DE818343C - Process for dewatering unsaturated aldehydes - Google Patents

Description

Process for Dewatering Unsaturated Aldehydes The invention relates to a process, unsaturated aldehydes, especially a-, ß-unsaturated aldehydes, which contain three or four carbon atoms in the molecule, such as aerolein and 2-methylacrolein, to make anhydrous or at least very little water, if the unsaturated Aldehydes come into contact with water at any stage in their production. This stage can already be the formation reaction, at which in some cases Water is created as a by-product. Water can also after its formation with the unsaturated Aldehydes come into contact, for example, when the reaction products are caused by the addition of water be cooled directly or during a purification stage which includes the addition caused by water.

The virtually complete removal of water from the unsaturated Aldehydes are made more difficult because they form azeotropic mixtures with water. Aerolein e.g. B. forms an azeotropic mixture that is 2.7 percent by weight at atmospheric pressure Contains water.

According to the invention, the unsaturated aldehydes before, during or after the stage in which they are in contact with water, a liquid hydrocarbon added while in a further stage of the production of the unsaturated aldehydes an aqueous liquid phase, which is practically free of unsaturated aldehydes, is deposited from a liquid phase, which the added hydrocarbon, along with practically the entire amount of the unsaturated aldehyde and an amount of water which is in proportion to the amount of aldehyde is much less than in the azeotropic mixture of the unsaturated aldehyde with water.

In some cases the one obtained in this way contains little water Solution of an unsaturated aldehyde in a hydrocarbon without further application can find. If necessary, the hydrocarbon can be stripped from the mixture. If a hydrocarbon is chosen, its boiling point differs from that of the unsaturated Aldehyde is different that both can easily be separated by distillation the hydrocarbon is finally deposited, either as a distillate or as a residue and possibly used again in the same way.

Appropriate treatment can possibly reduce the small amount of water remove from the solution of the unsaturated aldehyde in the hydrocarbon, e.g. B. by bringing the mixture into contact with a water-binding agent.

Preferably, however, the water is driven off by means of a distillation, which results in a mixture as a distillate, which in addition to unsaturated aldehyde a contains a small amount of hydrocarbon and a few percent by weight of water and as Residue a mixture that contains the added hydrocarbon together with the Most of the unsaturated aldehyde originally present and practically none Contains water.

The former mixture, the mainly unsaturated aldehyde, but also contains water, can be collected until a sufficient amount is available is to be treated according to the invention process. With continuous use of the invention process, it is more advantageous to use the mixture mentioned Add amount of unsaturated aldehyde, which according to the invention process is to be treated or has already been partly treated according to this procedure, but not yet. has reached the stage in which the aqueous liquid phase is separated. It is beneficial in many cases not to have an earlier stage of manufacture for the addition to choose as is necessary, but it is always possible to choose that Allow the addition to take place earlier.

The anhydrous mixture of the unsaturated aldehyde with the hydrocarbon, which has been obtained in the above-described distillation can be used as such Can be used or separated by further distillation. This distillation 'Can form a continuation of the first distillation, in which the water is driven off using the same apparatus. But you can also mix it Transfer to another distillation vessel.

The boiling points of the azeotropic mixtures of unsaturated aldehydes with water are little different from those of pure aldehydes. The boiling point of pure acrolein is for example 52.69 ° and that of the azeotropic mixture of acrolein with 2.7 percent by weight of water is 52.39 °. A mixture of acrolein finite less than 2.7 percent by weight " 'water is practically hardly by distillation to separate into pure acrolein and azeotropic mixture. surprisingly is such a separation is possible in the presence of a hydrocarbon.

In the process of the invention, aromatic hydrocarbons, paraffinic hydrocarbons Branched and straight chain hydrocarbons, olefins, cycloparaffins and cyclic olefins are used, including their homologues and hydrocarbon fractions, in which they appear.

If one wants to use distillation separation, it is Indian Usually advantageous to use hydrocarbons whose boiling point is significantly higher than that of the unsaturated aldehyde. When acrolein and 2-Nletliylacrolein are Very good results have been achieved especially with xylene. But it is also possible provided that special measures are taken with regard to temperature and / or pressure are to use low-boiling hydrocarbons such as propane or butane.

The amount of hydrocarbons added can be within wide limits vary. Preferably, however, between the amounts of hydrocarbon and of the unsaturated aldehyde selected a ratio expressed in the volumes of the pure substances, which is between 5: i and io: i.

In a simple form of application of the inventive method, the Hydrocarbon of a homogeneous or inliomogeneous mixture of the unsaturated aldehyde added with water, which mixture may still contain by-products. in the : In particular, saturated aldehydes and ketones may be present as impurities be. These compounds are often used as by-products in the production of unsaturated compounds Aldehydes are formed and in many cases they are difficult to separate because of their boiling points are very close to those of the unsaturated aldehydes.

As by-products in the production of acrolein through oxidation from propylene z. B. acetone and propionaldehyde d. The total of the same Can be up to 10 percent by weight of the aerolein.

A particular advantage of the invention process is that the possibly saturated carbonyl compounds present in the aqueous liquid phase loosen and can be removed almost entirely if sufficient for the presence of one Amount of water is taken care of.

Fig. I shows, for example, schematically a simple apparatus for continuous application of the invention process using a hydrocarbon, which boils higher than the unsaturated aldehyde.

Through line i a homogeneous or inhomogeneous mixture becomes one unsaturated aldehyde with water into the delamination chamber 3 directed. A hydrocarbon is fed through line 2 into the same chamber. In the chamber the aqueous liquid phase sinks to the bottom, while the liquid which contains the added hydrocarbon together with the unsaturated aldehyde, rises.

Since the temperature in the delamination chamber is preferably below should remain a certain value, depending on the type of unsaturated aldehyde and the possible admixtures, the cooler 4 is attached in the supply line. Possibly. the chamber itself can also be cooled. The aqueous liquid is by means of the line continuously removed from chamber 3. The upper liquid layer is through the line 6 is fed to the distillation column 7. This column becomes through Line 8 drained a residue, which mainly consists of a mixture of unsaturated Aldehyde and hydrocarbon. This mixture is fed to a column 9 and subjected to distillation therein, a vapor fraction being mainly consisting of anhydrous unsaturated aldehyde, from a residue, mainly consisting of hydrocarbon, is separated. The steam fraction is through pipe discharged io, the residue through line i i. The hydrocarbon can by means of Line 12 can be returned to the separation chamber 3. Possibly the hydrocarbon are also fed through line 13 to the upper part of the column 7, which, for. B. may be of interest for cooling this part of the column.

The water-containing 'mixture that escapes from column 7 in vapor form, is returned through line 14 to separation chamber 3.

When saturated carbonyl compounds from the unsaturated aldehyde need to be separated, you can of course also first the hydrocarbon and afterwards add the water. So what comes out is that a homogeneous Mixture of raw unsaturated aldehyde and hydrocarbon by adding water is washed out, whereby the saturated carbonyl compounds pass into the water, but also a small part of the water dissolves in the organic liquid mixture.

For the removal of saturated carbonyl compounds from raw It is often unsaturated aldehyde with the help of water and a hydrocarbon advantageous, the addition of the water and the hydrocarbon take place simultaneously to read. This is especially the case when using the so-called Duosol principle, which is widely used in lubricating oil refining (see e.g. Petroleum Refiner, 27, 1948, p. 178). So you let water through a vessel and a hydrocarbon flow in countercurrent while midway between the feed points of these two liquids the unsaturated aldehyde to be extracted into the vessel is initiated. : A water-containing mixture is left on the top of the vessel of hydrocarbons and unsaturated aldehydes and on the underside an aqueous one Liquid that contains the saturated @ carbonyl compounds.

This duosol extraction and the subsequent separation of the unsaturated Aldehydes in anhydrous state can be carried out by means of the apparatus, which is shown schematically in FIG.

The crude unsaturated aldehyde contaminated with saturated carbonyl compounds, is fed to the extraction column 17 through line 15. Water is introduced through line 18 and a suitable hydrocarbon through line 20. The liquid in column 17 is, if necessary, kept at the appropriate temperature by means of the Coolers 16, 19 and 21 in the supply lines and possibly by other temperature-regulating Devices not indicated in the figure. Through line 22 this is drained aqueous liquid mixture, while the water-containing mixture of Hydrocarbon and unsaturated aldehyde through line 23 of the distillation column 24 is fed, the function of which corresponds to that of the column 7 in Fig. I. The further treatment is also analogous to that in the apparatus according to FIG. With the numbers 24 to 31 designated items correspond to the items 7 'to 14 in Fig. I. The line 29 is now connected to the supply line 20 for the Hydrocarbon, just like line 12 on line 2 before.

Both when a previously prepared mixture of the raw unsaturated Aldehyde and a hydrocarbon is extracted using water, as if that If the duosol principle is used, it is recommended that the extraction be carried out in a vessel to carry out, in which a good mixing is ensured and afterwards the liquid phase, which contains the hydrocarbon and the unsaturated aldehyde, in a special, to transfer the layer separation serving vessel. The watery one that was dragged along Liquid is separated in it and can be drained off, while the water-containing one Mixture of hydrocarbon and unsaturated aldehyde may be treated further for drying and / or for isolating the unsaturated aldehyde.

In Fig. 3 an apparatus for duosol extraction is shown schematically, whereby the principle just discussed applies that special vessels, for the extraction and separation of the liquid layers are present. The apparatus is a combination of the two apparatuses according to FIGS. I and 2, so that a detailed explanation can be omitted. They are the same reference numbers has been used as in Figs. i and 2, the number of Fig. i being preferred has been given if a different number for an analog item in FIG was used.

The watery liquid that is drained at 5 can now through Line 32 is fed to line 18 and thus again in the duosol extraction column 17 can be used.

Through line 33 becomes, fresh hydrocarbon from fed outside the system. In this line opens line 12, which the recirculates already used hydrocarbons. The supply lines are on line 33 2 and 2o, for the layer separation chamber 3 and for the extraction column 17, connected. It is therefore possible to have an extra amount of hydrocarbon in the chamber 3 to add, which can often be beneficial.

When extracting raw aerolein and 2-methylacrolein by means of Water and xylene it is of interest, the temperature in the extraction column below 30 °, otherwise the distribution coefficients of the various substances present in the two solvents are less favorable. It is preferable do not let the temperature rise higher than 20 °. Is very cheap the area between o and io °, but it is often necessary to reach this temperature area a relatively expensive cooling system is required.

After a pre-treatment, the very volatile and a big one Some of the high-boiling components have been removed from raw aerolein by oxidation of propylene, for example the following composition: Aerolein 80 bis 9o percent by weight, acetaldehyde 3 to 10 percent by weight, propionaldehyde 0.5 to 3 percent by weight, acetone i, o. To 5 percent by weight, high-boiling organic compounds i, o to 2, o percent by weight, water 2.4 to 6, o percent by weight.

Propionaldehyde and acetone in particular are very difficult to remove, when it comes to technical quantities, because their boiling points are that of aerolein are very close. The relative solubilities of the various components of the raw aeroleins in readily available solvents such as water, hydrocarbon egg and alcohols, are not such that these ingredients can be removed by simple extraction are to be separated. Surprisingly, however, this is possible with the help of the described Duosol method. 'On the whole, the same applies to 2-methylacrolein as to Aerolein. Contains crude 2-methylacrolein, made by the oxidation of isobutylene i.a. Propionaldehyde, n-butyraldehyde and isobutyraldehyde, which are difficult to use by distillation or simple extraction are separated from it.

It is generally advantageous for the purpose of being more complete Removal of the saturated carbonyl compounds during Duosol extraction water in at least a twofold excess: to be added with respect to the hydrocarbon. Here, however, one encounters the difficulty that it is relatively much more unsaturated Aldehyde, e.g. B. Aerolein, dissolves in water, often over i 17v.

In a particular plant described in Example 4 is a measure possible to recover this aerolein in whole or in part.

Another measure that can be taken to eliminate the aforementioned difficulties can meet is that one can look for a different relationship between the two Solvents in the parts of the extraction column ensures that above and below the supply of the mixture to be extracted. If the relationship between the Amounts of water and hydrocarbon at the top of the column are greater and at the bottom in the column is smaller, the water above will be able to take up the undesirable constituents by the relatively large amount unsaturated aldehyde, which is also dissolved in water to a large extent passes into the hydrocarbon at the bottom. The quantitative ratio is preferably made from water to hydrocarbon larger than i above and smaller than i below in the Column.

This principle can be put into practice by means of the apparatus, . Which is shown schematically in FIG.

Crude unsaturated aldehyde is fed into the extraction column through line 59 5o passed, in which water is also introduced through line 51 and a high boiling point Hydrocarbon, e.g. B. xylene, through line 52. The aqueous liquid and the hydrocarbon solution are, as usual, below at 53 and above at 54 drained. In addition, however, something above the import 59 through the line 55 drained an inhomogeneous mixture with the composition, which in this Height in the column is present. This mixture is fed to the distillation column 56, from which a distillate escapes at 57, mainly consisting of water, but mixed with some hydrocarbon and quite a bit of unsaturated aldehyde. This mixture is returned to the apparatus, e.g. B. after import 51. it can be treated separately with a hydrocarbon to split it into two phases to be disassembled, both of which are fed back into the system at suitable points can.

The residue, consisting mainly of hydrocarbon and unsaturated Aldehyde, can possibly be further treated separately, but is preferably something lower than the import 59 returned to the extraction column 5o, for which purpose in of the figure, the line 58 is present.

If low boiling hydrocarbons are used, e.g. B. isobutylene, the procedure will of course have to be modified somewhat with reference to the further treatment of the fractions from the distillation column, which in this Case have a completely different composition. However, these amendments are available of the hand and do not require any further discussion. Example i The Azeotropic Mixture water and aerolein containing 2.7 weight percent water are mixed with a hydrocarbon, for which xylene was chosen in two of the cases considered here and in the other two cases one paraffinic denoted TS-i Hydrocarbon fraction with a boiling range from i 50 to i 60 °.

The mixture thus obtained was each time put in an apparatus as in Fig. I, brought and treated therein in the manner described above.

The results obtained are shown in the following table. Added hydrocarbon Xylene xylene TS-i TS-i Volume ratio of the added hydrocarbon to treated acrolein-water mixture. . . . . . . .... ...... 9 9 9 9 Temperature in the delamination chamber 3. . . . . . . . . o '' 20 ° o "20 ° Percentage by weight of water in the from chamber 3 to column 7 flowing mixture in relation to that in this mixture contained aerols .. ................ ......... .. o.7i 0.96 0.35 0.45 Percentage by weight of water in the final aerolein o, oi o, oi o, oi 0.01 In the case where loading takes to which -the first column, was thus being mixed with xylene in nine-fold excess, while the temperature was in the separation vessel o °, the further data is still to be mentioned. Weight percent Aerolein Xylene water Composition above Layer in the separation vessel 3. . . . . . . . . . . . 18.0 81.8 0.208 Composition De- Stillat from column 7 9i, 8 4.88 3.32 composition Residue from co- lonne 7. . . . . . . . . . . . 14.1 85.9 0.0033 Examples In the apparatus shown in Fig. 3, raw acroleiri was continuously treated in the manner described above. Xylene is used as a hydrocarbon. The temperature in the extraction column 17 was 9 °. The acrolein-xylene gemisoh obtained had a water content of 0.83 percent by weight. In this mixture, the ratio of the amounts of xylene and aerolein, expressed in terms of the volume of the pure substances, was 9: i. In the delamination chamber 3, the temperature of 21 ° was maintained. It was found that the aerolein finally obtained had a water content below 0.02 percent by weight.

Example 3 Containing a number of aeroleins or 2-medhylaeroleins Mixtures were made in the manner described above in that illustrated in FIG Treated apparatus. The composition of the: Mixtures was as follows: 1. 94.6 Weight percent aerolein, 5.4 weight percent propionaldehyde; 2. 94.4 percent by weight Aerolein, 0.7 percent by weight propionaldehyde, 4.86 percent by weight acetaldehyde; 3, 4 and 5 raw aerolein with .6 weight percent acetaldehyde, 2 weight percent Propionaldehyde, 2 percent by weight acetone; 6. Crude 2-methylacrolein at 1.5 weight percent Aerolein, 2.5 percent by weight propionaldehyde, 2.9 percent by weight acetone, about 0.5 Weight percent isobutyraldehyde, 1.4 weight percent acetaldehyde.

The latter mixture was described in more detail in Example 5 Way fed together with water to the extraction column. Water is in the added amount included, which is given in the following table.

The rare results are summarized in this table. TS-i denotes the same hydrocarbon as in example i. r 2 3 4 5 Applied hydrocarbon xylene xylene TS-i xylene xylene xylene Feed rate in g / min: Mixture to be treated. . ... . . . ... . . ... . . . 0.78 1.51 - - - 750 Water ........ ............................ 6.9 3.4 9 *) 9 *) 9 *) 2270 Hydrocarbon. . . . . . . . . . . . . . . . . . . . . . . ..... 6.9 7.3 1.7 *) 6.4 *) 7.6 *) 7825 Extraction temperature ....................... - - o ° o ° o ° 2o0 Temperature of the water supplied. . . . . . . . . . . 8 ° 7.50 - - - - Temperature of the supplied xylene. ... . . . . . . . . 7 ° 1.5 ° - - - - Purity of the finally obtained aerolein or 2-Metylacrolein in percent by weight. . . . . . ... 98.4 99.6 9911 99.2 9919 99> 9 '@) Weight ratio in relation to raw arcolein I 2 3 4 p Applied hydrocarbon xylene xylene TS-i xylene xylene xylene Yield of pure aerolein or 2-methylacro- lein in% ................................. 98.9 9910 97.6 9912 99.6 99 Aerolein in xylene phase in percent by weight ...... 9.47 7.53 - - - - Acrolein in water phase in percent by weight .... 0, i-2 0.23 - - -T - Saturated carbonyl compounds in the xylene phase in percent by weight ... .................... 0.15 0.029 - - - - Saturated carbonyl compounds in the water phase in percent by weight ......... .............. 0.42 0.32 - - - - Number of theoretical stages in extraction: Below the feed ........................ 8 io 8 7 12 5 Above the feed ......................... 12 4 12 3 8 5 Example 4 In this case the apparatus which is shown schematically in FIG. 4 was used.

A raw mixture containing acrolein obtained by the catalytic Oxidation of propylene was fed to separator 37 through line 34. The reaction product was cooled by adding water via line 35 and the mixture was continued cooled by means of the cooler 36.

In the separator 37. a liquid layer, consisting mainly of aerolein, acetone, propionaldehyde, formaldehyde, water and high-boiling organic substances, was deposited by a gaseous fralt ion, which also contained considerable amounts of acrelein and other compounds boiling at approximately the same temperature. The gas phase was fed through line 38 to the absorption column 39 , in which it was washed with water at an overpressure of about 8.5 atmospheres. The water was introduced into column 39 through line 4o. A gas mixture containing propylene, among other things, was discharged through line 41. The washing water rich in aerolein was introduced through line 42 into line 43 and there combined with the liquid phase which was separated in separator 37. From line 44 the liquid entered the distillation column 45, wherein crude aerolein was distilled off from a liquid residue mainly containing water, formaldehyde and high boiling point organic matter. This residue was drained at 46 and removed from the system. The distillate had the following composition, disregarding the amount of water it contained (a few percent by weight): Aerolein 82.9 percent by weight, acetaldehyde 12.5 percent by weight, propionaldehyde 3.6 percent by weight, acetone 1.0 percent by weight.

The distillate was treated further in a part of the apparatus which corresponds to the apparatus shown in FIG. A detailed description of the treatment can therefore be omitted. The reference numbers are the same as those used in Figure 3 for matching subparts. It should only be noted that the aqueous liquid from the layer separation chamber could now be returned not only through line 32 to the extraction column 17 , but also through line 47 to the cooling water line 35.

The results obtained during the extraction and further processing are shown in the following overview. Two cases are considered in which the amounts of water and xylene fed to the extraction column and their temperatures were different. Feed rate in g, min: Raw aerolein. . . . . . . . . . . . . 0.82 0.82 Water .................... 25.5 19, o Xylene ..................... 20.5 12.1 temperature Water . . . . . . . . . . . . . . . . . . . . o to 5 ° io to 12 ° Xylene ...................... o to 5 ° to 12 ° Composition in weight percent: Aerolein in xylene phase ...... 3.02 - 2.40 Aerolein in water phase ..... 0.11 0.31 Saturated carbonyl compounds gene in xylene phase ......... 0.035 o, o6 Saturated carbonyl compounds genes in the water phase ....... o, 86 1.7 Purity of the final ten aeroleins in weight percent .................. 98.9 97.7 Yield of pure aerolein in% .................... 96 83 Number of theoretical levels when extracting: Below the feed ....... io io Above the feed. . . . . . . . . 4 4 If one wants to avoid that the small amount of aerolein, which dissolves in the water phase, is completely lost, then all or part of the aqueous liquid can be fed through line 48 to column 45.

Example s A raw aerolein containing mixture obtained by catalytic oxidation of propylene, was treated in the apparatus according to Fig. 4, in the same manner as described in Example 4, but with the Difference, that the treatment in column 45 was omitted. The proportionate dilute aqueous solution of the crude acrolein from lines 42 and 43 was made fed directly to the extraction column 17 through line 49. The formaldehyde and the high-boiling impurities contained in this liquid, are now in the aqueous extract phase drained from the column 17 through line 22 recorded.

The mixture passed into the extraction column contained 6.7 parts by weight Acetaldehyde, 2.2 parts by weight of propionaldehyde and 2.2 parts by weight of acetone to 100 Parts by weight of acrolein.

For two cases where the conditions were slightly different, the results are shown in the following table: Feed rate in g ;; min: Mixture of water and raw Acrolein. . . . . . . . . . . . . . . . . 750 750 Water .................... 1550 1935 Xylene ...................... 2190 168o Extraction temperature ...... o ° 20 ° Purity of the final ten acroleins in weight percent ................. 99.4 98.9 Yield of pure acrolein in % . . . . . . . . . . . . . . . . . . . . 98.1 97.2 Number of theoretical levels when extracting: Below the feed ....... 1o 15 Above the feed. . . . . . . . 5 1o

Claims (7)

PATENT CLAIMS: i. Process for dehydrating unsaturated aldehydes, in particular a-, ß-unsaturated aldehydes which contain three or four carbon atoms in the molecule, such as acrolein and 2-methylacrolein, if they come into contact with water in any stage of their production, characterized in that the unsaturated Aldehydes before, during or after the stage in which they have come into contact with water, are extracted with a liquid hydrocarbon, preferably xylene, whereupon the aqueous liquid phase formed in a later stage of production, which is practically free from unsaturated aldehydes , is separated from the non-aqueous liquid phase which contains the added hydrocarbon together with practically the entire amount of the unsaturated aldehyde and an amount of water which, in relation to the amount of the unsaturated aldehyde, is essentially less than in the azeotropic mixture of the unsaturated aldehyde with water. 2. Procedure according to claim i, characterized in that the boiling point of the used for the extraction The hydrocarbon is so different from that of the unsaturated aldehyde that both possibly after further reducing the water content of the final from the Hydrocarbon and the unsaturated aldehyde obtained mixture, easily through Distillation are separated, the hydrocarbon optionally again used in the same way. 3. The method according to claim i or 2, characterized characterized that from because a mixture of hydrocarbons and still containing water unsaturated aldehyde, the water is driven off by distillation, being as Distillate a Mischlug is obtained, which in addition to unsaturated aldehyde a. low Contains amount of hydrocarbon and a few percent by weight of water, and as a residue a mixture that contains the added hydrocarbon along with most of it of the unsaturated aldehyde originally present and practically no water. 4. The method according to claim 3, characterized in that the by distillation deposited hydrous mixture added to an amount of the unsaturated aldehyde is to be treated according to the method according to claim i or already partially has been treated, but not yet the step of separating the aqueous liquid has reached. 5. The method according to claim i to 4, characterized in that in the space serving to separate the liquid phase is a temperature below 30 °, preferably between 0 and 2o ° is maintained. 6. The method according to claim i to 5, characterized in that the crude unsaturated aldehyde, possibly already finitely can be diluted in countercurrent with the hydrocarbon and the water Water extracted. 7. The method according to claim 6, characterized in that after the extraction vessel another vessel for the further separation of water Liquid from the hydrocarbon extract phase is connected downstream. B. Procedure according to claim 6 or 7, characterized in that in the upper part of the extraction vessel a higher ratio between the amounts of water and hydrocarbon than is retained in the lower part of the same vessel.