DE1076090B - Process for the reaction of gases in liquids - Google Patents

Description

Process for the reaction of gases in liquids The usual reaction of gases in liquids requires extensive scrubbing systems, dissolvers or trickle towers with associated liquid circulation pumps. Should the reaction product be used in a vacuum system run barometrically, the whole system must be built accordingly high. In addition, when working in a vacuum, the vapor pressure of the reactants or products is usually so considerable that a rewashing of the residual gas is not dispensed with brine-cooled liquids are required to reduce the vapor pressure of the former to be kept as low as possible.

Particular difficulties arise when implementing only one gas reasonably stable in the case of negative pressure, which in the absence of compression of the reaction partner reacts otherwise, with the reaction liquid at normal or overpressure is to be carried out.

Proposals have already been made to use gases without the use of scrubbers to react. So is z. B. in German Patent 832 440 the Dimerization of ketene in a slide air pump described. That kind of pumps however, is because of the relatively small amount of circulated liquid and the limited surface of the liquid available for the reaction Not very suitable for gas reactions in the pump. In addition, it is with exothermic reactions extremely difficult to dissipate the entire heat of reaction only through the pump body. The dissipation of this heat is, however, absolutely necessary in order to increase the vapor pressure the pump liquid as low as possible in order to achieve a good suction performance to keep.

It is also known reactions and mixtures of gases or liquids Carry out in a circuit, using jet devices, rotating air pumps of the system Westinghouse-Leblanc or mixed gas liquid lifters (mammoth pumps) can be used. In contrast, the method differs through the use of a liquid ring pump advantageous in that it is much more efficient than jet devices and air pumping without a liquid ring is achieved.

It also includes gas extraction, reaction and liquid extraction carried out with a single unit, which previously required two and three units was.

In the German Auslegeschrift 1 039 996 there is also a procedure for removing clouds of mist from gas or gas mixtures using a liquid ring pump described. It is expressly pointed out that such liquids in the absence of which with the nebulizing gas or components of the same chemical reactions would take place.

In contrast, it was found that the reaction of gases in liquids practically quantitatively without any significant drop in the delivery rate leaves when the reaction is carried out in a liquid ring pump.

The reaction in the liquid ring pump can be carried out with substances whose reaction product has a sufficiently high boiling point, which ' This is a prerequisite for the desired suction capacity of the pump. Will the circulating fluid cooled by brine cooling below the temperature at which the vapor pressure the circulating fluid is equal to the gas pressure on the suction side of the pump, so can also reactions whose reaction product has a relatively low boiling point has to be carried out in the pump without the suction power being significantly reduced. If necessary, the reaction can be completed in the liquid circulation, which then has to be increased accordingly.

If the reaction medium is the reaction product itself, it will through an overflow is removed from the liquid circuit as it occurs.

An auxiliary liquid can also be used as the reaction medium, whose vapor pressure is lower than the gas pressure on the suction side of the pump and in which the reaction product is suspended in addition to the reactant, emulsified or solved.

Gases and liquids are suitable as reactants for the sucked in Gas. If the sucked in gas is to be made to react with a liquid, so the gas is sucked in on the suction side of the pump and into the circulating liquid, which the contains liquid reactants, introduced. Included becomes the liquid reactant of the circulating liquid in the reaction required amount added.

If the reaction partner for the sucked in gas is also a gas, the gas mixture on the suction side of the pump is used to carry out the reaction sucked in. However, a gas can also be its own reactant. In this Only one gas supply is required in the case.

The term "sucked gas" also includes heat or vacuum liquid compounds which have been converted into the vapor state, individually or in a mixture.

The reaction temperature in the liquid ring pump can be accordingly the existing vapor pressure of the circulating liquid containing the reactant, and fluctuate within wide limits according to the reaction taking place. She is through easy to determine a preliminary test.

The process offers very special advantages, if only with negative pressure stable gas should be subjected to a reaction with satisfactory Conversion and in a satisfactory yield only take place at atmospheric or overpressure goes. In this case, there is one in the liquid ring pump during compression Sufficient amount of the reactant available for the reaction, whereby another unwanted conversion of the gas does not even come into play. The same goes for, if a gas that is only stable at normal or negative pressure at overpressure in the liquid ring pump is processed.

The method can be used in a wide range of pressure ranges, start at about 10 torr on the suction side and at 10 atm on the pressure side. lie.

If the performance of a liquid ring pump is not sufficient, you can several pumps can be connected in series, which also results in reactions at higher Push yourself through.

With the method according to the invention, for example, the following Reactions are carried out: catalytic and non-catalytic oxidations by means of Oxygen or oxygen carriers in the liquid phase, catalytic and non-catalytic Hydrogenation using hydrogen, catalytic and non-catalytic polymerizations, catalytic and non-catalytic additions to multiple bonds, condensation reactions, Substitution reactions, absorption of gases in liquids with the formation of Follow-on products.

With the following device, which essentially only consists of a liquid ring pump, a cooler and a separator, can thus save a lot of space the same result can be achieved, as was previously mostly only possible in extensive, multi-storey washer systems was possible.

A liquid ring pump 2 is on the suction side through the gas line 1 connected to the gas source.

A line leads from the pressure side of the pump to the coil cooler 3, which absorbs the heat of compression and reaction. The snake cooler is connected to a separator 4, from which through line 8, optionally via a Throttle valve for setting a specific reaction pressure on the pressure side the pump, the exhaust gas discharged and the circulating fluid of the pump through line 5 is fed back. Any necessary for the reaction with the gas liquid reactants are added through line 7, the resulting reaction product is via line 6 from the Liquid circuit removed, if necessary via a Throttle valve. The separator 4 can in its dimensions and shapes according to the Requirements of the reaction to be carried out vary within wide limits. Under Under certain circumstances, the gas separation and storage of the circulating liquid can also can be carried out in separate containers, or several containers can be connected in series which may be provided with heating or cooling devices.

Example 1 With a liquid ring pump with a suction volume of 35 Torr is 78 ms / h of air, at a vacuum of 33 Torr it will be 3.39 NmaJh at 33 Torr 5310 gih ketene as 871l'iaiges cracked gas, that is about 3.27 NTm3lh, sucked in. The fluid circuit of the pump consists of 25187Q / acetic anhydride. The temperature of the pump is increased by cooling the acetic anhydride circulation to about 300 C held. The acetic acid addition is regulated so that the acetic anhydride content the circulating fluid remains constant. The newly formed acetic anhydride runs continuously from.

Under these conditions, the exhaust gas expelled on the pressure side of the pump is ketene-free (sampling between pump and cooler), the reaction of the ketene to acetic anhydride therefore 1000 / oil.

Example 2 With the same apparatus as in Example 1, but with a circulating liquid of 25,185% propionic anhydride, 8800 are going Methylketene sucked in at 38 torr. The propionic acid required for the reaction is fed to the circulating fluid.

The newly formed propionic anhydride runs off continuously.

In this case too, the exhaust gas is free of ketones, so the conversion is 1000%.

Example 3 As in the previous examples, 7300 are isopropylketene as 75% fission gas with the aid of an isovaleric anhydride circulation Sucked in at 30 Torr. Isovaleric acid is added as a reactant. The exhaust is ketene-free as in the previous examples, the conversion accordingly 100 0 / cit.

Example 4 With the same apparatus as indicated in Example 1, 8,800 gih methyl ketene and 11,150 g / h chlorine are achieved by means of a brine-cooled liquid circulation sucked in by 25 1 a-chloropropion chloride and reacted. The circulating fluid was kept at 0 ° C. The implementation is quantitative, there is neither the ketene in the exhaust gas still detect chlorine.

Example 5 With a liquid ring pump whose suction volume is at Operation with water at 150 C at 80 Torr 6.21 / min. at a vacuum of 80 Torr therefore 0.37Nms / h, at 85 Torr there are 232 g (= 8.3 mol = 186 l) of ethylene per hour and 1330 g (= 8.3 mol = about 186 1) of bromine vapor sucked in. The fluid circulation of the Pump consists of Hexachlorobutadiene. The temperature of the pump will be held at about 150 C. The reaction mixture, consisting of ethylene bromide and hexachlorobutadiene, runs continuously.

On the pressure side of the pump there is an exact dosage of ethylene and bromine no exhaust gas can be detected. The absorption and response is also in this Trap quantitative.

If you drive for a long time, the hexachlorobutadiene will gradually run out displaced the liquid circulation, so that then the overflowing liquid only consists of ethylene bromide. However, Sol a constant hexachlorobutadiene concentration be maintained, so must the liquid circulation hexachlorobutadiene in the Measures are added as the latter runs off through the overflow.

Example 6 With the same apparatus as indicated in Example 5, per hour 282 g (= 16.5 mol = 370 l) ammonia by means of a liquid circulation sucked in by 6500 g of ethyl aminocrotonate. The fluid circulation will be hourly 2150 g (16.5 mol) of ethyl acetoacetate are added. The pump temperature is kept at 350 ° C. The result of the reaction of ammonia with ethyl acetoacetate resulting ß-aminocrotonic acid ethyl ester runs together with that in the reaction resulting water from continuously.

The implementation is quantitative, there is none on the pressure side of the pump Ammonia emitted more.

Example 7 Using the same pump as in Example 5, by means of Paraldehyde is sucked in 725 g (= 16.5 mol) of acetaldehyde vapor per hour as a liquid circulation. This corresponds to a volume of 370 lih. At the same time the fluid is circulating Sulfuric acid added as a catalyst in such a way that a constant catalyst concentration of 1 ° / o is maintained. The pump temperature is kept at around 200 ° C. The newly formed crude paraldehyde runs off continuously through an overflow.

No acetaldehyde escapes on the pressure side of the pump, the intake of the gas through the liquid is therefore 100%.

PATENT CLAIM: 1. Process for the reaction of gases in liquids, characterized in that the reaction is carried out in a liquid ring pump will.

Claims (1)

2. The method according to claim 1, characterized in that the in the liquid ring pump circulating liquid next to the reactant that Reaction product itself is. 3. The method according to claim 1, characterized in that the in the liquid ring pump circulating liquid is an auxiliary liquid whose Vapor pressure is lower than the gas pressure on the suction side of the pump and in which the reaction product is suspended, emulsified or dissolved in addition to the reactant is present. 4. The method according to claim 1 to 3, characterized in that the reactants reacting with the gas are added to the circulating liquid. 5. The method according to claim 1 to 4, characterized in that the reactant reacting with the gas is gaseous. 6. The method according to claim 1 to 5, characterized in that the Reactant reacting with the gas is the gas used itself. 7. The method according to claim 1 to 6, characterized in that as Liquid compounds converted into vapor by heat or vacuum can be used individually or as a mixture. 8. The method according to claim 1 to 7, characterized in that the Circulating liquid is cooled below the temperature at which the vapor pressure the circulating liquid is equal to the gas pressure on the suction side of the pump. 9. The method according to claim 1 to 8, characterized in that the Reaction product continuously, discontinuously or according to its formation is removed by overflow on the liquid circuit. Publications considered: German Patent only. 411637, 429 779, 446163, 498136; German interpretation document No. 1 039996.