DE1195279B - Process for the production of hydrogen peroxide in a cycle - Google Patents

Description

Process for the production of hydrogen peroxide in the circuit Die The invention relates to a process for the production of hydrogen peroxide in the circuit in such a way that alkyl anthraquinone in a solution and in the presence of a catalyst is hydrogenated to alkyl anthrahydroquinone, which then after removal of the catalyst by an oxygen-containing gas to hydrogen peroxide and alkyl anthraquinone is autoxidized, and that the peroxide is extracted by, for example, water, while the alkylanthraquinone thus obtained goes back to the hydrogenation stage mentioned is returned. In particular, the invention relates to the application of this circulating working solution.

It is known to use alkyl anthraquinone, e.g. B. 2-ethyl, 2-isopropyl, 2-secondary or 2-tertiary butylanthraquinone or the like, individually or mixed as a working medium to use. Allcylanthraquinones are known to have relatively low solubilities in solvents that are generally used for the hydrogenation and autoxidation mentioned can be used, so that the following troubles arise: 1. Lower yield of hydrogen peroxide with a single passage of the alkylanthraquinone solution.

2. Difficulty in extracting concentrated hydrogen peroxide.

3. Inevitable formation of by-products in the event of increased Hydrogenation to avoid the difficulties mentioned; these lead to one large loss of alkyl anthraquinone, which by the side reactions to tetrahydroalkyl anthraquinone is effected.

It has been found that all of the above difficulties can be combined into one Process for the production of hydrogen peroxide in the cyclic process using an almost eutectic mixture of alkyl anthraquinones as the working medium in the Solvents can be avoided in a simple manner when using benzene, an alkyl-substituted one Benzene, a-methylnaphthalene, methyl and butyl benzoate and anisole separately or in Mixture used as a solvent and in the hydrogenation of the cyclic process The degree of hydrogenation is kept below 40%; preferably a mixture of one the above solvents with an amount of up to 60 percent by volume of octyl alcohol and / or nonyl alcohol is used. According to an older proposal are in a proceeding for the production of hydrogen peroxide in the cycle process eutectic mixtures of alkyl anthraquinones used in the form of their highly concentrated solutions in solvents. As a solvent is named after _ the older proposal only trioctyl phosphate, that after Embodiment has an addition of 10 /, dimethyl naphthalene.

The invention is based on the observation that mixtures of alkyl anthraquinones Show eutectic properties and that such a mixture is an extraordinary high solvency in each of those generally used in the manufacture of hydrogen peroxide used solvents. The amount of this solvency is multiple arithmetic sum of the solubilities obtainable when that of the mixture underlying alkylanthraquinones are used separately.

In this context, reference is made to the drawings, in which F i g. 1 and 2, for example, show which melting properties a two alkyl anthraquinones existing mixture when their mixing ratio is changed having.

Various examples of mixtures, each of which has a favorable mixing ratio, are summarized in the following Table I, together with solubilities in solvents according to the invention. For comparison purposes, the individual alkyl anthraquinones are also listed. Table I. Solubility of anthraquinone mixtures and of individual anthraquinones at 30'C Anthraquinone Mixing ratio solubility (g / 1) in in parts by weight of 0, -Methylnaphthalin I butyl benzoate 2-ethyl- and 2-isopropyl- ....................... 20: 80 5730 4110 2-ethyl- and 2-sec-butyl- ....................... 27: 73 5210 3990 2-ethyl- and 2-tert-butyl. ....................... 45: 55 1160 650 2-isopropyl- and 2-sec-butyl- .................... 65: 35 7980 5990 2-isopropyl- and 2-tert-butyl- ................... 80: 20 6020 4510 2 sec: butyl and 2-tert-butyl ................... 70: 30 5040 3510 2-ethyl. ....................................... - 365 139 2-isopropyl- ................................... - 3100 1660 2-sec-butyl- ................................... - 2450 1480 2-tert-butyl- ................................... - 691 341 In the hydrogenation stage, in which alkylanthraquinone is hydrogenated to alkylanthrahydroquinone, a side reaction takes place more or less in addition to the main reaction, by means of which the aromatic nucleus is connected to further hydrogen atoms and tetrahydroalkylanthrahydroquinone is formed. The latter is nevertheless oxidized to tetrahydroalkylanthraquinone in the following autoxidation stage, releasing hydrogen peroxide. In this case, however, the rate of oxidation is very low. Furthermore, tetrahydroalkylanthraquinone and tetrahydroalkylanthrahydroquinone are difficult to dissolve in the solvent used in the oxidation or reduction stage, so that when the cycle reactions are repeated, the content of tetrahydroalkylanthraquinone in the working solution gradually increases, and leads to a precipitation of the working medium and a reduction in the Process speed leads. Finally, these unfavorable conditions make the production of hydrogen peroxide in the cycle much more difficult or almost impossible.

In general, the lower the side reaction, the lower the remaining Concentration of alkyl anthraquinone or the higher the degree of hydrogenation, below Formation of tetrahydroalkylanthraquinone occur increasingly in the hydrogenation stage. This is why it is when the initial concentration of alkyl anthraquinone increases a particularly high value can be increased with a relatively lower one Degree of hydrogenation possible, an increased yield of hydrogen peroxide without the risk to achieve the unfavorable accompanying side reaction, since the side reaction in this case can be reduced to a minimum without reducing the amount used of alkyl anthrahydroquinone per unit volume of working solution needs. If the degree of hydrogenation is kept below 40% then none is formed harmful amount of tetrahydro derivatives. In this way, the said unfavorable Side reaction can be effectively avoided according to the present invention.

The alkyl anthraquinone mixture that can be used according to this new process, which is mixed in such a proportion that it has the lowest melting point dissolves in solvents more than twice the amount that is normally used Working medium, e.g. B. of 2-tert-butylanthraquinone, so far as the strongest was considered soluble. This means that even if the degree of hydrogenation is up half of what is normally used is reduced from what is normally expected Amount of hydrogen peroxide can be produced without the risk of its formation of tetrahydroalkylanthraquinone.

The use of the aforementioned alkyl anthraquinone mixture has the further advantage that it effectively dissolves alkyl anthrahydroquinone. How general known, aromatic hydrocarbons dissolve alkyl anthraquinone easily, but alkyl anthrahydroquinone practically not. According to the present new process, however, it has been found that even if such hydrocarbons, as mentioned above, as a solvent for the used for the present purpose, the yield of hydrogen peroxide per unit volume the working solution has at least such a height as it is known in the art Process (see. Example 1, described below) is obtained.

In the above case is the partition coefficient of hydrogen peroxide between water and working solution extremely high, so that only by extraction hydrogen peroxide solution concentrated with water can be obtained. Come in addition, that the degree of mutual solubility between water and working solution is extraordinary is low or practically negligible, so that the extracted aqueous hydrogen peroxide solution contains practically no organic substances and an additional cleaning stage can be omitted.

On the other hand, as shown in Table II below, the degree of hydrogenation of alkyl anthraquinone may not increase sufficiently if only the solvent for alkyl anthraquinone, e.g. B. α-methylnaphthalene, xylene, is used, so that it is not always advantageous from an economic point of view to use only the solvent for the alkyl anthraquinone in the process, since the alkyl anthraquinones are expensive and required in considerable quantities. It is therefore preferable to carry out the process in the presence of a benzoic acid ester, e.g. B. butyl benzoate to be carried out as a solvent which has the appropriate solubility for the alkyl anthraquinone as well as for the alkyl anthrahydroquinone and in which the partition coefficient of hydrogen peroxide and the mutual solubility between water and working solution have values that come closest to those of the aromatic solvents. Table 1I Solubility of alkyl anthrahydroquinone mixtures and of individual alkyl anthrahydroquinones at 30 ° C and maximum achievable yields of hydrogen peroxide Mixture initial solubility of degree of maximum ratio in concentration anthrahydro-hydride yield Anthrahydroquinone weight solvent in g / 1 quinone in g / 1 tion in H20, divide solvent solvent% in g / 1 solution 2-ethyl- and 20:80 # x -methylnaphthalene 3500 24.5 0.7 0.95 2-isopropyl 2-ethyl and 20:80 butyl benzoate 3000 57 1.9 2.12 2-isopropyl 2-ethyl and 27: 73 oc-methylnaphthalene 4000 348 8.7 10.2 2 sec butyl 2-ethyl and 27: 73 3000 332 11 12.3 butyl benzoate 2 sec: butyl 2-ethyl and 27: 73 1000 183 18.3 13.2 butyl benzoate 2 sec butyl 2-ethyl and 27: 73 500 87.5 17.5 8.26 butyl benzoate 2 sec butyl 2-ethyl- and 45:55 a-methylnaphthalene 1000 110 11 7.9 2-tert-butyl 2-ethyl and 45:55 butyl benzoate 600 180 30 16.1 2-tert-butyl 2-ethyl- and 45:55 a-methylnaphthalene 550 192 35 17.1 2-tert-butyl 40 0/0 and diisobutyl carbinol 60 0/0 2-ethyl - butyl benzoate 120 49 40.8 6.34 2 sec butyl butyl benzoate 1200 122 10.2 7.49 2-tert-butyl butyl benzoate 300 153 51.1 15.4 2-tert-butyl- ca-methylnaphthalene 175 114 62.2 13.0 40 0/0 and diisobutyl carbinol 60 0/0 The above listed values of the solubility of alkyl anthrahydroquinone were determined by subjecting the working solution to hydrogenation in the presence of a catalyst and measuring the maximum amount of hydrogen absorbed without any precipitation of alkyl anthrahydroquinone. From this, the amount of alkyl anthrahydroquinone was calculated.

As can be clearly seen from Table II above, an alkyl anthraquinone mixture, for example a mixture of 2-ethyl- and 2-sec-butylanthraquinones in one suitable mixing ratio an almost equal yield of hydrogen peroxide per unit volume of the working solution like that with 2-tert.-butylanthraquinone alone is achievable unmixed, which is known to be the most effective among others Working medium is considered, although in the present case the degree of hydrogenation lower than half is chosen according to the known method.

Table II also shows that with approximately the same yields of hydrogen peroxide, the higher the initial concentration, the lower the degree of hydrogenation is, that is, the lower the risk of by-products being formed. if in this case, however, the initial concentration beyond a certain level goes, the maximum yield of hydrogen peroxide is slightly reduced, so that one an appropriate concentration of alkyl anthraquinone taking into account the Relationship between the degree of hydrogenation and the possible formation of by-products as well as taking into account the price of the solvent and the applied Can determine alkylanthraquinones.

Although in the above embodiment each of the alkyl anthraquinone mixtures contains only two anthraquinone components, it is expressly stated that the invention is not limited thereto. The mixture may of course contain three or more ingredients, e.g. B. it can consist of about 200 /, 2-ethylanthraquinone, 45 0/0 2-isopropylanthraquinone and 350 /, 2-sec-butylanthraquinone or of 250 /, 2-ethylanthraquinone, 450/0 2-sec-butylanthraquinone and 300 /, 2-tert-butylanthraquinone.

As a solvent for carrying out the present invention Process can use benzene, alkyl-substituted benzene with the boiling point between 80 and 200 ° C., α-methylnaphthalene, methyl and butyl benzoate and anisole are advantageous applied separately or in mixtures. Under certain conditions, if the solubility of alkyl anthrahydroquinones or the yield of hydrogen peroxide - to be increased in one go, this is for example from the ones listed above selected solvents, preferably in mixtures with octyl alcohol or nonyl alcohol used. The solvents for alkyl anthrahydroquinones, octyl and nonyl alcohols, however, have a high viscosity, which increases the rate of reaction is decreased. They also have a small distribution coefficient, due to which the concentration as hydrogen peroxide in that obtained in the extraction aqueous extract becomes low. They also have a relatively large mutual Solubility with water. For these reasons, these solvents are allowed in the mixture only be up to 60 percent by volume.

The following examples are intended to illustrate the nature and essence of the invention Explain the procedure in more detail. Example 1 2-ethylanthraquinone and 2-sec-butylanthraquinone are mixed in a weight ratio of 27:73 and 2000 g of the mixture in 1 1 dissolved a-methylnaphthalene. This solution occupies a volume of 4444 ccm, so that the concentration of the applied alkylanthraquinones is 900 g / 1 of the working solution is equivalent to. 50 cc of this solution are subjected to hydrogenation at 30 ° C. under normal pressure in the presence of 4.5 g of Raney nickel catalyst subjected to 334 ccm of hydrogen, calculated under normal conditions, are absorbed, which corresponds to an 8.5 ° / jgen degree of hydrogenation is equivalent to. The catalyst is then filtered off and air is introduced into the above solution blown in until it is pale yellow in color, indicating that the alkyl anthrahydroquinone is completely oxidized to alkyl anthraquinone. Distilled water is then added and shake the mixture sufficiently. After standing for some time the separated aqueous liquid phase is isolated and the hydrogen peroxide contained therein analyzed. The amount is 0.498 g, which corresponds to 9.96 g / 1 of the working solution. The yield is 97.0%, based on the amount of hydrogen consumed.

Example 2 2-ethylanthraquinone and 2-sec-butyl anthraquinone be in a ratio of 27: 73 mixed and 1000 g of the mixture in 1 1 butyl benzoate dissolved.

This solution occupies a volume of 1840 ccm, so that the concentration the applied alkylanthraquinones corresponds to 543 gil of the working solution. 50 cc this solution are at 30 ° C under normal pressure in the presence of 2.7 g of Raney nickel catalyst subjected to hydrogenation, up to 428 ccm hydrogen, calculated under normal conditions, are absorbed, which corresponds to an 18% degree of hydrogenation. Further treatment is, as explained in Example 1, carried out. In this way, 0.620 g of hydrogen peroxide are obtained obtained, which corresponds to 12.4 g / 1 of the working solution. The yield is 95.5%, based on the amount of hydrogen consumed. Example 3 2-ethylanthraquinone and 2-tert-butylanthraquinone are used in a weight ratio of 45:55 mixed. 550 g of the mixture are dissolved in 1 1 of a solvent mixture, which is based on 40 volume percent of α-methylnaphthalene and 60 volume percent of diisobutylcarbinol consists. The solution is at 30 ° C under normal pressure in the presence of a catalyst hydrogenated until an amount of hydrogen corresponding to 35 ° / jgem degree of hydrogenation is absorbed will. After filtering off the catalyst and oxidizing, the solution contains 17.1 g Hydrogen peroxide per liter.

Claims (2)

Claims: 1. A process for the production of hydrogen peroxide in the cycle by using a nearly eutectic mixture of alkyl anthraquinones as the working medium in the solvent, characterized in that benzene, an alkyl-substituted benzene, a-methylnaphthalene, methyl and butyl benzoate and anisole are separated or mixed as Solvent is used and the degree of hydrogenation is kept below 40 % in the hydrogenation of the cycle. 2. The method according to claim 1, characterized in that a mixture of a solvent according to claim 1 with an amount of up to 60 percent by volume of octyl alcohol and / or nonyl alcohol is used. Contemplated publications: Austrian Patent No. 151 946. Contemplated older patents: German patent no. 1063 581st.