WO2019091792A1 - Process for preparing methyl isobutyl ketone - Google Patents

Abstract

The present invention relates to a process for preparing methyl isobutyl ketone starting from acetone, wherein a raw product stream of methyl isobutyl ketone, for preparation, is firstly fed to at least one first distillation column (23) and the product from the sump of this first distillation column (23) is then fed to a liquid-liquid separation device (27), in which water is separated off from an organic phase. In accordance with the invention the water phase of the liquid-liquid separation device (27) is fed to at least one further separation device (35) in which a portion of the acetone contained in the water phase is separated off from the process stream. It is possible to recover acetone from the wastewater stream as a result of the further preparation step in this further separation device (35). This leads to an optimisation of the process for preparing methyl isobutyl ketone that makes it possible to further reduce the acetone loss.

Description

 Process for the preparation of methyl isobutyl ketone

The present invention relates to a process for the preparation of methyl isobutyl ketone starting from acetone, wherein the process is carried out in one stage in a reactor section and a discharged from the reactor section crude product stream of methyl isobutyl ketone for treatment first at least a first distillation column is fed and the product from the bottom of this first distillation column Subsequently, a liquid-liquid separation device is supplied in which water is separated from an organic phase, wherein the water phase from the liquid-liquid separation device is fed to at least one further separation device in which a portion of the acetone contained in the water phase from the process stream is separated.

For example, methyl isobutyl ketone (MIBK) can be prepared by first dimerizing acetone to give diacetone alcohol (DAA) as a product. Diacetone alcohol is then dehydrated in a second step to produce mesityl oxide (MSO) as a product. Subsequently, in the third step, a hydrogenation of mesityl oxide to methyl isobutyl ketone. The conventional process known from the prior art combines all three reaction steps in a single reactor (so-called "one-step synthesis") with a palladium-loaded ion exchange resin as a bifunctional catalyst.

(Acetone) (Diacetone Alcohol)

Mesit l Oxide

Mesite l oxides

The acetone consumption per unit of recovered product (MIBK) is an important economic factor of the process. In conventional product processing about 2-3% acetone are lost.

State of the art

US Pat. No. 3,574,763 A describes a process for the preparation of methyl isobutyl ketone in which acetone reacts with hydrogen on a palladium-doped acidic cation exchange resin in a one-stage process. In this process, a yield of methyl isobutyl ketone of about 34% to 37% is obtained.

WO 2007/069109 A2 discloses a one-stage process for the preparation of methyl isobutyl ketone in which the crude product is purified in a first distillation in which acetone is recovered. The bottom product from the first distillation is fed to a liquid-liquid separator in which an organic phase is separated, which is then introduced into the upper region of a second distillation column. The resulting top product is condensed and is fed to the liquid-liquid separator. The methyl isobutyl ketone-containing bottom product is withdrawn from the second distillation column. This bottom product is fed to a third distillation column, are withdrawn from the high-boiling impurities as the bottom product and also purified MIBK is recovered. In this known method, only the organic phase from the liquid-liquid separation device is subsequently processed further, while the resulting in this separation device water phase is discharged as waste water from the system.

Due to the stoichiometry of the condensation, it produces a large amount of water. Conventionally, the water in a decanter is removed from the system by the liquid / liquid phase separation, with other processes failing because of the azeotropes in the material system. In this conventional method, the following disadvantages exist:

1 . The water contains up to 8% by weight of organic components (MIBK, acetone, alcohol) and pollutes the wastewater treatment plant. 2. Valuable components (MIBK, acetone, alcohol) can not be recycled.

 3. The residual acetone content in the decanter can be reduced by changing the operating conditions of the upstream column (acetone column), which, however, leads to a higher energy consumption and an increasing acetone loss in the by-product stream (stream 24 in the Figure 1 below), which is deducted from the head of this column. The total loss of acetone (in the by-product stream and in the wastewater stream) can not be significantly reduced by changing the operating conditions of the acetone column.

 4. The acetone loss increases throughout the life of the catalyst due to the deterioration in catalyst selectivity and the concomitant increase in by-product formation.

US Pat. No. 6,518,462 B2 discloses a process for the preparation of methyl isobutyl ketone from acetone which is carried out in several separate stages, the acetone first being converted into mesityl oxide in one column to give diacetone alcohol and further by-products. In a second reactor then mesityl oxide is reacted with hydrogen to methyl isobutyl ketone. H ₂ is first separated from the product stream and discharged from the process, and the product stream containing the methyl isobutyl ketone (MIBK) is fed to a distillation column in which methyl isobutylcarbinol (MIBC) is separated from the product stream. It should be noted that the separation of MIBK and MIBC is difficult. The MIBC accumulates in the bottom of this distillation column while methyl isobutyl ketone is withdrawn as a side stream. From the top of this distillation column, an azeotropic mixture of water and MIBK is withdrawn, which is then condensed and separated in a decanter into an organic and an aqueous phase. The aqueous phase is passed to a second decanter whose aqueous phase is fed to a distillation column from which purified water is removed. The top product from this distillation column contains mesityl oxide and water and can be recycled to the second reaction stage of the process in which the production of methyl isobutyl ketone from mesityl oxide occurs. Since this known process proceeds in several stages, the wastewater after the second reaction stage contains no acetone, which could be recovered. From the statements in this document also shows that the two-stage process over the single-stage process according to the present Invention has several disadvantages. This is firstly the need to separate the methyl isobutylcarbinol from the product stream. In addition, the two-stage process is more complex and requires a considerably larger apparatus.

DE 101 12 099 A1 describes a process for the preparation of 6-methylheptanone in which 3-methylbutyraldehyde is first reacted with acetone in an aldol reaction, followed by dehydration and finally hydrogenation with the aid of hydrogen. In the preparation of the reaction mixture must first be carried out filtration to separate the hydrogenation catalyst. In this case, a two-phase mixture is obtained with an organic phase and an aqueous phase. The aqueous phase contains 10 wt .-% acetone, which is removed by rotary evaporation in a rotary evaporator and not recovered and thus lost. The organic phase is prepared by distillation, wherein in addition to the product and acetone can be recovered by distillation from the organic phase and recycled as Recyclierstrom in the reaction. A disadvantage of this method also that in the reaction in addition to the 6-methylheptanone as a by-product and methyl isobutyl ketone is formed, which must be separated from the product in the distillation of the organic phase.

The object of the present invention is to provide an improved one-step process for the production of methyl isobutyl ketone from acetone, which makes it possible to reduce acetone loss.

The solution of the above object provides a method of the type mentioned above with the features of claim 1.

According to the invention, the water phase of the liquid-liquid separation device is fed to at least one further separation device in which a portion of the acetone contained in the aqueous phase is separated from the process stream. Thus, the invention provides at least one further work-up step in this further separation device by which it is possible to recover acetone from the wastewater stream. This leads to an optimization of the process for producing methyl isobutyl ketone, which makes it possible to further reduce acetone loss. For example, the total acetone loss via wastewater and low-boiling by-products can be reduced to well below 2% by weight, preferably to below 1.5% by weight, more preferably for example to about 1.2 to 1.3% by weight -%. At the same time, a wastewater stream with better compatibility for biological water treatment, due to a significantly reduced hydrocarbon content in the wastewater stream. In the method according to the invention, it is particularly advantageous that the acetone-rich stream obtained by separation in the further separation device is recycled to the process of processing the crude product stream. This makes it possible to reduce the acetone used as starting material in the process.

Since the acetone is a low-boiling component compared with water and, if appropriate, other organic components in the wastewater stream, it is advantageous according to a preferred variant of the process according to the invention if the acetone is recovered in the head region of the further separating device.

The further separation device according to the invention is therefore preferably designed so that a purified water stream is obtained as the bottom product from this.

It has already been mentioned above that acetone recovered from wastewater in the further separation device can be returned to the process. A preferred variant of the process according to the invention provides that the acetone-rich stream obtained in the further separation apparatus is recycled to the first distillation column or to a line leaving this first distillation column for an acetone recycle to the reactor and then the subsequent further separation steps again passes. According to a further development, the recycling of the acetone can be carried out, for example, in a recycle line for acetone separated in the first distillation column and thus combined with the acetone stream separated there and returned to the reactor.

According to a preferred variant of the process according to the invention, a third process stream is discharged as side stream from the further separation apparatus in addition to the acetone-rich stream, which is discharged in the head area and water, which is discharged from the sump, which apart from small proportions acetone of acetone contains organic components. This variant thus provides for a separation of the water phase supplied to the further separation device into three further fluid streams, wherein the said side stream may be recycled with the organic components other than acetone to an earlier separation step and / or be processed in further subsequent separation processes.

A preferred variant of the method according to the invention provides that the further separation device is a fractionating device. In this variant, a fractionation takes place in the further separation apparatus, in which the acetone is obtained as a light fraction and the side stream discharged from the further separation apparatus is a middle fraction of the Fractionation is. This middle fraction with organic components other than acetone can be utilized, for example, as a solvent mixture or as a liquid fuel. This middle fraction may contain a proportion of, for example, up to 70% by weight, preferably up to 80% by weight, for example up to 85% by weight, of organic components.

As a light fraction of the fractionation, for example, a stream of more than 80% by weight, preferably more than 90% by weight, of acetone can be produced and recycled back into the reaction section.

Because a large proportion of the acetone present in the crude methyl isobutyl ketone stream can thus be recovered by the measures mentioned in the process according to the invention, the upstream first distillation column can be operated with relatively little separation effort and little acetone loss in the top product of the column.

According to further alternative variants of the process according to the invention, the further separation device comprises a dividing wall column, a two-column system, a multi-column system or a distillation column with side draw.

A preferred further development of the method according to the invention provides that the organic phase from the liquid-liquid separation apparatus which contains methyl isobutyl ketone is subsequently fed to at least one second distillation column for further purification of the product stream. The product stream withdrawn in the head region of this second distillation column can be returned to the liquid-liquid separation device or else directly further into the separation device according to the invention. The liquid-liquid separation device is in particular a decanter.

The bottom product from the second distillation column contains the methyl isobutyl ketone and optionally high-boiling organic impurities and can be further processed and purified in subsequent process steps. For example, the product stream withdrawn from the bottom of the second distillation column can then be fed to a third distillation column in which separation of the high-boiling organic impurities is carried out, the latter being discharged from the bottom of the third distillation column and the lower-boiling purified methyl isobutyl ketone in the top region or as Obtain side stream from this third distillation column and can supply, for example, a tank or the like. In general, the single-stage reaction of acetone to methyl isobutyl ketone is a catalytic process, and a preferred development of the invention provides that in this process the aging of the catalyst and the associated decreasing catalyst activity with respect to the conversion of acetone to methyl isobutyl ketone is determined and depending on this activity of the catalyst each optimized operating condition is determined and adjusted with the least possible loss of acetone. This variant of the method according to the invention makes it possible to carry out a process optimization in this way.

As the activity of the catalyst decreases, the yield of methyl isobutyl ketone decreases and the percentage of acetone in the reaction mixture increases. This proportion of unreacted acetone in the reaction mixture can be measured, which can be concluded from the increase in a decrease in the catalyst activity.

If such a decreasing catalyst activity is detected, one can adjust, for example, the bottom temperature and / or the reflux ratio of the first distillation column (23) so that the proportion of acetone in bottom product of the first distillation column (23) is increased accordingly and then this additional acetone by the Separating device according to the invention (35) is separated and recycled in order to optimize the process in this way and to achieve optimum operating conditions with the lowest possible acetone loss and low equipment consumption in the work-up process.

The present invention furthermore relates to a plant for the preparation of methyl isobutyl ketone from acetone comprising at least one reactor whose outlet line is in communication with at least one first distillation column in which acetone is separated from a crude methylisobutyl ketone-containing crude product stream obtained in the bottom of the first distillation column; Sump of this first distillation column is in operative connection with a liquid-liquid separator, suitable to separate water from an organic phase, wherein according to the invention, the water phase from the liquid-liquid separator laxative line is in operative connection with at least one further separation device, suitable, a Separate acetone-rich stream from the water phase. By means of such a plant can be separated in the waste water of the liquid-liquid separator acetone contained and return to the system, whereby the acetone loss is reduced. At the same time a purified wastewater stream is obtained, which can be completely cleaned, for example, in a biological wastewater treatment. The system according to the invention further provides that at least one return line originating from the top section of the further separating device is returned from the further separating device to the first distillation column or into a line which leads back to the first distillation column in the upper region. In this way, acetone recovered from the water phase in the further separation apparatus can be recycled to the treatment process and ultimately also to the production process, for example if the acetone recovered in the top section of the first distillation column is returned to the reactor in which methyl acetobutyl ketone is catalytically produced from the acetone ,

Purified wastewater accumulates in the sump area of the further separation device and can be removed via a line emerging from the sump area of the further separation device.

According to a preferred further development of the system, a further line emerging from the further separating device in a side area is provided, by means of which a third process stream is removed as a side stream from the further separating device, which contains, in addition to small amounts of acetone of acetone, various organic components. These organic components can be supplied for further use and used, for example, as a solvent mixture or as a liquid fuel.

According to a preferred development of the invention, a further, the organic phase including the methyl isobutyl ketone from the liquid-liquid separator laxative line is provided which leads from the liquid-liquid separator to a second distillation column. In this second distillation column, a further treatment of the crude product stream can be carried out, which contains the methyl isobutyl ketone. Lower boiling constituents can be recycled from the top section of the second distillation column via a line to the liquid-liquid separation device or to the further separation device according to the invention.

The product stream from the bottom of the second distillation column can be fed via a line to a third distillation column in which high-boiling organic components are separated from the product stream, which can then be removed from the bottom of this third distillation column via a line. The purified methyl isobutyl ketone can be removed, for example, as a side stream from the third distillation column via a product line. Hereinafter, the present invention will be described in more detail by way of embodiments with reference to the accompanying drawings. Showing:

Figure 1 is a schematically simplified system diagram of a plant according to the invention for the production of methyl isobutyl ketone from acetone;

FIG. 1 a shows a slightly modified plant diagram relating to an exemplary variant of a plant for the production of methyl isobutyl ketone from acetone;

FIG. 1 b is a slightly modified plant diagram relating to a further exemplary variant of a plant for the production of methyl isobutyl ketone from acetone;

Figure 2 is a graph of the acetone loss in the various process streams depending on the operating conditions using the other waste stream separation apparatus of the present invention;

FIG. 3 shows an exemplary embodiment of a further separating device according to the present invention;

Figure 4 shows an alternative exemplary embodiment of another separation device according to the present invention;

Figure 5 shows an alternative exemplary embodiment of another separation device according to the present invention.

Reference will first be made to FIG. 1 and on the basis of which an exemplary embodiment of the method according to the invention and the system used in this method will be explained in more detail. Via a first feed line 10, which passes at least one heat exchanger 1 1, acetone is fed to the inlet line 12, which feeds the educt stream to a reactor 13. Hydrogen is supplied from a tank 14 to the reactor via a second feed line 15, with the first feed line 10 opening into the second feed line 15, so that the two educt streams of acetone and hydrogen are combined and fed together to the reactor 13 via the input line 12. From the reactor 13, an outlet line 16 passes through the heat exchanger 1 1, so that the product stream from the reactor 13, which was heated by the reaction in the reactor 13, undergoes a heat exchange with the acetone stream in the educt line 10 and preheats the acetone.

About the output line 16 leaves a usually biphasic hot

Product gas mixture the reactor 13 and is first fed to a separator 17, in which a separation of hydrogen takes place, which then passes through a first line 18, a heat exchanger 19 and then via a return line 20 and a Compressor 21 or a pump can be returned to the hydrogen tank 14 and used again in the manufacturing process as a reactant. Optionally, a partial flow of hydrogen can be diverted from the return line 20 and removed.

The product mixture obtained after the separation of hydrogen is fed via a line 22 to a first distillation column 23 in which on the one hand low-boiling components in the top region of the distillation column 23 can be separated and removed via a line 24. In this first distillation column 23 also acetone is separated from the product mixture and recycled via a return line 25, which emanates from the upper portion of the first distillation column 23, to the inlet line 10 for acetone, so that the acetone separated here used again in the manufacturing process and the Reactor 13 can be supplied. From the bottom of the first distillation column 23, the product stream 26, which is largely freed from the low-boiling components and which also contains the methyl isobutyl ketone, is fed to a liquid-liquid separator 27 via a product line 26. This liquid-liquid separation device 27 may, for example, be a decanter in which a separation of an aqueous phase from an organic phase takes place. The organic phase from this liquid-liquid separation device 27 is fed via a product line 28 to a second distillation column 29.

In this second distillation column 29, a mixture of lower-boiling components is obtained in the top region, which contains in particular acetone, 2-propanol, water and optionally some methyl isobutyl ketone as a heterogeneous azeotropic mixture and via line 30 to the liquid-liquid separator or to the invention further Separating device 35 can be returned. In the bottom of the second distillation column 29, the product stream is obtained, which contains mainly methyl isobutyl ketone and higher-boiling by-products. This product stream can be passed via the outgoing from the bottom of the second distillation column line 31 to a third distillation column 32. From the bottom of this third distillation column 32 separated high-boiling impurities can be removed via line 33 from the system. The purified methyl isobutyl ketone is discharged as product stream via line 34 from the third distillation column and, for example, transferred to a tank for storage or fed to further processing.

According to the present invention, a further separation device 35 is now provided, into which the water phase accumulating in the liquid-liquid separation device 27 is transferred via the line 36 coming from this liquid-liquid separation device 27. In this further separation device 35 can be a treatment and separation of the water phase the liquid-liquid separation device 27 is carried out, being separated from the wastewater in the further separation device 35 for an acetone, which is obtained in the head region of the further separation device 35 and can be recycled via the return line 37 to the first distillation column 23. The recirculation can, for example, as shown in Figure 1 can be seen such that the coming of the further separation device 35 return line 37 opens into the coming of the first distillation column 23 return line 25 in the flow path to the first distillation column 23, so that the obtained from the wastewater acetone with the acetone separated in the first distillation column 23 can be returned via line 25 to the educt line 10, in order then to supply this acetone again to the production process in the reactor 13. By using this further separation device 35, the loss of acetone via the wastewater can thus be greatly reduced.

In the further separation device 35, a middle fraction is removed as side stream, which contains various organic components other than acetone and can be removed from the system via line 38 and, if appropriate, fed to a further use. This middle fraction can subsequently be used, for example, as a solvent mixture or liquid fuel.

In the bottom of the further separation device 35, a purified water phase is obtained, which at best still contains a very small proportion of organic constituents and can be removed from the system via the line 39 emerging from the bottom of the further separating device 35.

FIG. 1 a shows a variant of the system which is slightly modified compared to the embodiment of FIG. In this variant, the stream coming from the further separation device 35 is returned via the return line 37 directly into the distillation column 23 and not into the return line 25. Incidentally, the plant parts and the process sequences are as described above in FIG.

In Figure 1 b, a further compared to the embodiment of Figure 1 slightly modified variant of the system is shown. In this variant, the stream coming from the second distillation column 29 via the return line 30 is not passed into the liquid-liquid separation device 27, but into the further separation device (column) 35. Incidentally, the plant parts and the process sequences are the same as in FIG. 1 described.

Reference is now made to Figure 2, which is a graph of acetone loss in the various process streams depending on the Operating conditions when using the further separation device for the wastewater stream according to the present invention shows. In this graph, the ordinate indicates the acetone loss in the total process in% by weight. In the drawing, a total of three curves are shown, a lower curve, a middle curve and an upper curve. The lower curve represents the acetone loss in the wastewater, the middle curve the acetone loss over the light by-products and the upper curve represents the sum of the respective values of the other two curves, ie the upper curve corresponds to the total loss of acetone in the manufacturing process. The abscissa indicates the change in the operating conditions at which the loss of acetone via the waste water or the loss of acetone can be controlled by the light by-products. These variable operating conditions during operation of the system according to the invention include, for example, the bottom temperature and the reflux ratio of the first distillation column 23.

Although the residual acetone content in the waste water of the liquid-liquid separation device 27 can be reduced by changing the operating conditions of the first distillation column 23, which is connected upstream of the liquid-liquid separation device. However, this leads in a conventional system without treatment of the wastewater to an increasing acetone loss on the by-product stream of low-boiling components, which is obtained in the top of the first distillation column 23 and discharged via the line 24 from the process. Thus, in a conventional plant, the total loss of acetone (in the by-product stream 24 and in the waste water stream of the liquid-liquid separator 27) can not be significantly reduced by changing the operating conditions of the first distillation column 23.

By the treatment according to the invention of the water phase of the liquid-liquid separation device 27, which is supplied from this via the line 36 of the further separation device 35, however, can be greatly reduced by optimizing the process conditions, the acetone loss on the wastewater and thus the total acetone loss in the Significantly reduce the process.

From the lower curve in the graph according to FIG. 2, it can be seen that, by optimizing the process conditions in the first distillation column 23, the acetone loss in the wastewater drops from, for example, 0.6% by weight to less than 0.2% by weight leaves. In the lower curve, the acetone loss decreases steadily in the direction of the abscissa from left to right. At the same time, however, the acetone loss increases over the light by-products which are removed via the line 24 (see FIG. 1) in the top region of the first distillation column 23. This acetone loss increases from the right Seen initially only slightly on the left in FIG. 2, it then increases more, whereby the decreasing acetone loss via the wastewater is overcompensated. This effect is evident from the upper curve in Figure 2, which represents the total loss of acetone. Consequently, an optimum results in the operating conditions for the first distillation column, which can be determined empirically, for example. In the graph according to FIG. 2, it can be seen that, when optimizing the process conditions, the total acetone loss can be reduced to approximately 1.2% by weight. This is evident from the upper curve in FIG. 2, which has its minimum in the right-hand area of the graph at somewhat more than 1.2% by weight.

Reference is now made to FIG 3 and based on this, a further embodiment of the invention with respect to a possible variant of the further separation device will be explained. In this variant, the further separation device comprises a two-column system. A first column 35 a of the further separation device is fed via the line 36, which comes from the liquid-liquid separator 27, not shown here, a wastewater stream having a hydrocarbon content of, for example, 3 to 7 wt .-%. In the top of this first column 35 a is a process stream with the lower-boiling organic components, which were contained in the supplied wastewater stream. These organic components discharged in the top region are then fed via line 40 to a second column 35 b of the system in which the further separation takes place, wherein acetone is obtained in the top region of this second column 35 b, which is supplied via the return line 37 to the first Distillation column (see Figure 1) can be returned. In the bottom of the first column 35 a, a purified waste water stream having a hydrocarbon content of, for example, less than 0.1 wt .-% is obtained and can be removed via line 39 from the system. In the bottom of the second column 35 b, however, a solvent mixture is obtained, which was separated from the acetone in this column and discharged via the line 38 and can be supplied to a further use, for example as a solvent mixture or as a liquid fuel.

Subsequently, reference is made to the figure 4 and based on this will be another

Embodiment of the invention concerning a possible variant of the other

Separating device 35 explained. In this variant, the further separation device comprises a

System with only one column with a side draw. This column 35 the other

Separating device is connected via the line 36, the liquid-liquid from the not shown here.

Separator comes, a wastewater stream having a hydrocarbon content of, for example, 3 to 7 wt .-% fed. In the top of this column 35 acetone accumulates, which via the return line 37 to the first not shown here Distillation column (see Figure 1) can be returned. In the bottom of the column 35, a purified waste water stream having a hydrocarbon content of, for example, less than 0.1 wt .-% is obtained and can be removed via line 39 from the system. As a side stream falls in the column 35, a middle fraction with the other organic components which were contained in the supplied wastewater stream and separated from the acetone on the one hand and the water phase on the other hand in the column 35. These organic components obtained as the middle fraction can be removed via the line 38 and fed to a further use, for example as a solvent mixture or as a liquid fuel.

In the following, reference is made to FIG. 5, and with reference to this a further embodiment of the invention relating to a possible variant of the other will be referred to

Separating device 35 explained. In this variant, the further separation device comprises a system with only one column, which is designed as a dividing wall column with an example vertical partition 35 c, wherein the partition wall 35 c is shown in Figure 5 only schematically. This vertical partition divides the cross section of the column 35 into two sections. Above the partition 35 c, a liquid phase is collected and distributed in a selectable ratio to the two column cross-sections. By means of this dividing wall column, it is possible to separate the mixture supplied via the line 36 into three components. This column 35 of the further separation device is fed via the line 36, which comes from the liquid-liquid separation device 27, not shown here, a wastewater stream having a hydrocarbon content of, for example, 3 to 7 wt .-%. In the top of this column 35 falls to acetone, which over the

Return line 37 to the first distillation column, not shown here (see Figure 1) can be returned. In the bottom of the column 35, a purified waste water stream having a hydrocarbon content of, for example, less than 0.1 wt .-% is obtained and can be removed via line 39 from the system. On the other side of the dividing wall 35 c, a side product falls in the column 35 with the other organic components which were contained in the supplied wastewater stream and separated from the acetone on the one hand and from the water phase on the other hand in the column 35. These organic components obtained as side product can be removed via line 38 and fed to a further use, for example as solvent mixture or as liquid fuel. LIST OF REFERENCE NUMBERS

 10 first educt line for acetone

 1 1 heat exchanger

 12 input line of the reactor

 13 reactor section

 14 tank

 15 second educt line

 16 output line

 17 separating device

 18 line

 19 heat exchangers

 20 return line

 21 compressors

 22 line

 23 first distillation column

 24 line for low-boiling components

25 return line for acetone

 26 Product line from the sump

 27 liquid-liquid separator / decanter

28 product line

 29 second distillation column

 30 return line

 31 line

 32 third distillation column

 33 line

34 line further separation device

a first column

b second column

c partition wall of the column

 Line for wastewater from liquid-liquid separation device 27 Return line

 Line for side stream

 Line for water phase

 management

Claims

claims A process for the preparation of methyl isobutyl ketone starting from acetone, wherein the process is carried out in one stage in a reactor section (13) and a discharged from the reactor section (13) crude product stream of methyl isobutyl ketone for treatment first at least a first distillation column (23) is fed and the product of the Sump of this first distillation column (23) is then fed to a liquid-liquid separation device (27) is separated in the water from an organic phase, wherein the water phase from the liquid-liquid separation device (27) at least one further separating device (35) is fed, in which a portion of the acetone contained in the aqueous phase is separated from the process stream, characterized in that the acetone-rich stream (37) obtained by separation in the further separation device (35) is recycled in the process of processing the crude product stream , A method according to claim 1, characterized in that the acetone-rich stream in the head region of the further separation device (35) is obtained. Method according to one of claims 1 or 2, characterized in that in the further separation device (35) recovered acetone-rich stream to the first distillation column (23) or to an outgoing from this first distillation column line (25) for an acetone recycle to Reactor is returned. Method according to one of claims 1 to 3, characterized in that as the bottom product from the further separation device (35), a purified water stream (39) is obtained. Method according to one of claims 1 to 4, characterized in that in addition to the acetone-rich stream, which is discharged in the head region and a water phase, which is discharged from the sump, from the further separation device (35), a third process stream as a side stream ( 38) is removed, which in addition to small amounts of acetone of acetone contains various organic components. Method according to one of claims 1 to 5, characterized in that the further separation device (35) is a fractionating device. 7. The method according to claim 6, characterized in that in the further separation device (35), a fractionation takes place and the discharged from the further separation device side stream (38) is an average fraction fractionation. 8. The method according to any one of claims 1 to 7, characterized in that the further separation device (35) comprises a dividing wall column, a two-column system, a multi-column system or a distillation column with side draw. 9. The method according to any one of claims 1 to 8, characterized in that the organic phase from the liquid-liquid separation device (27) containing methyl isobutyl ketone, then at least one second distillation column (29) is supplied for further purification of the product stream. 10. The method according to any one of claims 1 to 9, characterized in that it is in the single-stage conversion to methyl isobutyl ketone is a catalytic process, in this method, the aging of the catalyst and the associated decreasing catalyst activity in relation to the conversion of acetone Methyl isobutyl ketone is determined and depending on this, each optimized operating condition is determined and adjusted with the least possible loss of acetone, in particular, the proportion of acetone, which is recycled, is increased. 1 1. A method according to claim 10, characterized in that depending on the catalyst activity, the bottom temperature and / or the reflux ratio of the first distillation column (23) can be adjusted. 12. The method according to any one of claims 1 to 1 1, characterized in that in the first distillation column (23) separated from the crude product stream acetone, which is obtained in the upper part of the first distillation column (23), is recycled to the reactant stream for the production of methyl isobutyl ketone , 13. Plant for the production of methyl isobutyl ketone from acetone comprising at least one reactor (13) whose outlet line (16) is in communication with at least one first distillation column (23) in the acetone of a methylisobutyl ketone obtained in the bottom of the first distillation column (23). containing crude product stream, wherein the bottom of this first distillation column (23) with a liquid-liquid separation device (27) in Active compound is suitable to separate water from an organic phase, wherein the water phase from the liquid-liquid separation device (27) laxative line (36) with at least one further separation device (35) is in operative connection, suitable, an acetone-rich stream separated from the water phase, characterized in that at least one of the head region of the further separation device (35) outgoing return line (37) is provided, which from the further separation device (35) to the first distillation column (23) or in one of the first distillation column (23 ) in the upper area recirculating acetone returning line (25). 14. Plant according to claim 13, characterized in that one of the sump region of the further separating device (35) outgoing line (39) is provided, is discharged through the purified water. 15. Installation according to one of claims 13 or 14, characterized in that one of the further separation device (35) emanating in a side region further line (38) is provided, by means of which a third process flow as side stream from the further separation device (35) dissipated is, which in addition to small amounts of acetone of acetone contains various organic components. 16. Plant according to one of claims 13 to 15, characterized in that a further, the organic phase including the methyl isobutyl ketone from the liquid-liquid separator (27) laxative line (28) is provided, which of the liquid-liquid separator (27) to a second distillation column (29), wherein the plant comprises a third distillation column (32) and wherein a from the bottom of the second distillation column (29) outgoing line (31) is provided which leads to the third distillation column (32) ,