EP0445516A1 - Process and apparatus for the production of silver nitrate - Google Patents

Abstract

To produce silver nitrate, use is made of an apparatus comprising a cathode chamber (3) having a silver-free cathode (9) immersed in nitric acid, an anode chamber (4) having a silver anode (8) immersed in nitric acid, and an anion exchanger membrane (2) separating the cathode chamber (3) and the anode chamber (4). The concentration of nitric acid in the cathode chamber (3) is higher than in the anode chamber (4). When a direct voltage is applied, silver is anodically dissolved and nitrate ions migrate through the anion exchanger membrane (2) into the anode space. Virtually no undesired nitrogen oxides are produced in this process. <IMAGE>

Description

The subject of the invention is a method for producing silver nitrate by dissolving silver in nitric acid.

It is known to produce silver nitrate by dissolving silver in hot nitric acid. The following reaction takes place:



4 Ag + 6 HNO₃ → 4AgNO₃ + NO + NO₂ + 3 H₂O



It can be seen from the reaction equation that - based on the amount of silver used - an excess of nitric acid has to be used, because nitrogen oxides initially form from a third of the nitric acid used, which leave the solution as waste gas, unless part of the nitrogen dioxide formed is in turn converted into nitric acid and nitrogen monoxide with the water present in the solution. The formation of the nitrogen oxides makes it necessary to post-treat the exhaust gas, the nitrogen oxides being broken down into nitrogen and oxygen by thermal decomposition or being converted into nitric acid in gas scrubbers with the addition of oxygen. The nitric acid formed can be fed back into the process.

The silver nitrate is obtained by evaporation from the nitric acid solution, during which it crystallizes out. There are also significant amounts of nitrogen oxides in the exhaust air, which must be removed from the exhaust air in one of the ways mentioned. This is associated with considerable effort.

The invention has for its object to provide a method for producing silver nitrate, in which less nitrogen oxides are generated than before.

This object is achieved by a method with the features specified in claim 1. Advantageous developments of the invention are the subject of the dependent claims.

According to the invention, the silver nitrate is produced by an electrodialytic process: two are produced by one Anion exchange membrane separate chambers formed; in one chamber there is dilute nitric acid in which anodically polarized silver is immersed, for example in the form of a silver plate; In the other chamber there is more concentrated nitric acid, into which a silver-free cathode, which is made of V2A steel, for example, is immersed. After applying a DC voltage between the cathode and anode, silver is anodically dissolved in the dilute nitric acid and an equivalent amount of nitrate ions migrates through the anion exchanger membrane from the chamber with the concentrated nitric acid into the chamber with the dilute nitric acid and forms there with the silver that has dissolved -Ion a silver nitrate solution. An equivalent amount of hydrogen ions is discharged at the cathode to form molecular hydrogen which leaves the solution. No nitrogen oxides are initially formed in this reaction and accordingly no excess nitric acid is required. Rather, in the anolyte in which the silver anode is located, a cold, highly dilute nitric acid is used, which merely has the task of ensuring a certain electrolytic conductivity. In the course of the process, the concentration of silver nitrate in the dilute nitric acid increases, the anion exchanger membrane being an obstacle for the silver ions which want to migrate into the more concentrated nitric acid. With increasing silver concentration in the dilute nitric acid, however, a small proportion of the silver ions migrate into the osmosis more concentrated nitric acid and is deposited as sludge on the cathode. This process reduces the silver nitrate yield of the process and can lead to the formation of nitrogen oxides which are undesirable per se, but the amount of which is less by one to three orders of magnitude than in the known process.

Electrodialysis is ended when the yield drops below a predetermined value, which is associated with the consumption of the silver anode. The dilute nitric acid is then treated in a manner known per se to obtain the silver nitrate enriched therein, e.g. evaporated.

In an advantageous development of the basic idea of the invention, the deposition of silver on the cathode and its subsequent conversion with nitric acid to silver nitrate can be drastically reduced again with the formation of nitrogen oxides by providing a third chamber between the chamber containing the anode and the chamber containing the cathode (Hereinafter also referred to as the bipolar chamber in which nitric acid is present in a higher concentration than in the chamber in which the anode is contained. The third chamber is separated from the two neighboring chambers by an anion exchange membrane contains, the nitric acid can be present in a higher concentration than in the chamber with the anode, but this does not have to be the case; rather, a low nitric acid concentration in the catholyte is sufficient to maintain the necessary ionic conductivity nitric acid concentration, in particular from a concentration that begins with the Nitric acid concentration in the third chamber matches, then the nitric acid concentration in the catholyte gradually decreases by electrodialysis in favor of the nitric acid concentration in the third chamber. In the course of the electrodialysis, nitrate ions from the more concentrated nitric acid migrate through the anion exchange membrane into the anolyte (this is the electrolyte in the chamber containing the anode) and form silver nitrate with the silver that has anodically dissolved. With increasing concentration of the silver ions, some of the silver ions migrate through osmosis into the concentrated nitric acid in the third chamber, but cannot be converted there with the formation of nitrogen oxides; on the contrary, this could only happen in the nitric acid in which the cathode is immersed. To do this, however, the silver ions would have to overcome another anion exchange membrane, which would only be possible after the electrolyte had been enriched with silver ions. The losses in yield of this improved method, which is the subject of claims 2 and 3, are only low, nitrogen oxides are only produced in very small amounts.

In both process variants, the concentration of the initially more concentrated nitric acid gradually decreases. If the anolyte is removed in order to obtain the silver nitrate by evaporation, the initially more concentrated nitric acid, which has now decreased in concentration, can be used as anolyte for the next process run and replaced by fresh, concentrated nitric acid. This double use has a beneficial effect on the cost of the process.

Electrodialysis is preferably carried out with current densities of 5 to 50 A / dm² at a temperature between 5 ° C. and 60 ° C. If the current density remains below 5 A / dm², the yield is low and the process is not particularly economical . However, the yield cannot be increased arbitrarily by increasing the current density. Above a current density of 50 A / dm², one has to reckon with the fact that the anion exchange membrane is damaged and becomes porous.

It is an essential advantage of the method according to the invention that one can work with relatively cold nitric acid. However, the working temperature should not be below 5 ° C, otherwise the electrical conductivity in the electrolytes will be too low. The working temperature should also not exceed 60 ° C to avoid that the silver is chemically dissolved by the hot nitric acid.

When you stop electrodialysis essentially depends on how much nitrogen oxides you want to allow in the exhaust gas. The electrodialysis is expediently ended when the concentration of the silver ions in the catholyte exceeds 2 g / l. Since the concentration of silver ions in the catholyte increases with the concentration of silver ions in the anolyte, one can also form a criterion for the termination of electrodialysis from the concentration of silver ions in the anolyte; in the event of of the method, as stated in claim 2 or 3, in which the silver ions have to pass through two anion exchange membranes before they can reach the cathode, the electrodialysis is preferably ended when the concentration of the silver ions in the anolyte is 400 g / l exceeds.

All you need for the anolyte is a dilute nitric acid; a certain minimum concentration is required to ensure the necessary ion conductivity and to prevent hydrolysis. Preferably an anolyte is used which contains 25 to 100 g HNO₃ / l. The same applies to the catholyte in the case of the process variant according to claim 2 or 3: In this case the catholyte preferably contains 10 to 100 g HNO₃ / l; the nitric acid in the catholyte only serves to maintain the conductivity.

The higher concentration of nitric acid is used to store nitrate ions for the process; their concentration is not critical; it should be greater than the concentration in the anolyte and is preferably between 40 and 300 g HNO₃ / l.

A device for performing the method according to the invention is the subject of claim 10. It contains a cathode chamber with a silver-free cathode immersed in nitric acid, an anode chamber with a nitric acid immersing, consisting of silver anode and at least one anion exchange membrane separating the cathode chamber from the anode chamber. The concentration of nitric acid in the anode chamber is lower than in the adjacent chamber, which can be the cathode chamber, but which is preferably a chamber free of electrodes, which is arranged between the cathode chamber and the anode chamber and is separated from both by an anion exchange membrane (claims 11 and 12). With such a structure, particularly little nitrogen oxides are formed.

An advantageous development of the invention is characterized in that several such modular devices are combined to form larger systems. This can be done by arranging several anode chambers and cathode chambers in an alternating sequence and separating them from each other by an anion exchange membrane, but preferably by arranging several anode chambers and cathode chambers in an alternating sequence, each with the interposition of a chamber free of electrodes (bipolar chamber) and the chambers are separated from each other by an anion exchange membrane.

Figur 1

zeigt eine Vorrichtung mit drei aufeinanderfolgenden Elektrolytkammern,

Figur 2

zeigt eine Vorrichtung mit fünf aufeinanderfolgenden Elektrolytkammern, und

Figur 3

zeigt eine Vorrichtung mit neun aufeinanderfolgenden Elektrolytkammern.

Two embodiments of the invention are shown schematically in the accompanying drawings.

Figure 1

shows a device with three successive electrolyte chambers,

Figure 2

shows a device with five successive electrolyte chambers, and

Figure 3

shows a device with nine successive electrolyte chambers.

All three figures show the device in a vertical section. The same or corresponding parts are identified in the different figures with the same reference numerals.

In the device shown in FIG. 1, a vessel 1 is divided into three chambers 3, 4 and 5 by two mutually parallel anion-exchange membranes. The middle chamber 4 contains a silver anode 8 and nitric acid concentrated as anolyte. The chambers 3 and 5 arranged on both sides of the middle chamber 4 each contain a cathode 9 made of V2A steel and nitric acid diluted as a catholyte. After a direct voltage has been applied between the anode 8 and the cathodes 9, silver is anodically dissolved in the chamber 4 and an equivalent amount of nitrate ions migrates from the chambers 3 and 5 through the two anion exchange membranes 2 into the middle chamber 4. At the same time discharge an equivalent amount of hydrogen ions at the cathodes 9 and escape as a molecular one Hydrogen.

The device shown in Figure 2 differs from that shown in Figure 1 in that between the anode chamber 4 and the cathode chambers 3 and 5 of electrodes-free chambers 10 and 11 (bipolar chambers) are arranged, which contain the concentrated nitric acid, while the cathode chambers 9 and the anode chamber 8 each contain dilute nitric acid. When a direct voltage is applied between the anode 8 and the cathodes 9, silver anodically dissolves in the anode chamber 4. An equivalent amount of nitrate ions migrates from the bipolar chambers 10 and 11 through the anion exchange membranes 2 into the anode chamber 4 and an equivalent amount of hydrogen ions is discharged at the cathodes 9 and escapes as molecular hydrogen.

Numerical example:

The anode chamber 4 contains 8 15 l of dilute nitric acid in a concentration of 35 g HNO₃ / l in addition to the silver anode. The two cathode chambers 3 and 5 each contain 20 l of dilute nitric acid in a concentration of 20 g HNO₃ / l in addition to the cathodes 9. The two bipolar chambers 10 and 11 each contain 20 l of concentrated nitric acid in a concentration of 220 g HNO₃ / l. Electrodialysis is carried out at a temperature of 30 ° C and a current density of 30 A / dm² and is terminated when the concentration of silver ions in the anolyte reaches 400 g / l. The concentration of silver ions in the catholyte is then less than 2 g / l. The amount of nitrogen oxides released is less than 1/100 of the amount that would result from working with the conventional method (dissolving silver in hot nitric acid).

After the electrodialysis is complete, the anolyte is removed in order to obtain the silver nitrate. The silver nitrate can be obtained in a conventional manner, e.g. by evaporation.

The device shown in FIG. 3 differs from that in FIG. 2 in that it additionally contains a further anode chamber 14, a further cathode chamber 13 and two further bipolar chambers 20, 21, so that with this arrangement double the amount of silver nitrate can be produced in the device according to FIG. 2. FIG. 3 shows that by inserting further modules formed from an anode chamber, a cathode chamber and two bipolar chambers, larger systems can be built up according to the desired production capacity.

Claims (14)

Process for the production of silver nitrate by dissolving silver in nitric acid, characterized in that dilute nitric acid and more highly concentrated nitric acid are separated from one another by an anion exchange membrane, the silver is anodically polarized in the dilute nitric acid and a silver-free cathode is immersed in the more highly concentrated nitric acid . A method for producing silver nitrate by dissolving silver in nitric acid, characterized in that more highly concentrated nitric acid is separated from a first volume of dilute nitric acid by a first anion exchange membrane and from a second volume of nitric acid through a second anion exchange membrane, the silver anodically poled into the dilute nitric acid in the first volume and a silver-free cathode is immersed in the nitric acid in the second volume, the current flow from the cathode to the anode in each case being completely through the more concentrated nitric acid. A method according to claim 2, characterized in that the nitric acid in that second volume is a dilute nitric acid from the beginning (ie that its concentration is less than that of the more concentrated nitric acid in which no electrode is immersed). A method according to claim 1, 2 or 3, characterized in that after removal of the dilute nitric acid enriched with silver nitrate, the initially higher concentrated, now decreased in concentration, is used further to form the anolyte and is replaced by fresh, concentrated nitric acid. Method according to one of the preceding claims, characterized in that one works with current densities of 5 to 50 A / dm² at a temperature between 5 ° C and 60 ° C. Method according to one of the preceding claims, characterized in that the electrodialysis is ended when the concentration of the silver ions in the catholyte exceeds 2 g / l. Method according to one of claims 2 to 6, characterized in that the electrodialysis is terminated when the concentration of silver ions in the anolyte exceeds 400 g / l. Method according to one of the preceding claims, characterized in that an anolyte is used which contains 25 to 100 g HNO₃ / l. Method according to one of claims 2 to 8, characterized in that a catholyte is used which contains 10 to 100 g HNO₃ / l. Device for producing silver nitrate by dissolving silver in nitric acid, characterized by

a cathode chamber (3, 13) with a silver-free cathode (9) immersed in nitric acid,

an anode chamber (4, 14) with a silver anode (8) immersed in nitric acid,

and with at least one anion exchanger membrane (2) separating the cathode chamber (3, 13) from the anode chamber (4, 14), the concentration of nitric acid in the anode chamber (4, 14) being lower than in the adjacent chamber (3, 4 ; 10, 11; 20, 21). Apparatus according to claim 10, characterized in that the cathode chamber (3, 5, 13) and the anode chamber (4, 14) are separated by two anion exchange membranes (2) which have an electrode-free chamber (10, 11; 20, 21) (hereinafter referred to as the bipolar chamber), in which the concentration of nitric acid is higher than in the anode chamber (4, 14). Device according to claim 11, characterized in that the concentration of nitric acid in the bipolar Chamber (10, 11; 20, 21) is also higher than in the cathode chamber (3, 5, 13). Apparatus according to claim 10, characterized in that a plurality of anode chambers (4, 14) and cathode chambers (3, 5, 13) are arranged in an alternating sequence and are each separated from one another by an anion exchanger membrane (2). Apparatus according to claim 11 or 12, characterized in that a plurality of anode chambers (4, 14) and cathode chambers (3, 5, 13) are arranged in an alternating sequence, each with the interposition of a bipolar chamber (10, 11; 20, 21) and each by one Anion exchanger membrane (2) are separated.

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