EP4146618A1 - Method for breaking down michael adducts contained in a fluid f and formed during the preparation of acrylic acid - Google Patents

Abstract

The present invention relates to a method for breaking down Michael adducts of acrylic acid, which adducts are contained in a fluid F, in a breakdown apparatus which comprises at least one separating column K, an evaporator V and a pump P, in which method, when the viscosity of the residue R in the sump chamber of the separating column K increases in an undesired manner, the inflow of the fluid F into the breakdown apparatus is interrupted, the residue R in the sump chamber of the separating column K is diluted with a solvent 1 and cooled, and the sump chamber of the separating column K is emptied.

Description

Process for the cleavage of Michael adducts contained in a liquid F, which were formed during the production of acrylic acid

description

The present invention relates to a process for the cleavage of Michael adducts of acrylic acid contained in a liquid F in a cleavage device which comprises at least one separating column K, an evaporator V and a pump P, with an undesirable increase in the viscosity of the residue R. in the bottom space of the separating column K, the feed of the liquid F into the splitting device is interrupted, the residue R in the bottom space of the separating column K is diluted with a solvent 1 and cooled, and the bottom space of the separating column K is emptied.

Acrylic acid is an important intermediate that is used, for example, in the production of polymer dispersions (this also in the form of their esters with alcohols) and superabsorbents.

Acrylic acid is produced, among other things, by heterogeneously catalyzed gas phase partial oxidation of C3 precursor compounds of acrylic acid (this term is intended to include, in particular, those chemical compounds that are formally obtainable by reduction of acrylic acid; known C3 precursors of acrylic acid are, for example, propane, propene, Acrolein, propionaldehyde and propionic acid; however, the term should also include precursor compounds of the aforementioned compounds, such as glycerol (starting from glycerol, acrylic acid can be generated, for example, by heterogeneously catalyzed oxidative dehydration in the gas phase; cf. e.g. EP 1 710227 A, WO 2006/114506 and WO 2006/092272)) with molecular oxygen on catalysts in the solid state of aggregation at elevated temperature (for example DE 10 2007 055 086 A and DE 102006 062 258 A).

Due to the numerous parallel and subsequent reactions occurring in the course of the catalytic gas phase partial oxidation as well as due to the inert diluent gases to be used in the context of the partial oxidation, the catalytic gas phase partial oxidation does not result in pure acrylic acid, but rather a reaction gas mixture (a product gas mixture) which is obtained in the essential acrylic acid, which contains inert diluent gases and by-products, from which the acrylic acid must be separated. The acrylic acid is usually separated off from the reaction gas mixture, among other things, by first converting the acrylic acid from the gas phase into the condensed (liquid) phase using absorptive and / or condensation measures. The further separation of the acrylic acid from the liquid phase produced in this way is then usually carried out using extractive, distillative, desorptive, crystallizing and / or other thermal separation processes.

One such undesirable side reaction is free-radical polymerization with itself under the formation of acrylic acid polymer or oligomer. The disadvantage of this secondary reaction is that it is essentially irreversible, which is why monomeric acrylic acid converted into free radical acrylic acid polymer is lost for the acrylic acid production process and the acrylic acid yield of the production process is reduced. The advantage of the undesired free-radical polymerization of acrylic acid, however, is that it can at least be reduced by adding polymerization inhibitors.

The latter does not apply to the second undesirable side reaction of acrylic acid in the liquid phase. This side reaction involves the so-called Michael addition of an acrylic acid molecule to another acrylic acid molecule, with the formation of a dimeric Michael adduct ("dimeric acrylic acid"), which is formed by further Michael addition of acrylic acid molecules ("monomeric acrylic acid"). ) can continue with Michael adducts that have already formed with the formation of oligomeric Michael adducts (“oligomeric acrylic acid”).

Dimeric Michael adducts and oligomeric Michael adducts are to be subsumed in this document under the designation “Michael adducts”. If the prefix “Michael” is missing in this font, the terms “oligomerizate” and “polymerizate” mean the compounds that grow through radical reactions.

In contrast to the radical polymerization of acrylic acid, the formation reactions of the Michael adducts are typically reversible formation reactions. Since the boiling point of acrylic acid is below that of the Michael adducts (from which it was reformed), the reformed acrylic acid can be continuously removed from the reaction equilibrium by superimposing a corresponding pressure gradient and the reverse reaction can be completed successively.

A recovery of the acrylic acid contained in the Michael adducts chemically bonded in this way is desirable insofar as this increases the target product yield in the manufacture of acrylic acid. Due to the comparatively high boiling points, the Michael adducts are usually obtained as a component of bottom liquids in the thermal separation of liquid reaction product mixtures in the context of the production of acrylic acid. Typically, such bottom liquids contain, based on their weight,> 10% by weight of Michael adducts.

In addition, such liquids containing Michael adducts usually contain other constituents in addition to acrylic acid whose boiling points are different from those of the Michael adducts.

These boiling points can lie both above and below those of the Michael adducts. Therefore, if one subjects liquids containing Michael adducts, which were formed during the production of acrylic acid, to a process for cleavage of the Michael adducts they contain by supplying thermal energy, the resulting cracking gas containing at least a portion of the cracking products is preferably subjected to countercurrent rectification in order to recover the cracking products contained in the cracking gas with increased purity (cf., for example, WO 2004/035514).

Usually, therefore, a process for splitting back Micha el adducts contained in a liquid with a weight fraction, based on the weight of the liquid, of> 10% by weight, which were formed during the production of acrylic acid, is carried out in a splitting device ( see e.g. WO 2010/066601).

However, a disadvantage of the cleavage process has been found to be that the viscosity of the residue can increase unexpectedly during continuous operation.

EP 3255 030 A teaches the addition of higher alcohols during the splitting of the residue, with maleic anhydride contained in the residue being converted into maleic acid esters that are less sensitive to polymerization.

No. 6,414,183 teaches the dilution of the discharged residue with solvents such as acetic acid, water and methanol.

WO 2007/147651 describes the distillation of residues sensitive to polymerization in the presence of a boiling oil. The object of the present invention was therefore to provide an improved Rückspaltver drive available.

Accordingly, there is a method for cleaving back Michael adducts of acrylic acid which are contained in a liquid F and which were formed during the production of acrylic acid, the liquid F containing at least 10% by weight of Michael adducts of acrylic acid, based on the liquid F, in a cleavage device, the at least one separation column K, which from bottom to top consists of a bottom space, a separation space adjoining the sump space, containing separating internals and a head space adjoining this and in which the pressure in the gas phase is from below decreases towards the top, comprises an evaporator V and a pump P, wherein Michael adducts contained in the liquid F are cleaved at a temperature of 130 to 240 ° C and removed by distillation and the remaining residue R is discharged, characterized in that at a undesired increase in the viscosity of the residue R in the bottom space of the separating column K of the feed of the liquid speed F is interrupted in the cleavage device, the residue R in the bottom space of the separating column K is diluted and cooled with at least 10% by volume of a solvent 1, based on the total volume of the residue R in the bottom space of the separating column K, and the bottom space of the separating column K is emptied, the solvent tel 1 having a boiling point at 1,013 hPa of at least 150 ° C and a solubility in water at 25 ° C of at least 10 g per 100 g of water.

The liquid F preferably contains at least 20% by weight Michael adducts of acrylic acid, particularly preferably at least 30% by weight Michael adducts of acrylic acid, very particularly preferably at least 40% by weight Michael adducts of acrylic acid, each based on the Liquid F.

The Michael adducts contained in the liquid F are cleaved at a temperature of preferably 140 to 220.degree. C., particularly preferably 150 to 200.degree. C., very particularly preferably 155 to 180.degree.

The evaporation of the acrylic acid released during the cleavage can be assisted in various ways. The cleavage can be carried out, for example, under reduced pressure. However, it is also possible for a stripping gas to be passed into the cleavage device above the bottom liquid and below the lowermost separating internals of the separating column K. In the latter case, it is advantageous to interrupt the supply of stripping gas in the Spaltvor direction in the event of an undesired increase in the viscosity of the residue in the bottom space of the separating column K. The solvent 1 has a boiling point at 1,013 hPa of preferably at least 170 ° C, particularly preferably at least 190 ° C, very particularly preferably at least 210 ° C, and a solubility in water at 25 ° C of preferably at least 20 g per 100 g of water, particularly preferably at least 30 g per 100 g of water, very particularly preferably at least 40 g per 100 g of water.

The boiling point of solvent 1 at 1,013 hPa should be as higher as possible than the temperature of the residue R.

Suitable solvents 1 are, for example, alcohols such as ethylene glycol, propylene glycol, diethylene glycol, triethylene glycol and 2-ethoxyethanol, carboxamides such as N, N-dimethylacetamide, N-methylacetamide and N, N-dimethylformamide, sulphoxides such as dimethyl sulphoxide, and sulphones such as sulfolane . Instead of the pure substances, residues containing these substances can also be used. Suitable solvents 1 are, for example, residues from the oxo synthesis.

The residue R in the bottom space of the separating column K is diluted with an undesired increase in viscosity with preferably at least 20% by volume, particularly preferably at least 30% by volume, very particularly preferably at least 40% by volume of the solvent 1, based in each case on the total volume of the residue R in the bottom space of the separating column K.

The viscosity of the residue R in the bottom space of the separating column K at a temperature of 100 ° C. is preferably less than 12 Pa s, particularly preferably less than 10 Pa s, very particularly preferably less than 8 Pa s.

The discharged residue R can be diluted with a solvent 2. Suitable solvents 2 are, for example, alcohols, carboxamides, sulfoxides and sulfones. Instead of the pure substances, residues containing these substances can also be used. Suitable solvents 2 are, for example, residues from the production of methanol.

Liquids F containing Michael adducts, which were formed during the production of acrylic acid, are obtained, for example, in processes for the production of acrylic acid in which a product gas mixture containing acrylic acid is obtained by catalytic gas phase partial oxidation of a C3 precursor compound of acrylic acid, optionally after previous cooling, ascending in itself with side withdrawal of a crude acrylic acid in a Separating column provided with seed internals is fractionally condensed, and the Michael adducts of the acrylic acid-containing liquid formed in the process are continuously removed from the bottom of the condensation column and fed as liquid F to the cleavage of the Michael adducts of the acrylic acid contained therein (cf., for example, WO 2004 / 035514).

Of course, liquids F can also result if the acrylic acid contained in the product gas mixture of the heterogeneously catalyzed gas phase partial oxidation is converted into the liquid phase by absorption in an absorbent and the acrylic acid is subsequently separated from the absorbate by means of rectificative and / or crystallisative separation processes, as described in DE 103 36 386 A and DE 29 01 783 A disclose.

As a rule, liquids F, based on their weight, contain at least 10 ppm by weight, frequently at least 50 ppm by weight and in many cases at least 150 ppm by weight of polymerization inhibitor. As a rule, the content of polymerization inhibitors in liquids F, based on the same principle, is not more than 1% by weight or not more than 0.5% by weight. In addition to phenothiazine (PTZ) and / or hydroquinone monomethyl ether (MEHQ) and their subsequent products, such polymerization inhibitors also include compounds such as alkylphenols (e.g. o-, m- or p-cresol (methylphenol)), hydroxyphenols (e.g. hydroquinone), tocopherols (e.g. o-tocopherol) and N-oxyls (for example hydroxy -2,2,6,6-tetramethyl-piperidi-N-oxyl) and the other polymerization inhibitors known in the literature can be considered.

The components of liquids F, which differ from acrylic acid and the Michael adducts, are primarily compounds that boil higher than acrylic acid at normal pressure.

In principle, all types of rectification columns known per se can be used as the separating column K.

These are all columns containing separating internals, such as packing, random packing and / or trays being considered as separating internals. The purpose of the separating internals is to enlarge the exchange area between the gas phase rising in the separating column K and the liquid running off in the separating column K, thereby improving both the mass and heat exchange between the two phases. They are permeable to both the gas rising in the separating column K and the liquid flowing out in the separating column K. The separating column K preferably contains only trays and / or packings. Dual-flow trays are advantageously used as trays, and it is particularly advantageous that the separating column K contains only dual-flow trays as internals that are effective for separation.

In this document, dual-flow trays are understood to mean plates with simple passages (holes, slots, etc.). The gas rising in the separating column K and the liquid falling in the separating column K flow in opposite directions through the same passage. The cross section of the passage points is adapted to the loading of the separating column K in a manner known per se. If it is too small, the ascending cracked gas flows through the passages at such a high speed that the liquid descending in the separating column K is entrained with essentially no separating effect. If the cross-section of the passage points is too large, the rising cracked gas and the falling liquid move essentially past each other without exchanging and the soil runs the risk of running dry. Usually dual-flow floors do not have a drain pipe that connects them to the next floor. Of course, each dual-flow tray can be flush with the walls of the rectification column. However, it can also be connected to these via webs. As the load on the rectification column decreases, dual-flow trays run dry, in contrast to hydraulically sealed cross-flow trays.

The feed point I, at which the liquid F is fed into the separating column K, is located above the lowest separating internals in the separating column K. In the case of a tray column, the feed point I is thus above the lowest tray.

If the separating column K is a column with pure packing, the feed point I is above the lowermost packing.

A separating column K containing pure dual-flow trays can contain up to 60 dual-flow trays or more. These advantageously have an opening ratio (the ratio D: U, formed from the area of the soil that is permeable to the cracked gas (D) and the total area of the soil (U) of 10 to 20%, preferably 10 to 15% on.

In the case of a pure dual-flow tray column (for example with at most 40 equidistant) dual-flow trays, feed point I is advantageously located in the region of the fourth to tenth dual-flow tray, viewed from bottom to top. Appropriately from an application point of view, the feed temperature of the liquid F at the feed point I corresponds to that temperature which the liquid descending in the separating column K has at this point. Advantageously, the temperatures mentioned above do not deviate by more than 10% (based on their arithmetic Mean) from each other. Appropriately from an application point of view, the separating column K, like its feed and discharge lines, is thermally insulated from the environment.

As a rule, separating columns K with 2 to 25 theoretical plates are sufficient. The theoretical plate (or theoretical separation stage) should be understood to mean that spatial unit of the separation space of the separation column K containing internals and which brings about an enrichment of substances in accordance with the thermodynamic equilibrium without loss of energy.

The feed point I of the separating column K is preferably located in the region of the second to eighth theoretical tray, viewed from bottom to top.

The reflux liquid for the separating column K can be generated by direct and / or indirect cooling of the gas stream G flowing into the headspace of the separating column K. According to the invention, the method of direct cooling is advantageously used.

For this purpose, the gas stream G flowing through the uppermost separating internals of the Trennko lonne K in the headspace above is fed to a quenching device in the simplest manner, which z. B. can be integrated into the head space (in this case the head space is separated from the separating space e.g. by a chimney tray; the sump space and head space do not contain any separating internals).

In principle, however, the quenching device can also be spatially separated from the separating column K. As such a quenching device, all devices known in the prior art for this purpose (e.g. spray scrubbers, venturi scrubbers, bubble columns or other apparatus with sprinkled surfaces) can be used, with Ven turi scrubbers or spray coolers preferably being used. A direct current device (e.g. one with a baffle plate nozzle) is advantageously used. For indirect cooling of the quench liquid, it is usually passed through an (indirect) heat exchanger or heat exchanger. In this regard, all common heat exchangers or heat exchangers are suitable. Tube bundle heat exchangers, plate heat exchangers and air coolers are preferred. Suitable cooling media are air for the corresponding air cooler and cooling liquids, in particular special water (e.g. surface water), for the other cooling devices. Appropriately for application purposes, a portion of the condensate formed during quenching is used as the quenching liquid. The other portion of the condensate formed during quenching is normally returned essentially as reflux liquid to the uppermost separating internals in the separating column K (if necessary, part of the condensate can also be used be left out). Of course, the condensation can also be carried out exclusively with indirect heat exchangers integrated into the headspace and / or relocated from the headspace, in that the gas flow G is passed through them.

From an application point of view, the separating column K is operated with polymerization inhibition.

Such polymerization inhibitors can in principle be used for this purpose all of the polymerization inhibitors known in the prior art for acrylic monomers. Examples include phenothiazine (PTZ) and hydroquinone monomethyl ether (MEHQ).

Often these two are used in combination. Appropriately, they are added to the reflux liquid dissolved in pure cleavage product. MEHQ is preferably metered in as a melt.

In principle, all types of evaporators known per se can be used as the evaporator V.

For this purpose, residue R removed as substream I in the bottom space of separating column K is heated in the simplest manner by means of an indirect circulation heat exchanger and the thus heated residue R is returned as substream II via feed point II into the separating column. The residue R is conveyed by means of a pump P through the indirect circulation heat exchanger (forced circulation heat exchanger).

In the case of an indirect circulation heat exchanger, the heat transfer does not take place in the direct contact between the fluid heat transfer medium and the liquid mixture to be heated, which is forced by mixing. Rather, the heat is transferred indirectly between the fluids separated by a partition. The interface of the heat exchanger (heat exchanger) that is active for heat transport is referred to as the heat exchange or transfer surface, and the heat transport follows the well-known laws of heat transfer.

The indirect circulation heat exchanger is flowed through by both the fluid heat transfer medium and the back R stand. That is, both flow into the heat exchanger and then out again (one flows through the at least one primary space and the other flows through the at least one secondary space).

In principle, all possible hot gases, vapors and liquids can be used as fluid heat transfer media for the method according to the invention. First and foremost, this includes water vapor, which can be at different pressures and temperatures. It is often beneficial if the water vapor condenses as it flows through the indirect heat exchanger (saturated steam).

Indirect circulation heat exchangers suitable for the process are in particular double-tube, tube bundle, finned tube, spiral or plate heat exchangers. Double-pipe heat exchangers consist of two pipes one inside the other.

Several of these double pipes can be connected to form pipe walls. The inner tube can be smooth or provided with ribs to improve the heat transfer. In individual cases, a tube bundle can also represent the inner tube. The fluids exchanging heat can move in cocurrent or in countercurrent. According to the invention, the liquid F is expediently conveyed upwards in the inner tube and hot water vapor flows downwards in the annular space, for example.

Tube bundle heat exchangers are particularly suitable for the process according to the invention. They usually consist of a closed, wide jacket tube which encloses the numerous smooth or ribbed transfer tubes of small diameter attached to the tube bases.

The feed point II (this means the point in the bottom space of the separating column K at which the substream II exits the feed line into the bottom space) is located below the lowest separating internals of the separating column K and above the level S of the bottom liquid (which enters the bottom space the liquid running off the separating column K). In accordance with the invention, the level S of the (the sump liquid) running into the sump space is advantageously set so that it is less than 40%, preferably less than 30% and particularly preferably less than 20% of the distance A. As a rule, however, the level S will not be less than 5% of the distance A (safety fluid level).

According to the invention, this safety height is advantageously implemented with a low sump liquid volume by attaching displacement bodies in the sump space or pulling in the sump space towards its lower end (cf. FIG. 6 of DE 103 32 758 A or also EP 1 095 685 A and FIG. 1 DE 102004 015727 A).

With particular advantage, the sump space is drawn in towards its lower end and the level S of the liquid draining into the sump space (the level of the sump liquid) is det is in the section of the sump space in which the sump space is drawn in (ie, in the section in which it has a reduced inner diameter).

As a rule, the feed point II is at least 0.25 x A above the level S of the sump liquid (above the liquid level (level) of the sump liquid).

The return of substream II into the bottom space of the separating column K takes place in such a way that the substream II in the bottom space of the separating column K is not directed towards the bottom liquid (that is, the extension of the flow vector of that flow with which the substream II from the corresponding feed line into the bottom space escapes, does not hit the sump liquid, but hits a material object different from the sump liquid (e.g. the wall of the sump space, a baffle plate, etc.).

The aforementioned condition according to the invention can be achieved in a simple manner in that the partial flow II flows horizontally into the sump space (e.g. via a simple inlet connection).

The inflow of substream II into the sump space of the separating column K advantageously takes place, however, from a line A which is led into the sump space and whose outlet opening in the sump space points downwards, but not directed towards the sump liquid, but towards an impact device A (directed towards a flow distributor ), which (which) is attached in the sump space above the level S of the sump liquid, and which deflects the partial flow II upwards when it hits the impact device (see, for example, FIG. 1 of DE 102004015727 A).

Often the forced circulation heat exchanger is also designed as a forced circulation relaxation heat exchanger, preferably a forced circulation tube bundle relaxation heat exchanger. In contrast to the case of a purely forced circulation heat exchanger, this is normally separated from the feed point II in the separating column K by a throttle device (e.g. in the simplest case by a perforated diaphragm (or other diaphragm); alternatively, a valve can also be considered).

As a result of the above measure, boiling of the at least one partial stream I pumped around is suppressed within the at least one secondary space of the heat exchanger (heat exchanger), for example in the tubes of the tube bundle heat exchanger. The at least one partial flow I pumped around is rather overheated within the at least one secondary chamber with respect to the gas pressure GD prevailing in the bottom chamber of the separating column K and the boiling process is thus completely shifted to the passage side of the throttle device (ie, the content of the tubes of the tube bundle heat exchanger is single-phase, the tube bundle heat exchanger only acts as a superheater). The throttle device separates the heat exchanger (heat exchanger; e.g. tube bundle heat exchanger) and the supply point II on the pressure side and, by suitably selecting the output of the pump according to the invention, enables the setting of a throttle inlet pressure above the gas pressure GD prevailing in the sump space, which is above the gas pressure GD prevailing in the sump space, which is above the boiling pressure associated with the temperature of the partial flow II flowing out of the at least one secondary space of the heat exchanger. Boiling evaporation takes place in the flow device only after the throttle. The use of forced circulation expansion heat exchangers is preferred.

The difference between the throttle inlet pressure and the gas pressure GD present in the sump space is typically 0.1 to 5 bar, frequently 0.2 to 4 bar and often 1 to 3 bar.

In principle, the evaporator V can also be a thin-film evaporator integrated into the separating column K. The thin-film evaporator is located between the separation space and the bottom space of the separating column K. In the bottom space of the separation column K, residue R withdrawn as a substream is conveyed back into the thin-film evaporator by means of a pump P.

If "stripping gas" is also used as entrainer (entrainer gas or support gas) for the cleavage products (cleavage products) in the separating column K, then in the process according to the invention this is also above the level S of the bottom liquid and below the lowest separating internals of the separating column K in the bottom space the separating column K (and flows from there into the head space of the separating column K). The latter in turn in such a way that the gas stream in the bottom space of the separating column K is not directed towards the bottom liquid (i.e. the extension of the flow reactor with which the gas stream exits from the corresponding feed line into the bottom space does not hit the bottom liquid).

This can be achieved in a simple manner in that the stripping gas stream flows horizontally into the sump space (e.g. via a simple inlet connection).

Advantageously, the inflow of a stripping gas stream into the sump space of the separating column K takes place from a line B which leads into the sump space and whose outlet opening in the sump space points downwards, but is not directed towards the sump liquid but towards a Prallvor direction B (directed towards a flow distributor) , which (which) is attached in the sump space above half the level S of the sump liquid, and which the stripping gas flow at his The impact on the impact device deflects in an upward direction (see, for example, FIG. 1 of DE 102004 015 727 A).

For reasons of polymerization inhibition, the stripping gas preferably contains molecular oxygen. As such, z. B. air, oxygen-depleted air and / or cycle gas into consideration. Cycle gas is understood to mean the residual gas that remains when the acrylic acid is absorbed from the product gas mixture of the heterogeneously catalyzed gas phase partial oxidation of a C3 precursor compound (e.g. propene, propane, acrolein, glycerine) used for the production of acrylic acid a liquid absorbent or converted into the liquid state of aggregation by fractional condensation (cf., for example, WO 2004/035514). Most of this residual gas is recycled to the partial oxidation in order to dilute the reaction gas mixture.

As a rule, an aqueous phase is condensed out of the aforementioned residual gas prior to its use as stripping gas, which usually contains residual amounts of acrylic acid (Sauewater), which are separated from this aqueous phase by extraction with an organic extractant into the resulting extract can. Before using the residual gas as stripping gas in the process according to the invention, the residual gas can also have been used to strip the acrylic acid from the aforementioned extract (cf. DE 102007 004 960 A). The stripping gas is normally fed in at a temperature which is below the temperature of the sump liquid and above 100.degree. C., in some cases above 150.degree.

Based on 1 kg of liquid F fed in at feed point I per hour, the fed stripping gas stream can be, for example, 1 to 100 kg / h. Stripping gas is used especially when the evaporator V is a forced circulation expansion heat exchanger.

By metering in stripping gas, the partial pressure of the (re) cleavage products in the separating column K can be reduced in a corresponding manner, as by the application (application) of reduced pressure (negative pressure).

If no stripping gas is fed to the separation column K, a working pressure is applied at the top of the column which is advantageously below 1 bar (and is e.g. 100 mbar).

If a stripping gas is also used, the working pressure at the top of the separation column K is generally from 1 to 3 bar, preferably from 1.5 to 2.5 bar. The temperature of the sump liquid located in the sump space with level S is generally in the range from 140 to 220.degree. C., frequently 150 to 200.degree. C. and in many cases 155 to 180.degree.

A partial flow of the residue R is discharged as a residual flow and passed to its disposal, e.g. its incineration.

The gas stream remaining and omitted in the process according to the invention during the partial condensation of the gas stream G, as well as a partial amount of the condensate formed, which may not be used as reflux liquid, can be reused in the same way as in the prior art (e.g. DE 103 32 758 A, WO 2004/035514, WO 2008/090190, WO 2008/077767, EP 0 780 360 A, DE 197 01 737 A and EP 1 357 105 A) has already been described.

Of course, dispersants (e.g. surfactants) and / or defoamers can be added to the bottom liquid of the separating column K, as recommended e.g. in DE 10 2008 001 435 A. They can also be added at the top of the separating column K.

The present invention also relates to the dilute residue obtainable by the process according to the invention.

Examples

For Examples 1 and 2, a residue R prepared in accordance with the example of WO 2010/066601 in the separating column K was used.

example 1

In a 1 l round bottom flask, 500 g of residue R were heated to 170 ° C. and stirred. After 6 hours, the mixture was diluted with 500 g of ethylene glycol and cooled with stirring.

Samples were taken during the experiment and the viscosity measured at 100 ° C. Tab. 1 Dilution with ethylene glycol

Example 2

In a 1 l round bottom flask, 500 g of residue R were heated to 170 ° C. and stirred. After 6 hours, the mixture was diluted with 500 g of propylene glycol and cooled with stirring.

Samples were taken during the experiment and the viscosity measured at 100 ° C.

Tab. 2 Dilution with propylene glycol

Example 3

The product gas mixture of a two-stage heterogeneously catalyzed partial gas phase oxidation of propylene (chemical grade) to acrylic acid, which was carried out as described in the exemplary embodiment of WO 2008/090190, was subjected to fractional condensation as in the exemplary embodiment of WO 2008/090190 in order to to separate the acrylic acid contained in the product gas mixture of the partial oxidation from the same.

As described in the exemplary embodiment of WO 2008/090190, high boiler liquid was removed from the bottom region of the condensation column and fed to a splitting device as in the exemplary embodiment of WO 2010/066601. The temperature in the bottom space of the separating column K was 168 ° C. The amount of residue R in the bottom space of the separating column K was about 25 m ³ . After 4 days the viscosity rose from liquid to very viscous at 120 ° C. The supply of high boiler liquid and stripping gas to the separating column K are stopped. The reflux to the separating column K is also stopped. The residue R in the bottom space of the separating column K is then ^{diluted with about 20 m 3 of} ethylene glycol. The diluted residue R is discharged and incinerated.

Claims

Expectations

1. Process for the cleavage of Michael adducts contained in a liquid F of

Acrylic acid, which were formed in the production of acrylic acid, the liquid speed F containing at least 10 wt .-% Michael adducts of acrylic acid, based on the liquid F, in a splitting device, the at least one separating column K, from bottom to top consists of a sump space, an adjoining the sump space, separating internals containing separating space and an adjoining head space and in which the pressure in the gas phase decreases from bottom to top, comprises an evaporator V and a pump P, in which Michael adducts containing liquid F are split at a temperature of 130 to 240 ° C and removed by distillation and the remaining residue R is discharged, characterized in that in the event of an undesired increase in the viscosity of the residue R in the bottom space of the separating column K, the feed the liquid F is interrupted in the splitting device, the residue R in the bottom space of the separating column K m it is at least 10% by volume of a solvent 1, based on the total volume of the residue R in the bottom space of the separating column K, diluted and cooled, and the bottom space of the separating column K is emptied, the solvent 1 having a boiling point of 1,013 hPa of at least 150 ° C and a solubility in water at 25 ° C of at least 10 g per 100 g of water.

2. The method according to claim 1, characterized in that the liquid F at least

Contains 40% by weight of Michael adducts of acrylic acid, based on the liquid F.

3. The method according to claim 1 or 2, characterized in that the Michael adducts contained in the liquid F split at a temperature of 155 to 180 ° C who the.

4. The method according to any one of claims 1 to 3, characterized in that the solvent 1 has a boiling point of at least 210 ° C at 1,013 hPa.

5. The method according to any one of claims 1 to 4, characterized in that the Lö solvent 1 has a solubility in water at 25 ° C of at least 40 g per 100 g of water.

6. The method according to any one of claims 1 to 5, characterized in that the solvent 1 is an alcohol, a carboxamide, a sulfoxide and / or a sulfone.

7. The method according to any one of claims 1 to 5, characterized in that the solvent 1 is selected from ethylene glycol, propylene glycol, diethylene glycol, triethylene glycol, 2-ethoxyethanol, sulfolane, N, N-dimethylacetamide, N-methylacetamide, dimethyl sulfoxide and / or N, N-dimethylformamide.

8. The method according to any one of claims 1 to 5, characterized in that the Lö solvent 1 is a residue of the oxo synthesis.

9. The method according to any one of claims 1 to 8, characterized in that the residue R in the bottom space of the separating column K with at least 40 vol .-% solvent 1, based on the total volume of the residue R in the bottom space of the separating column K, is diluted.

10. The method according to any one of claims 1 to 9, characterized in that the viscosity of the residue R in the bottom space of the separating column K at a temperature of 100 ° C is less than 12 Pa s.

11. The method according to any one of claims 1 to 10, characterized in that a stripping gas above the bottom liquid and below the lowermost separating internals of the separating column K is fed into the cleavage device.

12. The method according to claim 11, characterized in that in the event of an undesired increase in the viscosity of the residue R in the bottom space of the separating column K, the supply of stripping gas to the cleavage device is interrupted.

13. The method according to any one of claims 1 to 12, characterized in that the discharged residue R is diluted with a 2 solvent.

14. The method according to claim 13, characterized in that the solvent 2 is a residue of the methanol production.

15. Dilute residue R, obtainable by a process of claims 1 to 14.