tank were examined iodometrically to determine the concentration of the hydroperoxide. The Oxidation was terminated after 18 hours when the mixture contained 41.3 percent by weight of hydroperoxide, calculated as m-isopropyl-α, α-dimethylbenzyl hydroperoxide (hereinafter referred to as "benzyl hydroperoxide"). Further examination of the dried mixture showed the following

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Composition of the hydroperoxides present in the mixture:

Weight percent benzyl hydroperoxide 33.3

m- (2-Oxy-2-propyl) -ai a -dimethylbenzyl hydroperoxide (called »Oxyhydroperoxydff for short) 2.2

m-bis- (2-hydroperoxy-2-propyl) benzene (called "dihydroperoxide" for short) 3. ¹

1130 parts by weight of the oxidation mixture obtained were extracted twice with 200 parts by volume of an aqueous 2N sodium hydroxide solution. The alkaline extract was discarded and a sample of the remaining oxidation mixture was examined and found to contain 34.8 percent by weight of benzyl hydroperoxide, 1.3 percent by weight of oxyhydroperoxide and 0.6 percent by weight of dihydroperoxide. The main amount of the oxidation mixture was washed with a little water, which was discarded, and then diluted with 1000 parts by volume of methyl alcohol: The alcoholic oxidation mixture was now in a reaction vessel in the presence of 30 parts by weight of Raney nickel at about 40 ^° while passing hydrogen into the, vigorously stirred mixture reduced. From time to time samples were taken from the reaction mixture and examined iodometrically for hydroperoxide. The hydrogenation was terminated after 21 hours when the concentration of the hydroperoxide in the mixture had fallen to 0.3 percent by weight, calculated as benzyl hydroperoxide. The Raney nickel was filtered off, and the methyl alcohol was distilled off from the filtrate first at atmospheric pressure and finally under reduced pressure. The remaining liquid was cooled and filtered to remove a small amount of crystallized m-bis- (2-oxy-2-propyl) -benzene.

The clear, colorless filtrate, 943 parts by weight, consisted mainly of m-isopropyl-a, a-dimethylbenzylcarbinol (called "monocarbinol" for short). It was washed with an aqueous 5 ° / _o sodium carbonate solution and oxidized at 90 ° with a commercially available oxygen in the apparatus used above. The oxidising mixture was maintained during oxidation by the addition of a temporary 4 ° / ₀ aqueous sodium hydroxide solution strongly alkaline. The increase in the formation of hydroperoxide in the oxidation mixture was determined in samples that were withdrawn from time to time. The oxidation was interrupted after about 24 hours when the concentration of the hydroperoxides reached the following value:

Benzyl hydroperoxide 41.0%

Oxyhydroperoxide ... 19.1 ° / ₀

Dihydroperoxide 4.0 ° / ₀

1127 parts by weight of the oxidising mixture were washed five times a / extracted with 600 parts by volume of 8 ° _o aqueous sodium hydroxide solution. The combined alkali extracts were washed with a small amount of benzene (about 50 parts by volume) which was discarded. The aqueous alkaline solution of hydroperoxides has now neutrahsiert dioxide with carbon and the neutralized aqueous milky mixture, which had a _pH value of 9.8, then extracted five times with 200 parts by volume of ether. The aqueous layer, which was discarded, contained 0.21 ° / ₀ hydroperoxide, calculated 'as Benzylhydroperoxyd.

The ether was then removed from the combined ether extracts by distillation. To his complete removal, 500 parts by volume of benzene were added to the residue and then about 50 parts by volume of benzene distilled off. The remaining hot benzene solution of the hydroperoxides was diluted with about 100 parts by volume of hexane until the solution became continuously cloudy. The solution was first cooled slowly and finally quenched by ice cooling. The secluded white crystalline mass was filtered off and freed from the solvent in vacuo. There were 153 g of 95.6 weight percent Oxyhydroperoxide obtained with a temperature of 68 to 70 °.

The oxidation mixture that remained after the alkaline extraction and was 851 parts by weight, contained 36.5 percent by weight benzyl hydroperoxide, 2.3 percent by weight oxyhydroperoxide and 0.61 percent by weight Dihydroperoxide. The mixture was also hydrogenated as described above; the Hydrogenation took 28 hours and the mixture then contained only 0.2 percent by weight hydroperoxide, calculated as benzyl hydroperoxide. The removal of the Raney nickel and methyl alcohol was in done in the same way. Then it became 100 parts by weight m-Diisopropylbenzene was added and a further 24.3 parts by weight of m-bis (2-oxy-2-propyl) benzene removed from the hydrogenation product.

The hydrogenation product was, as described above, oxidized at 90 ° with commercially available oxygen and the oxidation was terminated after 26 hours when the oxidation mixture contained 44.1 percent by weight of benzyl hydroperoxide, 20.3 percent by weight of oxyhydroperoxide and 5.2 percent by weight of dihydroperoxide. The oxidising mixture, 1103 parts by weight, was extracted six times with 500 parts by volume of an 8 ° / _o aqueous sodium hydroxide solution. The combined alkali extracts were washed with a small amount of benzene (about 100 parts by volume), which was discarded, and then neutralized with carbon dioxide. The neutralized, milky, aqueous mixture was extracted five times with 250 parts by volume of ether each time. The remaining aqueous layer, which contained 0.24 percent by weight hydroperoxide, calculated as benzyl hydroperoxide, was discarded. The ether was distilled off from the combined extracts and replaced by 500 parts by volume of benzene. After about 100 parts by weight of hexane had been added until clouding occurred, the crude oxyhydroperoxide crystallized from the benzene solution. The benzene-hexane mixture was finally ice-cooled. The white crystalline mass was filtered off and freed from the solvent. There were 137 parts by weight

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pure, g4> 3g ^{e 'w c} i htsprozentiges Oxyhydroperoxyd having a melting point of 67 to 69 receive ^{the 0th}

The remaining 847 parts by weight of the oxidation mixture that remained after the alkali extraction and 41.1 percent by weight benzyl hydroperoxide, 2.6 Containing percent by weight of oxyhydroperoxide and 0.8 percent by weight of dihydroperoxide were added to the Oxydatidnkreislauf returned.

Claims (10)

PATENT CLAIMS: i. Process for the preparation of oxyhydroperoxides of the general formula HO-C-Ar-C-O-OH R -ρ 4 ^Κ 2 characterized in that a monocarbinol of the formula R ₃ R ₁ HO-C-Ar-CH in which R _{1 is} a hydrogen atom, an alkyl radical or an alicyclic radical and R ₂ , R ₃ and R _{4 are} alkyl radicals or alicyclic radicals, Ar is an aromatic hydrocarbon radical, and the radicals Ri R ₃ -CH and -COH ah non-adjacent carbon atoms are bound to a benzene ring or to two benzene rings of the aromatic radical, ^{oxidized in the liquid state at temperatures between 60 and 130 0} with molecular oxygen or oxygen-containing gases. 2. The method according to claim 1, characterized in that the oxidation is carried out at a temperature between 90 and 130 ⁰ . 3. The method according to claim 1 and 2, characterized in that the rate of oxidation increased by the addition of a heavy metal oxidation catalyst. 4. The method according to claim 1 to 3, characterized characterized in that the oxidation is achieved by the addition of compounds which release free radicals initiates. 5. The method according to claim 1 to 4, characterized in that the oxidation in the presence an inert liquid or a solvent, especially in the presence of the hydrocarbon from which the monocarbinol was made. 6. The method according to claim 1 to 5, characterized in that one in the oxidation The acid formed is neutralized by adding basic substances to the reaction mixture. 7. The method according to claim 1 to 6, characterized in that the oxyhydroperoxide pulls out of the reaction mixture with an aqueous, at most 9 η-alkali hydroxide solution. 8. The method according to claim 7, characterized in that only part of the generated Oxyhydroperoxide is extracted and the remaining reaction mixture is further oxidized. 9. The method according to claim 1 to 8, characterized by the use of a monocarbinol, which was produced by reducing the corresponding monohydroperoxide. 10. A method for the continuous production of oxyhydroperoxides according to claim 1 to 9, characterized in that the monocarbinol used was prepared by a hydrocarbon of the formula RT ")
3 ^K i HC-Ar-CH in which R ₁ , R ₂ , R ₃ and R _{4 have} the meaning given above, oxidized in the liquid state with molecular oxygen, the resulting reaction mixture, which contains a solution of monohydroperoxide, monocarbinol and oxyhydroperoxide in unreacted hydrocarbon, with an aqueous, a maximum of 9 n-alkali hydroxide solution is extracted, the oxyhydroperoxide is separated from the alkaline extract by adding acid, while the solution of monohydroperoxide and monocarbinol remaining in the extraction in unreacted hydrocarbon is reduced in a known manner and the resulting solution of monocarbinol is returned to the oxidation cycle . © 6Ο9 66Ο / Φ63 10.56