DE2362923C3 - Process for the production of ammonium rhodanide - Google Patents

Description

The invention relates to a process for the continuous production of ammonium rhodanide in a column divided into three zones, with the ammonia and carbon disulfide in the molar ratio of 2: 1 are introduced into the middle zone, the ammonium rhodanide formed from the lower zone is withdrawn and hydrogen sulfide escapes at the top of the column.

The synthetic production of ammonium rhodanide from carbon disulfide and ammonia takes place each after the reaction has been carried out via the intermediates ammonium dithiocarbamai and ammomumtrilhiocar bonat to the end products ammonium rhodanide and hydrogen sulfide.

This reaction was previously due to the volatility of the starting materials and the Zersetziichkeu the Intermediate products run under overpressure in closed pressure vessels, and because of the high Pressure increase was necessary due to the hydrogen sulfide evolved during the reaction, a large excess of ammonia water increases the hydrogen sulfide as ammonium sulfide bind and thus make them water-soluble.

A disadvantage of this procedure is that the starting materials are carbon disulfide and ammonia water exist in two different, mutually insoluble liquid phases, so that the reaction initially only takes place at the phase interfaces. As a result, the reaction speed remains low, and the response time is greatly increased. Only as the reaction progresses do the water-soluble ones form Intermediate products, transforming the various liquid phases into a single aqueous phase pass over. From this point on, the further implementation takes place in a relatively short time.

Another disadvantage is that this pressure reaction because of the sharp rise in pressure at the beginning of the Reaction can only be carried out in individual batches and on a limited scale therefore a continuous operation is very difficult.

The end product of this pressure reaction is an aqueous solution of ammonium thiocyanate and sulfur ammonium. The latter has to be removed from the reaction mixture through an additional process step are boiled and can be obtained as an aqueous solution or by a further process step be converted into a sulfhydrate, ammonia

ίο is recovered.

Recently, two processes have become known according to which the reaction with carbon disulfide and ammonia carried out continuously and without pressure or with a slight overpressure in reaction towers will.

According to a known method, a reaction tower is used which is filled with conventional packing elements, such as Raschig rings. The reaction between carbon disulfide and ammonia is carried out in the presence of an aqueous ammonium rhodanide solution with 20 to 50% by weight NH ₄ SCN by recycling part of the ammonium rhodanide solution produced, the reaction rate remaining low. The end product is ammonium thiocyanate solution and gaseous hydrogen sulfide (US Pat. No. 2,850,356).

In another known continuous mode of operation, the reaction is carried out in a tubular reactor in The presence of activated carbon and carried out with a large excess of carbon disulfide. An aqueous solution of ammonium rhodanide and hydrogen sulfide gas are formed as end products a high content of excess carbon disulfide, in an additional washing system with a suitable ab-, orpiionsöl removed and recovered will.

Both processors have the disadvantage with regard to the apparatus implementation in operation that the entire Due to the high aggressiveness of the ammonium rhodanide, the system must be made of high-quality stainless steel. to keep corrosion at an economically acceptable level. This problem as well as the disadvantage the repeatedly / u additional expensive activated carbon is avoided in the method according to the invention.

4 ") The object of the invention is to create a continuously operating process / ur production of ammonium rhodanide which, without a catalyst, with the disadvantages associated therewith, and without continuous recirculation of NH ₄ SCN with constant dilution of the reaction mixture at a high reaction rate, to a pure End product and that can be carried out smoothly over a long period of time without the need to use high-quality stainless steel for the entire apparatus.

The process according to the invention for the production of ammonium rhodanide is characterized in that that the ammonia and the carbon disulfide are placed in an aqueous solution in the middle zone Sulfur ammonium solution, which contains sulfur ammonium in at least an equivalent amount, based on carbon disulfide, contains, dissolves and the ammonium trithiocarbonate formed in the lower zone of the column Ammonium rhodanide and hydrogen sulfide decomposed thermally and developed a part of it

fa5 hydrogen sulfide is used with the introduced ammonia for the continuous regeneration of the sulfur ammonium.
The method according to the invention is continuously

Itch done

The inventive method is based on the fact that the reaction time can be shortened considerably, if the reaction is not directly related to the starting materials Carbon disulfide and ammonia, but in the presence of at least equivalent amounts of ammonium sulfur started and continued, so that the introduced carbon disulfide with the formation of Ammonium trithiocarbonate is immediately dissolved. As a result, the reactants are in dissolved form and in a thin aqueous phase, which consists of ammonium trithiocarbonate and sulfur ammonium It is particularly advantageous to use an excess of Schrwefe'.ammonium. The ammonium trithiocarbonate is then in the decomposition zone in ammonium rhodanide with elimination of Hydrogen sulfide is converted while the ammonium thiocyanate at the end of the reaction as aqueous Solution is withdrawn, forms part of the evolved hydrogen sulfide with the introduced ammonia again sulfur ammonium, which is continuously regenerated in this way.

The overall reaction therefore proceeds according to the following reaction equations:

(NlI ₄ I ₂ S + CS ₂

H ₂ S + 2 NH,

MNH ₄ I ₂ CS, (D

* NH ₄ SCN + 2 H ₂ S (2]

(NH ₄ I ₂ S (3)

For the overall reaction, duher dio results Sum equation:

CS ₂ + 2 NH.,

NH ₄ SCN + H ₂ S

d. That is, the reaction is carried out with the theoretical starting amounts, and that for the formation of the Sulfur ammonium required for the intermediate product is only necessary within the reaction zone Reaction partner and is there continuously from the ammonia introduced and that during the decomposition of the intermediate product regenerated hydrogen sulfide. The excess hydrogen sulfide escapes in a gaseous state after a washing process.

When the process is carried out continuously, the ammonium sulphide in the reaction mixture is thoroughly absorbed ammonia gas introduced and hydrogen sulfide gas formed during the reaction are continuously regenerated.

The reaction using a column, in particular a bell-bottom column, is particularly advantageous, carried out continuously in several stages.

The decomposition of the ammonium trithiocarbonate preferably takes place at a higher temperature than the temperature at which the trithiocarbonate is formed, within the range from 50 to 90 ^° C.

For the technical implementation of the process, the reaction is broken down into individual stages, which are divided into three Declare zones of a column, only suitable for this purpose A combined bubble cap column is particularly suitable, although other column constructions are applicable.

The conduct of the reaction according to the invention for the preparation of NH ₄ SCN is described below and explained with reference to the schematic representation shown in the drawing

The column K is divided into three zones. The lower zone 1 is used to rearrange the ammonium trithiocarbonate in ammonium rhodanide with elimination of hydrogen sulfide at temperatures between 50 and 90 C, preferably 70 to 80 ⁰ C, and contains in the lower part two heating registers 4, 5 for heating the reaction solution to the necessary temperature without

Hi other fixtures. A pressure of 1 to 2 m is favorable Water column, corresponding to the sum of the immersion seals of the bubble cap column and the outer one Immersion seal 9 in the hydrogen sulfide discharge.

r> The aqueous ammonium thiocyanate solution formed is drawn off at the bottom of the column for further processing via a level vessel 6, while the hydrogen sulfide evolved escapes into the upper zones. In the middle zone 2, on the one hand, the formation of ammonium trithiocarbonals takes place from the sulfur ammonium and the supplied carbon disulfide and, on the other hand, the formation of ammonium sulfide from the hydrogen sulfide developed in zone 1 and the imported

2) th ammonia. The introduction of the starting materials in a molar ratio of 1 CS ₂ : 2 NH3 takes place via a circulation system outside this part of the column in order to achieve intensive mixing and circulation of the reactants. For this purpose, the reaction mixture is drawn off through a pipeline from the sump of the lower body of zone 2 and fed to a gas jet pump 7. Before this pump, the carbon disulfide is introduced in liquid form into the suction line. The gas jet pump 7 is operated by means of an ammo

Γι niakgas under the tensile pressure of the liquid (4) Ammonia operated and thus via the jet nozzle the

required ammonia introduced. At the same time, it brings about an intensive mix of all editorial participants. Since this reaction is exothermic, it is advisable to put it in the pressure line of the gas jet pump a heat exchanger 8 built in, which ensures an optimal reaction in the temperature range from 30 to 50 C. preferably 40 "C. allows the pressure line is then returned to the top floor of Zone 2

4 ^r i so that the circuit is closed

The upper zone 3 of the column is used to introduce the necessary fully demineralized water of solution at a temperature of about 10 to 20 ⁰ C at the top of the column, which at the same time to wash out the

Μ the lower zones entrained ammonia and carbon disulfide gases from the excess Hydrogen sulfide gas is used. The number of plates in this zone is to be dimensioned so that at the top of the column pure hydrogen sulfide escapes, which via a

5 ") immersion closure 9 discharged for further use will.

For this process, the proposed bubble cap column has the advantage that the immersion seals the individual bell bottom from top to bottom

At the bottom there is a slight increase in pressure, which counteracts the decomposition of the ammonium trilhiocarbonate into the starting materials and favors the rearrangement in the direction of ammonium thiocyanate.
The most essential feature of this procedure is that

b ¹ ) Presence of sulfur ammonium in at least an equivalent amount, preferably in excess, in the middle zone 2 of the column, which is continuously regenerated and due to the rapid formation of the intermediate product

tes amnionium rithiocarbonate to a strong shortening the response time leads.

The yields are practically theoretical. Another great benefit of this procedure is that low aggressiveness of this reaction mixture that it allows most of the combined Ciluk kenbodenkok-.nne to be carried out in iron, like that years of experience have proven. Only the lower part of the column with the heating registers has to be off consist of high quality stainless steel.

The following example serves to further explain the invention.

example
Before the start of the reaction, the bubble-cap tray column is filled with deionized water up to the overflow of the individual trays in the upper part, insofar as it encompasses zone 3.
In the middle part of zone 2, for example, 200 kg of ammonium sulfur solution with 89.4 kg (NH ^ S vorgelepi The reaction is carried out by adding carbon disulfide and ammonia in a molar ratio of 1 CS _?: 2 NH ₃ , e.g. 1000 kg / h carbon disulfide and 447 kg / h of ammonia, continuously while maintaining a temperature range of 70 to 80 ⁰ C in zone 1 and from 30 to 5O ⁰ C in zone 2 started and continued. arise end products 1000 kg / h of ammonium thiocyanate than 30 to 50% aqueous solution, which corresponds to a theoretical yield, and 580 mVh hydrogen sulfide gas.

1 sheet of drawings

Claims (2)

Patent claims: 1. Process for the continuous production of ammonium rhodanide in a divided into three zones Column in which ammonia and carbon disulfide in a molar ratio of 2: 1 in the middle Zone are introduced, the ammonium rhodanide formed is withdrawn from the lower zone and Hydrogen sulfide escapes at the top of the column, characterized in that one the ammonia and carbon disulfide in an aqueous solution placed in the middle zone Sulfur ammonium solution, the sulfur ammonium in at least equivalent amount, based on carbon disulfide, contains, dissolves and the formed Ammonium thiithiocarbonate in the lower 7one of the Amniotic Rhodapid and Hydrogen Sulphide Column thermally decomposed and part of the evolved hydrogen sulfide with the imported Ammonia is used for the continuous regeneration of the sulfur ammonium. 2. The method according to claim 1, characterized in that the column is a bubble-cap tray column used.