DE1812721B - Process for the production of methyl ethyl ketone - Google Patents

Description

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The invention relates to a method for manufacturing products. With the expression "Rmim-time-yield" of methyl ethyl ketone by reaction of butene- (l), the yield per hour unit and per volume, if necessary in a mixture with ßuten- (2) in the liquid unit of the reaction space (or the reaction phase with an aqueous catalyst solution, which understood a volume).

Palladium compound and a chlorine compound are composed of 5 It is known in the art that mono-

holds. olefins are converted into carbonyl compounds,

The process enables the large-scale production of the reaction in the presence of palladium of methyl ethyl ketone in high space-time chloride, copper (TI) chloride and water according to the following Yield with reduced formation of secondary reaction equation is carried out:

PdCL ₂
R - CH = CH ₂ + 2CuCl ₂ + H ₂ O> - RCOCH ₃ + 2CuCl + 2HCl

wherein R is a hydrogen atom or an alkyl group catalyst solution becomes remarkably small,

means. if desired, methyl ethyl ketone in one

To obtain the process according to the above-mentioned high space-time yield and the reaction carried out is often referred to as the Hoechst-Wacker process, on the other hand the space-time yield is remarkable and is first applied low when it is desired is, a high methyl chemistry ", Vol. 71, pp. 176 to 182 (1959), described; to achieve the ability to form ethyl ketone,
subsequently, a number of literatures - these disadvantages posed serious limitations and patents - dealt with this process. 20 when carrying out the large-scale production The process is used for the large-scale production of methyl ethyl ketone from η-butene.
of acetaldehyde as ethylene or acetone from There is therefore an urgent propylene applied in the art. Need for the production of methyl ethyl ketone from

However, the use of this process has increased the space yield per unit of time to higher olefins with four or more carbon atoms at least equal to or greater than that of the manufacture atoms, for example η-butene for the preparation of acetaldehyde or acetone, and the solution Methyl ethyl ketone, on an industrial scale so far, these problems can be considered fundamentally not satisfactory due to the following additional keys for achieving large-scale deficiencies achieved: see production of methyl ethyl ketone with low

Consider costs in the Hoechst-Wacker process using application 30. So far it has not been effective

of catalysts from palladium chloride-copper (II) - process despite extensive and extensive

chloride-type takes the space efficiency in the time-investigations known.

unit for the carbonyl compounds formed rapidly There was now a process for the production of from when the carbon number of the starting methyl ethyl ketone by reaction of butene (I), material used olefin increases. In detail, 35 is optionally mixed with butene- (2) in liquid in the "Proceeding of the Sixth Petroleum Congress, phase with an aqueous catalyst solution, which a Section IV", Paper 40, p. 4, stated that the palladium compound and a Chlorine compound ent space yield in the unit of time for acetone, found, which is characterized in that it assumes a value of 130 (g / l · h) when it is converted into the reaction with a catalyst solution of propylene with an aqueous solution of 40 carries out, which also contains iron (ITI) sulfate, Pal) adium chloride-copper (II) chloride at a temperature where the chlorine content per liter of catalyst solution temperature of 90 to 100 ⁰ C under a pressure of 0.005 to 0.15 g-atom and the chemical 9 to 12 atm is transposed, while that of equivalent in the ratio of chlorine to palladium in methyl ethyl ketone only has a value of 30 (g / l hour) of the catalyst solution between 1.5: 1 and 20: 1 is assumed if it is you rch conversion of η-butene with 45 As can be seen from the figure, the space-time of the same catalyst solution is produced with the same yield with methyl ethyl ketone at the maximum more reaction conditions. The value of times greater if the chlorine content is 0.005 to 0.15 g-30 g / l · hour for the space yield per unit of time at atom per liter, preferably 0.01 to 0.1 g atom per liter, methyl ethyl ketone only represents the tenth part of the value, as applied in the process according to the invention in the preparation of acetaldehyde from 50, compared to the case when there is no chlorine in the ethylene. The very low space yield is contained in the aqueous catalyst solution. In addition, the time unit for methyl ethyl ketone compared to the space-time yield of methyl ethyl acetaldehyde and acetone means that only a very ketone amount of methyl ethyl ketone from η-butene higher than the value of 30 g by the process of the invention is about 20 times lower / l · hour, as it is obtainable if normal reaction vessels and the Hoechst-Wacker process are used in accordance with the usual reaction times. Therefore the “Sixth Petroleum Congress” report is the procedure for industrial and large-scale technology.

niche working methods not suitable. On the other hand, the space-time yield in a known process for the preparation of methyl ethyl ketone with chlorine contents of up to 0.005 g methyl ethyl ketone by reacting n-butene falls below 60 atoms per liter and more than 0.15 g atom per liter Use a PdCl ₂ -CuCl ₂ containing rapidly. The space-time yield is maintained in the case of a methyl-aqueous catalyst solution, and it has been established that ethyl ketone reached its peak point within a range of 1.5 to 20 chemical equivalents of chlorine, which frequently interrupts the operating compared to palladium in the aqueous catalyst regime. This way of working was therefore the solution. If the ratio is less than 1.5 for large-scale implementation, the space-time yield of methyl ethyl ketone is unsuitable. In addition, it was found that the time unit rapidly and concurrently with the Aus-MethyläthylketonbildungsfäbJgkeit per liter of the precipitation of metallic palladium during the

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Implementation from, and the regeneration of the consumable chlorine compound can be delivered. On the other hand brewed Catalyst solution with an oxygen-containing clien only supplementary amounts of chlorine with respect to the Gas such as oxygen and air becomes difficult. total amount required by the chlorine-if on the other hand, the chemical equivalence ratio can be provided if chlorine-containing palladium is supplied by Chlorine to palladium in the catalyst solution, the 5 compounds, such as palladium chloride, are used who value Exceeds 20, the space-time yield decreases.

of methyl ethyl ketone also abruptly, and number in the preparation of the catalyst solution or

rich unwanted by-products such as B. 3-chlorine during the reaction can sometimes be an

butanone- (2), n-butyraldehyde and the like can be formed due to precipitation of iron (M) hydroxide

will. io hydrolysis of iron (III) sulfate occur. To the

It is therefore a surprising finding that the formation of iron (ill) hydroxide should be avoided

An aqueous catalyst solution that suffers from chlorine is the catalyst solution during production

bond, a palladium compound and iron (IT) - or to make acidic during the reaction,

sulfate of the specific addition given above in that a mineral acid, such as sulfuric acid, in one

sarametisetzung contains a remarkable cataly- 15 amount of 0.5 to 100 g / l to the catalyst solution

table activity for the conversion of butene into is added.

Shows methyl ethyl ketone. The aqueous catalyst solution can usually

According to the invention, as starting material in an amount of 0.1 to 201, preferably 0.2 to 101,

material 1-butene, optionally mixed with per mole of butene. If the crowd

cis-2-butene or trans-2-butene can be used. 20 is less than 0.11, the product yield will be low

If the starting material also contains isobutene, ger. As a lot more than 201 none in the

If the product contains tert-butanol except for the main practice, it gives somehow compensating advantage

product methyl ethyl ketOTi. This is due to the fact they are not economical.

due to the fact that the isobutene in the starting material The reaction can take place at ordinary temperature with formation of tert-butanol by the 25 and atmospheric pressure. The action of the iron (III) sulfate salt in the aqueous reaction is preferred, but is selectively hydrogenated at elevated temperature and with catalyst solution. If the overpressure is used to increase the degree of conversion, starting material alkadienes, for example butadiene, are carried out. Thus, the reaction may in practice methylallene and / or alkynes, for example at temperatures between room temperature and dimethylacetylene, diacetylene, ethylacetylene, vinyl is 30 200 ° C, preferably 70 to 120 ⁰ C and under an acetylene, methyl acetylene, acetylene, It is favorable to have sufficient pressure to at least the aqueous previously to keep these impurities in the liquid state by using a metal catalyst of the platinum group in the usually from atmospheric pressure up to 50 atm, to remove the nature of hydrogen, thus preferably 5 to 40 atm. If the implementation is disrupted, this is prevented. These temperatures above 200 ° C can be used in industry in more favorable analysis with precipitation of iron (IIl) hydroxide as the BB fraction of the ethylene factories, BB- follow, so that the space-time- Yield of methyl fraction from catalytic mineral oil hot bed cracking ethyl ketone can be lower. It is advantageous to use as the return BB fraction of butadiene extraction measures that ensure an intimate manufacturing process and, as the BB fraction of plants for stirring between the two phases, ensure catalytic dehydrogenation of η-butane to or from their Increase miscibility. A heartfelt providence. agitation is achieved through mechanical working methods, such as

As chlorine compounds can be used in the context of stirring, shaking, spraying or application of

Invention all used by the water oscillations or by chemical operations that

are soluble; inorganic chlorine compounds will favor the formation of large surfaces,

preferred. For example, hydrogen chloride is obtained. To increase the miscibility, z. B.

Hydrochloric acid and metal chlorides, such as iron (fll) chloride, inert Aktiyatoren for the solution, for example

Copper (II) chloride, cobalt chloride, nickel chloride, methanol, ethanol, ethylene glycol, polyethylene glycol,

Chromium chloride, potassium chloride, sodium chloride, calcium dioxane, dimethylformamide, acetic acid or propionic

cium chloride, barium chloride, strontium chloride, acidic 50 are added. The implementation can

turns. Furthermore, organic chlorine, for example, in countercurrent, cocurrent or

compounds such as monochloroacetic acid, dichloroacetic acid by blowing butene into the stream of aqueous

acidic and acetyl chloride can be used. Catalyst solution take place.

As a palladium compound can also be used in the context of the implementation both in individual inventions all water-soluble ones are used in batch, semi-continuous or continuous form; suitable are e.g. B. palladium sulfate, palladium are performed.

nitrate, palladium chloride, palladium potassium chloride, Pal- To obtain the methyl ethyl ketone formed ladium acetate. Of these are inorganic palladium- the reaction mixture is a distillation or salts which are subjected to steam stripping in water as well as in aqueous solutions, so that a counter are easily soluble in mineral acids, for example a mixture of methyl ethyl ketone and water wise palladium sulfate, palladium nitrate, palladium will. The unreacted butene can be recovered chloride, Palladium potassium chloride, to be preferred. and repeatedly back into the reaction zone.

The iron (III) sulfate can either be carried out in the form of. The used catalyst solution

anhydrous salt or the hydrated salt can be returned to the reaction zone,

be turned. 65 after going through a certain concentration

If the palladium compound does not contain any chlorine, add additional water and, after

such as B. palladium sulfate or palladium nitrate, must ration by conventional catalyst regeneration

the entire required amount of chlorine from driving, e.g. using oxidation

of oxygen or oxygen-containing gases such as air.

Various conventional methods for separating off anhydrous methyl ethyl ketone can be used applied to the mixture. For example, the mixture with known dehydrating agents, treated like anhydrous sodium sulfate or rock salt. The mixture can also be mixed with usual Substances that can modify the relative volatility of methyl ethyl ketone and water, for example Cyclohexane, η-hexane, methylcyclopentane are mixed and then to remove the Water.

Since the aqueous catalyst solution according to the invention is somewhat corrosive, those are parts of the device that are in contact with the catalyst solution, preferably made of corrosion-resistant Materials such as titanium, tantalum, synthetic rubbers, resins, enamel, glass, porcelain, ceramics manufactured.

On the basis of the above details, the invention enables large-scale production of methyl ethyl ketone at low cost due to the following advantages:

(a) The space-time yield of methyl ethyl ketone is very large. Therefore, the volume of the Reaction vessel can be brought to a small size. Furthermore, the response period can be shortened and the amount of the expensive catalyst solution can be kept to a minimum will.

(b) The amount of by-products is very low. According to the invention, the amount of byproducts such as 3-Chlorbutanon- (2), n-butyraldehyde u. Like. ₀ about ¹ Zi that amount which is formed in a conventional high-Wacker process. There is therefore no need for a complicated operation to clean the products.

(c) The used aqueous catalyst solution can be processed by the extremely economical Luftoxydationsverfabren regenerate easily, and it is not an expensive regeneration treatment, for example an electrolytic oxidation process is necessary.

The methyl ethyl ketone obtained has numerous ⁰ uses in many fields, for example as solvents for Anstrichs- or coating materials, solvents for dewaxing of petroleum fractions and as a starting material for the production of medicines and chemical products.

The following examples are provided for further explanation the invention.

example 1

_{40 ml of an aqueous catalyst solution containing 1 g of PdSO 4} · 2H ₂ O and 280 g of Fe ₂ (SOi) ₃ · 9H ₂ O, 1 aqueous solution and 5 g / l of aqueous solution, were placed in a 50 ml glass reaction vessel equipped with a magnetic stirrer Solution of 12 η-hydrochloric acid (corresponding to a chlorine content of 0.05 g atom / 1 in Experiment No. 4 in Table I below) as a chlorine compound. 3.1 g of liquid 1-butene were fed into the reaction vessel and nitrogen gas was then introduced up to 6 atmospheres. The resulting mixture was stirred at 105 ⁰ C under 15 atm heated for 2 minutes, at a speed of 2,000 rev./min. was stirred. The reacted mixture in the reaction vessel was then transferred to a customary distillation column and distilled, the unreacted butene, then a mixture of methyl ethyl ketone and water being distilled off at the top and the used aqueous catalyst solution being obtained as the bottom fraction. The mixture of methyl ethyl ketone and water was dehydrated with anhydrous sodium sulfate and crude methyl ethyl ketone was obtained. According to gas chromatographic analyzes, the crude product contained only a small amount of 3-chlorobutanone- (2) and n-butyraldehyde as by-products.
The same tests as the above were carried out with eight catalyst solutions, each of which differed in terms of the chlorine content and the chemical equivalent ratio of chlorine to palladium, and which were each modified by changing the amount of 12η-hydrochloric acid added according to the chlorine content, as shown in Table I below specified, had been produced. The results of these tests are shown in Table I.

Table I.

composition
the catalyst solution Chemical Space-time yield Olefin Methyl ethyl
ketone Yield*) n-butyraldehyde attempt
"Wr equivalent to
ratio of methyl ethyl ketone conversion (Mole percent) (Mole percent) ΓΊΙ. Chlorine content Cl / Pd 100 3-chlorine
butanone- (2) 0 (g atom / 1) 0 (g / l-hr.) (7.) 99.98 (Mole percent) 0.02 1**) 0 2.38 123 4.1 99.88 0 0.03 2 0.02 4.77 355 11.9 99.80 0 0.04 3 0.04 5.96 494 16.5 99.74 0.09 0.04 4th 0.05 7.16 541 18.1 99.55 0.16 0.04 5 0.06 9.54 527 17.7 98.78 0.22 0.06 6th 0.08 14.9 352 11.8 97.42 0.41 0.13 7th 0.125 29.8 212 7.2 1.26 8th**) 0.25 88 3.0 2.45

*) = Yield based on converted 1-butene (selectivity). **) = comparison test.

The relationship between the chlorine content and the space yield of methyl ethyl ketone in unit time, which is shown in Table I, was shown as curve A in FIG. 1, the abscissa indicating the chlorine content (g atom per 1) in each 11 solution and the ordinate indicating the space-time yield (g / l · hour) of the methyl ethyl ketone obtained.

Example 2

The same procedure was used as in Example 1, except that iron (TTI) chloride was used Place of hydrochloric acid used. The results are summarized in the tables below.

Table II

composition Chemical
equivalent to
ratio Space-time yield Olefin Methyl ethyl
ketone Ausheiitf ** 1 n-butyraldehyde the catalyst solution Cl / Pd of methyl ethyl ketone conversion (Mole percent) AUt) UvUlC J (Mole percent) attempt
No. Chlorine content 1.67 (g / lh) (%) 100 3 chior
butanone- (2) 0 (g atom / 1) 6.56 238 7.9 99.85 (Mole percent) 0.04 9 0.014 16.7 669 22.4 99.07 0 0.07 10 0.055 33.4 200 6.7 97.65 0.10 0.14 11th 0.14 98 3.3 0.86 12 **) 0.28 2.21

*) = Yield based on converted 1-butene (selectivity).
**) - comparison test.

The relationship between the space-time yield and the chlorine content, as can be seen from Table II, is shown in FIG. 1 plotted as curve B.

Example3

The experiment was carried out in the same way as in Example 1, but copper (II) chloride used as a chlorine compound in place of hydrochloric acid. The results are given in Table III.

Table IH

composition
the catalyst solution Chemical Space-time yield Olefin Atf *.! 1 «ii 1 Yield*) n-butyraldehyde attempt
No equivalent to
ratio of methyl ethyl ketone conversion Methyl ethyl
ketone (Mole percent) Chlorine content Cl / Pd (Mole percent) 3-chlorine
butanone- (2) 0.03 (g atom / 1) 6.30 (g / lh) ( ⁰ A.) 99.41 (Mole percent) 0.04 13th 0.029 12.39 306 10.3 99.37 0.56 0.07 14th 0.057 19.53 604 13.6 99.05 0.59 15th 0.147 197 6.6 0.88

*) = Yield based on converted 1-butene (selectivity).

Example 4

The η-butene used as feed had the composition listed in Table IV:

Table IV

links salary
(Mol
percent) Mixture of 1-butene and 2-butene ...
Isobutene 60.6
23.2
16.2 η- and isobutane

In a cylindrical reaction vessel of 61 reaction volumes made of titanium with a height of 2 m, which was equipped with a stirrer and baffle plates, the butene with the composition shown in Table IV was continuously fed at a feed rate of 5.5 kg / hour. and an aqueous catalyst _{solution (containing Ig PdCl 2} , 300 g Fe ₂ (SO ₄ ) ^ H ₂ O and 7 g FeCl ₃ -OH ₂ O per liter of solution; the chlorine content was 0.089 g-atom per liter; the chemical equivalent ratio of Chlorine to palladium was 7.94) at a rate of 100 l / h at the bottom of the reaction vessel. The reaction was carried out at 110 ° C and at 30 atm in countercurrent, while at a speed of 700 rev / min. was stirred. The product formed was separated from the reaction mixture in a conventional manner. The conversion of butene was 85%. Methyl ethyl ketone was in an amount of 3501 g / hour. obtained, which corresponds to a space-time yield of 583.5 g / l · hour. In addition, tert-butanol was used in an amount of 1214 g / hour. obtained, 3-chlorobutanone- (2) and n-butyraldehyde were found, but the yield was only 18.5 g / hour. The yield (based on the converted butene) of methyl ethyl ketone was 96.1%, and the total yield of 3-chlorobutanone- (2) and n-butyraldehyde was 3.9%.

Example5

The same experiment as in Example 4 was carried out carried out, but 1001 / hour. a catalytic converter

109540/388

solution was used that contained 0.77 g of Pd (NOj) ₂ , 300 g of Fe ₂ (SO ₄ ) S - 9H ₂ O and 5 g of FeCl ₃ · 6H ₂ O (chlorine content: 0.0056 g-atom per liter, chemical Equivalent ratio of chlorine to palladium: 8.31. The conversion of butene was 82%. 3405 g / h of methyl ethyl ketone and 1182 g / h of tert-butanol were obtained. The space-time yield of methyl ethyl ketone was 567. 5 g / l · h. The formation of 3-chlorobutanone (2) and n-butyraldebyd was just as low as in Example 4. The yield of methyl ethyl ketone was 96.9%, and the overall yield of 3-chlorobutanone (2 ) and n-butyraldehyde was 3.1%.

Comparative example 1

The procedure was carried out in the same way as in Example 1, but using 40 ml of an aqueous catalyst solution containing 0.75 g of PdCl, 70 g of Fe ₂ (SOi) _{3 .9H 2} O and 200 g of FeCl _n . 6H ₂ O each Liter of aqueous solution (chlorine content: 2.31 g-atom per liter, chemical equivalent ratio of chlorine to palladium: 275). The space-time yield of methyl ethyl ketone was only 57 g / l · hour, and the weight ratio of the by-products to methyl ethyl ketone was 0.26.

From this comparative example it can be seen that the space-time yield of methyl ethyl ketone is noticeable drops when the chlorine content of the aqueous catalyst solution exceeds 0.2 g atom per liter and the chemical equivalent ratio of chlorine to palladium clearly exceeds 20. In addition, the formation of by-products occurred in amounts of 26 parts by weight per 100 parts of the Main product methyl ethyl ketone, as can be seen above.

Comparative example 2

The same procedure was carried out as in Example 1, but using 40 ml of an aqueous catalyst solution which contained 0.75 g of PdCl ₂ and 271 g of FeCl ₃ · 6H ₂ O per liter of aqueous solution (chlorine content: 3.13 g- Atom per liter, chemical equivalent ratio of chlorine to palladium: 372). The space-time yield of methyl ethyl ketone was only 40 g / l · hour, and the weight ratio of the by-products to methyl ethyl ketone was 0.42.

From the above results, it is confirmed that the space-time yield of methyl ethyl ketone shows a far greater reduction and the formation of the by-product increases far more than in the case of Comparative Example 1 when the chlorine content of the solution exceeds 0.2 g-atom per liter and the equivalent ratio from chlorine to palladium becomes significantly higher than 20 and if in the catalyst solution it does not contain iron (III) sulphate.

Claims (1)

Claim: Process for the preparation of methyl ethyl ketone by reaction of ButeD- (l), optionally im Mixture with butene- (2), in the liquid phase with an aqueous catalyst solution which is a palladium compound and contains a chlorine compound, characterized in that one the reaction is carried out with a catalyst solution that also contains iron (HI) sulfate, the chlorine content per liter of catalyst solution being 0.005 to 0.15 g atom and the chemical Equivalent ratio of chlorine to palladium in the catalyst solution between 1.5: 1 and 20: 1 Cherishes. 1 sheet of drawings