DE749973C - Process for dewatering of aqueous solutions of acetic acid - Google Patents

Description

Method for dehydrating aqueous acetic acid solutions It is known aqueous solutions of acetic acid by distillation in the presence of in To dewater so-called liquid withdrawal agents, which are sparingly soluble in water. the Acetic acid remains as a tail, while the water with the removal agent distilled in the form of a hetero-azeotropic mixture; from this layering Mixture you can easily separate the water, which is poured away.

If liquids are used as removal agents which are sparingly soluble in water and do not tend to form azeotropic mixtures with the anhydrous acetic acid, the hetero-azeotropic mixture of water and removal agent can be obtained completely free of acetic acid.

Mixtures containing acetic acid and acetic anhydride from pyrolysis acetic acid can be dehydrated in a similar manner, but difficulties arise here on, since acetic anhydride in the heat for hydrolysis with regression of the acid tends. So you have to resort to liquid withdrawal agents with a boiling point like this is low so that the boiling temperature of the mixture is reduced as much as possible becomes, and which neither with acetic acid nor with acetic anhydride an azeotropic one Form mixture.

Acetic acid esters, e.g. B. ethyl acetate, Propyl acetate and isopropyl acetate. These esters were already used for dehydration aqueous acetic acid and mixtures of acetic anhydride, acetic acid and Water suggested. However, these deprivation agents, namely ethyl acetate, show the disadvantage that they dissolve a relatively large amount of water, so that in the hetero-azeotropic Mixture entrained water is by no means completely separated by stratification will. Thus, of the 711 /,) Binary mixture water Water-ethyl acetate only 4.3% in the lower layer, the remainder in the The upper layer, which contains the useful oil, is dissolved. The rest suffered increase certain impurities that are easily soluble in water, such as acetone or acetaldehyde, which are always found in the products of acetic acid pyrolysis and in some technical ones find dilute acetic acid solutions, the solubility of the water in the Acetate and are subject to normal stratification of the lietero-azeotropisclien ('etnisches Water-ethyl acetate in the way, so that the drainage is quickly ullniöglieh.

Furthermore, hydrocarbons are used in the dehydration of aqueous acetic acid and mixtures containing such known aids for the removal of full water. They are almost completely insoluble in water, but generally form with acetic acid azeotropic mixtures, so that they carry acid with them at the same time as water. This requires urgent special treatment of the aqueous layer of the @cheidegefil @ es to obtain the acid carried along.

It has been found zero that these disadvantages can be eliminated, if in just a vain column you have esters and hydrocarbons as removal agents can act, with the proviso that a special column section for each withdrawal agent is provided. This results in two separate zones in the column: In the acts immediately above the infeed of the diluted acetic acid zone the main depriving agent (Ester.), "-which alone with the acetic acid to be treated comes into contact. The task falls to the ester. on the one hand the rise of the Acid to the top of the column zti prevent, on the other hand the water by azeotropic To remove detillation from it. Acts in the zone above the column a hydrocarbon as auxiliary removal agent, which is with your water content loaded, which is fed from your underlying ester, and it into the condenser and -eiter transferred into the separating vessel in the form of the azeotropic geiniselies. Esters and auxiliary deprivation agents are used by nian with an appropriate one Number of trays in such an amount that effective hurried through the ester in the ester zone Prevention of rising -Ic: r I-.si "s @ iure <1i-inipfe after the upper part of the column as well as through the auxiliary targeting means the complete formation of cliielites is secured in your vaginal vessel in all cases.

In this way, no ester or very little ester, compared to me, gets through with the length of the insoluble carbon hydrogen, in (read a separating vessel so that the stratification takes place under extreme conditions, even in the presence volatile and soluble impurities in the acid to be rapidly watered. At this Procedure management uses the advantages of the individual targeting means and at the same time eliminates the disadvantages that had previously persisted.

It is known to use dilute aqueous solutions of acetic acid to concentrate, <let them first extracted with a mixed solvent that from an ester, e.g. B. = Italian acetate. and a hydrocarbon, e.g. 13. l; enzol, -bestelit, and dehydrating the extract by distillation, the mixed solvent acts as a withdrawal agent for water. The development column is used here not, as in the present invention, with dilute aqueous acetic acid. but with a mixture consisting essentially of the mixed solvent and acetic acid and water is continuously charged. 1 time must therefore with the older method continuously remove as much dissolver from the separator as, the amount and Composition according to your fed into the column in the same period Solvent corresponds. Accordingly, the mixed solvent only flows through the column and then pulls into the septum al>. The formation of two distinct distillation zones in the column, which is essential for the process of the present invention, is found therefore not held.

The accompanying drawing serves to explain the invention.

Eitle dewatering column A of any type is charged once and for all with your ester and an additional water-insoluble liquid removal agent in a suitable amount. The acetic acid-water mixture to be dehydrated, which may contain acetic acid etheride, flows in continuously through Rolir i and is distilled. The vapors escaping at the top of the column are condensed in B; the condensate flows through pipe 2 into the separating vessel 3 C: there it is divided into two layers. The w. äßri, s - layer is drawn off through the pipe. 3 while the withdrawing agent layer as a whole returns as reflux through the tube d into the upper K «-lonen part in the manner customary in azeotropic distillation, in order to keep the content of the feed and all the withdrawing agents constant. If necessary, part of the condensate can flow back directly into the upper part of the column through pipe d '.

Whatever happens, during the operation of the system you can drawn by inserted thermometers or by analysis Find samples that are in the column above the feed opening for the liquid to be dewatered form two distinct zones: i. A zone a. with the ester as an active ingredient. The ester forms an impenetrable restricted area for the acetic acid vapors and acts on the upward movement of the acid towards the top of the cauldron too successful counter.

A zone b as the area of action of the water-insoluble, additional, liquid withdrawal agent. This falls to the task of absorbing the water, which is added by: ethyl acetate on the underlying floors and to the top of the column and from there to the condenser. - After the Vapors are compressed in the condenser, you get a in your separator Z = complete separation of the lietera-azeotropic mixture, even if possible there are small amounts of readily soluble substances in water, such as acetone, Acetaldehyde or methanol, which causes stratification when only ethyl acetate is used impede.

Another advantage of this way of working is that from the Separating vessel, aqueous layer withdrawn through tube 3, no traces of acetic acid or contains withdrawal agents and can therefore be thrown away. That of withdrawal drugs Completely freed dehydrated product (acetic acid or a mixture of acetic acid and anhydride) flows off through tube 5 at the bottom of the column.

Certain aliphatic or aromatic hydrocarbons are suitable as additional liquid removal agents. So turns out to be a gasoline fraction that is within very narrow limits, e.g. B. at 84 to 85 °, boils, for carrying out the invention as particularly suitable. This gasoline fraction takes with it 6.5 % water, which is separated altogether in the separating vessel; in this way an extremely effective drainage is achieved. In this case the presence of the two above-mentioned working zones in the column is very evident, in that the condensed vapors do not even contain traces of ethyl acetate.

The latter condition is by no means indispensable for a smooth Course of proceedings; you can use it as an additional withdrawal agent without any disadvantage choose a substance that is sparingly soluble in water, but capable of working with ethyl acetate and water to form an easily stratified ternary azeotropic mixture. But even in this case one always finds in the column, immediately above the feed of the treatment mixture, a zone in which the ester alone is effective is.

This applies, for example, to cyclohexane, whose boiling point is 8o, 75 ° and that with water at normal pressure a boiling point of 68, g5 ° and g ° / o Forms azeotropic mixture containing water.

With ethyl acetate and water, cyclohexane forms a ternary mixture with a boiling point of 63.5 to 64 °, which contains 15 % ethyl acetate and 6.8% water. In this case, the ternary hetero-azeotropic mixture is formed on the upper trays of the column above the zone in which the binary water-ethyl acetate mixture (boiling point 70, 15 °) is located.

Although the condensed mixture contains ethyl acetate, it takes place as a result Insolubility of the cyclohexane, complete stratification takes place; here arises an aqueous layer in which practically no removal agent is dissolved and which therefore can be poured away without working up.

As a general guideline it can be stated that it is for the execution according to the invention, ten above the charge of the mixture to be treated is sufficient Soil finely with the binary water-ester mixture and about five soils with the binary mixture water-hydrocarbon (or optionally with the ternary mixture Water-hydrocarbon-ester).

For the purpose of simple illustration of the invention is of a column Been speech. The column can also be divided into several, provided that they are of this type are connected with each other that they are under similar conditions as a single Work column.

Claims (6)

PATENT CLAIMS: r. Process for dehydrating aqueous acetic acid solutions or other aqueous solutions which also contain substances such as acetic anhydride, using a mixture of dehydrating agents consisting of acetic acid esters and those hydrocarbons that also form azeotropic mixtures with water, and using a distillation column in the middle part of which the solution to be dewatered is introduced, characterized in that the mixture to be dehydrated is introduced directly, without prior extraction, into the distillation column, where an azeotropic distillation is carried out in the presence of acetic acid ester added once and for all to the column and very little water-soluble hydrocarbon is subjected, which forms a lower than the azeotropic mixture of ester and water boiling hetero-azeotropic mixture with water, whereby in the column above the feed section for the liquid to be dewatered Ability to form two distinct zones, namely a zone with the ester as the only active ingredient and above that a zone as the area of action of the water-soluble auxiliary removal agent, the amounts of the removal agents added to the column on a corresponding number of trays being such that the effective prevention of the As the acetic acid vapors rise to the upper part of the column or complete stratification in your separator is ensured. 2. The method according to claim i, characterized by the use of ethyl acetate. 3. The method according to claims i to 2, characterized in that that as an auxiliary deprivation agent a boiling within very narrow temperature limits Gasoline fraction is used. .f. Process according to claims i to 2, characterized characterized in that a substance is used as auxiliary deprivation agent, which with Water and the ester form a ternary mixture which has a lower boiling point than the azeotropic mixture has ester-water. 5. The method according to the claims i, z and .4, characterized by the use of cyclohexane as an auxiliary withdrawal agent. 6. Process according to claims i to 5, characterized in that for the ester zone ten floors, five floors are provided for the auxiliary withdrawal agent zone.