RU2361966C2 - Method of electrolysing aqueous salt solution - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: initial salt solution is electrolysed thereby obtaining a solution, containing electrolysis products, to which a liquid agent is added, and further electrolysis is carried out. The liquid agent used is an aqueous salt solution, dilute with respect to the initial solution.

EFFECT: reduced power consumption in carrying out electrolysis, while providing for high output of desired product.

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Description

The invention relates to electrochemistry, in particular to methods for electrolysis of aqueous solutions of salts, and can be used to obtain solutions of salts of oxygen-containing acid of chlorine, for example sodium hypochlorite.

There is a method of electrolysis of saline solution [SU 262862], according to which electrolysis of an aqueous solution of sodium chloride is carried out in order to obtain sodium hypochlorite. The electrolysis process is carried out in several successive stages with repeated use of the electrolyte, sequentially passing the electrolyte through a series of electrolysis chambers, resulting in a more complete conversion of the starting salt and increases the yield of the target product. To normalize the temperature conditions of the flow of electrochemical reactions, the electrolyte is periodically cooled in refrigerated chambers.

A known method of electrolysis of an aqueous salt solution [RU 2125120 C1], selected by the authors as the closest analogue.

This method includes the step of electrolysis of the initial saline solution and the subsequent electrolysis of the solution obtained in the previous step containing the electrolysis products, wherein the subsequent electrolysis of the solution obtained in the previous step is carried out by additionally introducing a liquid agent into said solution, which is used as water.

Used in the considered method, the method of diluting the electrolyte solution obtained at the previous stage of electrolysis with water allows increasing the yield of the target product, as well as optimizing the temperature regime of electrochemical reactions. However, this increases the energy consumption for electrolysis.

The task of the invention is to reduce the energy consumption for the implementation of the process of electrolysis of an aqueous solution of salt while ensuring a high yield of the target product.

The essence of the invention lies in the fact that in the method of electrolysis of an aqueous salt solution, comprising the step of electrolyzing the initial salt solution and subsequent electrolysis of the solution obtained in the previous step containing electrolysis products, the subsequent electrolysis is carried out by adding liquid to the solution obtained in the previous step of the agent according to the invention, a dilute aqueous solution of salt is used as a liquid agent.

A feature of the proposed method is that it uses the method of introducing into the zone where the electrolysis is carried out, the solution obtained at the previous stage of electrolysis, a liquid agent, which is used diluted with respect to the original aqueous salt solution. As shown by the authors of experimental studies, this leads to an increase in the yield of the target product. Apparently, when the electrolyte solution is diluted with the indicated liquid agent, the concentration of the reagents decreases and the reactions between the products of the electrochemical conversion in the solution shift toward the formation of the target product. Moreover, due to the fact that the specified liquid agent contains dissociated salt ions, the electrical conductivity of the electrolyte solution increases, which is subjected to electrolysis and, as a result, the cost of electricity for electrolysis is reduced.

In addition, depending on the specific electrolysis process, the temperature of the liquid agent described above is selected from the conditions for optimizing the temperature conditions of the electrochemical reactions, which also has a positive effect on increasing the yield of the target product and reducing the cost of electricity for electrolysis.

Thus, the claimed method provides a reduction in energy consumption for electrolysis while ensuring a high yield of the target product.

The inventive method can be implemented in electrolytic cells of both continuous and periodic action, while electrolysis can be carried out using a single electrolysis section or a series of series-connected electrolysis sections.

The drawing shows a schematic representation of a General view of one of the special cases of the installation to implement the proposed method.

The method is as follows.

In the case of carrying out the electrolysis process in batch electrolyzers, the prepared initial aqueous salt solution is loaded into the electrolyzer and electrolysis is carried out in the mode required for a particular process. At the end of the electrolysis process to the resulting solution containing the products of the electrochemical reaction, add diluted with respect to the original aqueous saline and again carry out the electrolysis process. Then, the above liquid agent is again added to the obtained electrolyte solution and the electrolysis process is again carried out.

At the same time, at each subsequent stage, dilute aqueous salt solution is added in relation to the initial one. As follows from practical experience, to add, you can use a salt solution diluted with respect to the original solution at least 2 times with a volume ratio of electrolyte solution and said diluted saline solution of 1: (0.15-2.00).

The operation of adding the specified liquid agent is repeated until there is a noticeable increase in the yield of the target product in comparison with the previous stage of electrolysis. As practice has shown, it is economically feasible to repeat the electrolysis operation when adding to the solution obtained in the previous stage, the above liquid agent, 3-4 times.

In the case of an electrolysis process in flow-type electrolyzers, for example, in a box-type electrolyzer with undivided cathode and anode spaces, the method is as follows (see drawing).

The initial aqueous salt solution from the source 7 of the aqueous salt solution using the means 8 for supplying the specified solution to the electrolysis section 2 of the electrolyzer 1 is fed from above into the interelectrode space of the electrodes 3. Moreover, the specified liquid agent is supplied from the source 9 of the salt diluted with respect to the initial aqueous solution using means 10 for supplying it to the zone 11 located in the lower part of the electrolysis section 2.

Zone 11 is the zone in which the electrolysis of the electrolyte solution obtained in the previous electrolysis is carried out.

For the installation shown in the drawing, zone 11 represents that part of the volume of the electrolysis section 2 occupied by the electrolyte solution by the height of the electrolyzer, in which a noticeable amount of the target electrolysis product is present in the electrolyte.

The first stage of electrolysis of the initial aqueous salt solution occurs in the volume of the electrolysis section 2, located above the location of the means 10. The next stage of electrolysis of the electrolyte solution containing electrolysis products occurs when salt is diluted with respect to the initial aqueous solution in zone 11.

The specified stage of electrolysis proceeds in the volume of the electrolysis section 2, lying below the location of the means 10.

At the end of electrolysis, the solution containing the target product enters the collection section 4 of the target product and is drained through pipe 5.

Examples of the implementation of the proposed method.

Example 1. Carried out the electrolysis of a 10% solution of sodium chloride (NaCl) in order to obtain a solution of sodium hypochlorite (NaClO).

The electrolysis was carried out in a periodic cell electrolyzer with an undivided electrode space. Electrolysis mode: U = 22 V; f = 0.5-0.6 A / cm ² . The volume of the initial saline solution is 3 liters. The first stage of electrolysis was carried out for 35 minutes.

At the end of the first stage, the amount of NaClO in the solution was 15.9 g (in terms of active chlorine).

To the solution obtained in the first stage was added 3 L of an aqueous salt solution diluted 5 times with respect to the initial saline solution, with a volume ratio of these solutions of 1: 1. The temperature of the added saline was 18.0 ° C.

The resulting electrolyte in a volume of 6 l was fed to the second stage of electrolysis. The electrolysis mode was not changed.

At the end of electrolysis, the amount of NaClO in the solution was 36 g.

The third, fourth, fifth and sixth stages of electrolysis were carried out in a similar manner. Before each subsequent stage, the solution obtained in the previous stage was diluted with the above liquid agent in a volume ratio of 1: 1.

The amount of NaClO in the solution after the third stage was 72 g, after the fourth stage - 96 g, after the fifth - 120.8 g.

After the sixth stage, the yield of NaClO did not increase compared with the fifth stage, which indicated the inappropriateness of the further process.

In total, upon decomposition of 600 g of NaCl, 120.8 g of NaClO was obtained, which is a very high result for the electrolysis process under consideration.

Electricity costs amounted to 4.2-4.5 kW per 1 kg of sodium hypochlorite (in terms of active chlorine).

Example 2 (comparative).

Conducted electrolysis in accordance with the method selected as the closest analogue.

Carried out the electrolysis of a 10% solution of sodium chloride (NaCl) in order to obtain a solution of sodium hypochlorite (NaClO).

The electrolysis was carried out in a periodic cell electrolyzer with an unshared electrode space. Electrolysis mode: U = 22 V; f = 0.5-0.6 A / cm ² . The volume of the initial saline solution is 3 liters. The first stage of electrolysis was carried out for 35 minutes.

At the end of the first stage, the amount of NaClO in the solution was 15.9 g (in terms of active chlorine).

To the solution obtained in the first stage, 3 L of water with t = 18.0 ° C was added at a volume ratio of the solution to water of 1: 1.

A solution diluted with water in a volume of 6 L was fed to the second stage of electrolysis. The electrolysis mode was not changed.

At the end of electrolysis, the amount of NaClO in the solution was 36 g.

The third, fourth, fifth and sixth stages of electrolysis were carried out in a similar manner. Before each subsequent stage, the solution obtained in the previous stage was diluted with water in a volume ratio of 1: 1.

The amount of NaClO in the solution after the third stage was 72 g, after the fourth stage - 96 g, after the fifth - 120.8 g.

After the sixth stage, the yield of NaClO did not increase compared with the fifth stage, which indicated the inappropriateness of the further process.

In total, upon decomposition of 300 g of NaCl, 120.8 g of NaClO was obtained.

Electricity costs amounted to 6.0-6.5 kW per 1 kg of sodium hypochlorite (in terms of active chlorine).

Example 3

Carried out the electrolysis of a 10% solution of NaCl in order to obtain NaClO using the electrolyzer shown in the drawing.

The flow rate of the initial saline solution was 220 l / h, the flow rate of the aqueous salt solution diluted 5 times with respect to the initial one was 33 l / h. In this case, the volume ratio of these solutions was maintained at 1: 0.15.

Electrolysis mode: voltage - 80 V, current density - 0.6 A / cm ² .

The residence time of the electrolyte in the working area was 18 s.

The concentration of NaClO in the resulting solution with a volume of 253 L was 6.7 g / L (in terms of active chlorine), which corresponds to 2295.1 g.

Electricity costs amounted to 4.2-4.5 kW per 1 kg of sodium hypochlorite (in terms of active chlorine).

Example 4 (comparative).

Conducted electrolysis in accordance with the method selected as the closest analogue.

Carried out the electrolysis of a 10% solution of NaCl in order to obtain NaClO using the electrolyzer shown in the drawing.

Saline flow rate - 220 l / h, water flow rate - 33 l / h. In this case, the volume ratio of the solution and water was maintained at 1: 0.15.

Electrolysis mode: voltage - 80 V, current density - 0.6 A / cm ² .

The residence time of the electrolyte in the working area was 18 s.

The concentration of NaClO in the resulting solution with a volume of 253 L was 6.7 g / L (in terms of active chlorine), which corresponds to 2295.1 g.

Electricity costs amounted to 6.0-6.5 kW per 1 kg of sodium hypochlorite (in terms of active chlorine).

Thus, as can be seen from the above examples, when implementing the proposed method, a reduction in energy costs is achieved while ensuring a high yield of the target product.

Claims (1)

The method of electrolysis of an aqueous salt solution, comprising the step of electrolysis of the initial salt solution and subsequent electrolysis of the solution obtained in the previous step containing electrolysis products, the subsequent electrolysis being carried out when a liquid agent is added to the solution obtained in the previous step, characterized in that as the liquid agent is used diluted with respect to the original aqueous salt solution.