UA7362U - Method for water preparation - Google Patents

Abstract

Method for water preparation includes filtration of outlet water through N-cation filters of the first and the second stage, with sequential regeneration of filters with regeneration acid solution.

Description

Description of the invention

The proposed useful model refers to the cation exchange technology of water preparation (desalination), which can be used for water demineralization in the field of thermal energy.

There is a known method of preparing water by two-stage H-cationization of the source water, in which the source water is sequentially passed (filtered) from top to bottom through filters of the first and second stages loaded with cation exchange resin. Water filtration in this method is carried out before sodium ions pass through the finished water, which comes out after the second-stage filter. 70 Filters are regenerated with a sulfuric acid regeneration solution sequentially: first, the regeneration solution is passed through a second-stage filter, and then through a first-stage filter.

A counter-flow method of regeneration is used, in which the regeneration solution in both filters is fed against the flow of water, that is, the water in both filters is fed from top to bottom, and the regeneration solution in both filters is fed from bottom to top. (1).

A method of water preparation is also known, which includes filtering the source water through two series-connected H-cationite filters of the first and second stages, and sequential regeneration of the filters with an acid regeneration solution, which is fed into the second stage filter parallel to the flow of water.

Water filtration in this method is also carried out before the passage of sodium ions in the finished water, that is, in the water that comes out after the second-stage filter.

In this method, a parallel flow method of regeneration is used, in which the regeneration solution in both filters is supplied parallel to the flow of the source water, that is, the water in both filters is supplied from top to bottom and the regeneration solution in both filters is also supplied from top to bottom. Moreover, water is first fed into the first-stage filter and then into the second-stage filter, and the regeneration solution is fed first into the second-stage filter and then into the first-stage filter. (1).

The disadvantage of the known methods of water preparation is the increased washing of the regeneration solution for the regeneration of the filters and the significant release of salts into the sewer.

These shortcomings are due to the discharge into the sewer of the first portions of the regeneration solution, which comes from the second-stage filter and which cannot be fed into the first-stage filter due to the presence of a high concentration of calcium ions in this solution, which creates a danger of crystallization of calcium sulfate in the first-stage filter. The high concentration of calcium ions in the regeneration solution after the second-stage filter is due to "the fact that water filtration is carried out before sodium ions pass through the finished water, which comes out after the second-stage filter, and, thus, the H-cationite matrix of the second-stage filter contains a significant amount ions about calcium. In the process of regeneration, calcium ions on the cationite matrix are replaced by hydrogen and pass into the regeneration solution, which makes it impossible to use the first portions of the regeneration solution for the first stage filter regeneration. Therefore, the first portions of the regeneration solution that come out of the second-stage filter are thrown into the sewer.

In addition, the use of parallel-current regeneration of the first-stage filter worsens the conditions of water purification in this filter, because the water first meets the most completely reduced upper layer of the cationite 8, and then - with the less reduced lower layer of the cationite of this filter. This leads to the rapid leakage of 70% of calcium to the filter of the second stage, the deterioration of its working conditions, the reduction of the exchange capacity and the increase in the consumption of the regeneration solution for the regeneration of both filters. The basis of the useful model is the task of improving the known method of water preparation, in which by changes in the conditions of the process of water filtration and regeneration of H-cationite, it is possible to reduce the costs of the regeneration solution and reduce the emissions of salts into the sewage system.

The problem is solved by the fact that in the known method of water preparation, which includes filtering the source and water through two series-connected H-cationite filters of the first and second stages, and successive regeneration of the filters with an acid regeneration solution, which is fed to the filter of the second stage parallel to the flow of water, according to the proposed method, the filtering of the source water is carried out until calcium ions pass through the water outlet from the first-stage filter, and the regeneration of this filter is carried out with 20 countercurrent to the flow of water with the regeneration solution, which is obtained after the parallel-current regeneration of the second-stage filter . Sulfuric acid is used as an acid.

The proposed method provides: - reduction of regeneration solution costs for regeneration of filters of the first and second stages; - increasing the life of the second stage filter;

So" - improvement of environmental safety by reducing emissions of salt solution into the sewage system.

Filtration of water until the passage of calcium ions at the water outlet from the first-stage filter creates such conditions that after the stage of water purification by the filtration method, the N-cationite of the second-stage filter, downstream of the water, is exclusively in the sodium-magnesium form and practically does not contain calcium ions , and the H-cationite of the filter of the first, upstream, stage is exclusively in the calcium form. 60 This circumstance facilitates the regeneration of the second-stage filter with a regeneration solution, in the process of which the sodium and magnesium ions of the cationite matrix are easily replaced by hydrogen ions and pass into the regeneration solution, which makes it possible to use the first portions of the regeneration solution after the second-stage filter for the regeneration of the first-stage filter and not throw away them into the sewer. The regeneration solution after the second stage filter, which initially contains a mixture of sodium, hydrogen and magnesium cations, after the second stage filter regeneration is completed, is an acid solution.

This circumstance also allows to reduce the cost of the regeneration solution for the regeneration of the first-stage filter, because it is largely restored by the regeneration solution obtained after the regeneration of the second-stage filter, which contains sodium and magnesium ions.

This circumstance also makes it possible to apply a parallel flow method of regeneration at the second stage of water filtration using a second stage parallel flow filter that is simpler in design and equipment.

Along with this, the use of the combined filter regeneration method proposed by the applicant, first in parallel with the current method of regeneration of the second-stage filter and then with the counter-current method of regeneration 7/0 of the first-stage filter, makes it possible to soften the conditions of regeneration of the first-stage filter and reduce the costs of the regeneration solution for its regeneration, and as well as improving water filtration conditions and increasing the life of the second stage filter. Due to the fact that the source water first meets with the least reduced upper layer of the cation, and then with the more reduced lower layer of the cationite of the first stage filter, and then with the even better reduced cationite of the second stage filter.

The technical result of the method consists in increasing the cost-effectiveness and environmental safety of the process by reducing the costs of the regeneration solution for filter regeneration, using the first portions of the regeneration solution obtained after the regeneration of the second-stage filter for the regeneration of the first-stage filter, and eliminating the discharge of these first portions of the regeneration solution into the sewer.

The proposed method includes the following stages: - filtration of the source water through two series-connected H-cationite filters of the first and second stages. Moreover, the filtration of the source water is carried out before calcium ions pass through the water outlet from the first-stage filter; - sequential regeneration of filters with an acid regeneration solution, which is first fed into the second-stage filter parallel to the flow of water, and then the regeneration solution that comes out after the second-stage filter is fed to the first-stage filter upstream of the water flow. Regeneration of filters includes operations: loosening of the cationite with softened water, actual regeneration of the filters with a regeneration solution of sulfuric acid and washing of the cationite with water from the regeneration solution of sulfuric acid.

The main parameters of the filters are calculated based on the productivity of the installation, taking into account the speed of filtration in the filter of the first stage of 15-25m/hour, of the second stage - 30-40m/hour, and based on the volume of loading of the highly acidic universal cationite KU-2-8. The loading volume of the filters of the first and second stages is calculated based on the ratio of the concentration of calcium ions in the source water to the total concentration of cations, taking into account the working exchange capacity of the cationite and the productivity of the installation. with

Consideration is also given to the fact that is the basis of the proposed method, according to which calcium ions are retained by the cationite of the filter of the first stage, and only the remaining cations (mainly magnesium and sodium ions) that remain after the removal of calcium ions in the filter of the first stage enter the filter of the second stage degree

The volume of cationite for loading the second-stage filter is calculated in such a way that it ensures the complete absorption of all the remaining cations, until the regeneration unit is turned off, which is carried out due to the fact that calcium cations have slipped through the filtrate after the exit of water from the first-stage filter more 2Omkg.eq/l.

The proposed method is explained by a drawing of a scheme of a water purification and filter regeneration installation and with a specific example of the implementation of the method. c The diagram shows: filter 1 of the first stage and filter 2 of the second stage, loaded with cationite KU-2-8 in . H-shaped, drainage 3,4, pipelines: water inlet 5 for purification, purified water outlet 6, inlet 7 and outlets 8,9 and? softened water for loosening, inlet 10 and outlet 11 of regeneration solution of sulfuric acid, inlet 12 of softened water for washing filter 2; and latches 13-25.

Example. The source water, which contains calcium, magnesium and sodium salts, is fed through the pipeline 5 and the open valve 13 from above into the filter 1 of the first stage. Water passes through filter 1 from top to bottom at a speed of 15-25m/hour, leaves filter 1 and through open valves 14,15 enters from above into filter 2 of the second stage, passes through filter 2 from top to bottom at a speed of 30-4O0m/hour and then is ready "hot water comes out of the filter 2 through

Ge» pipeline 6 and open valve 16. In the process of filtration, H-ions of the KU-2-8 cationite matrix are replaced by ions of calcium, magnesium, and sodium. The filtration process is carried out until calcium ions pass through at the water outlet from filter 1. g" For this purpose, the water at the outlet of filter 1 is periodically analyzed for calcium content. In the presence of calcium ions in the amount of 20 μg.eq/l at the water outlet from filter 1, both filters 1, 2 are stopped for regeneration. For this, latches 13 and 16 are closed.

Regeneration of filters includes operations: loosening of cationite with softened water, regeneration

Han with a regenerating solution of sulfuric acid and washing the cationite from a regenerating solution of sulfuric acid.

Cationite loosening is carried out with softened water, which is supplied to filters 1, 2 from the softened water collector or from the softened water pipeline of the working block of H-cationite filters. Water is supplied to the filters from the bottom up, from where it is removed through the distributor. First, loosening of cationite in filter 1 is carried out with softened water, which is fed through valve 17 and discharged through valve 18. Then valve 18 is closed, because valves 14, 19, 20 are opened, and cationite is loosened in filter 2. After loosening, valves 17, 20 are closed. If there is a flow meter on each of the filters, loosening of both filters can be carried out simultaneously, while the flow of water for loosening is regulated by valves 17 and 20. The speed of water during loosening is 10-15 m/hour. The duration of fluffing is 20-30 minutes.

After loosening, filter regeneration is carried out: first, filter 2 65 is regenerated parallel to the flow of water (i.e., with the flow of regeneration solution from top to bottom), and then regeneration of filter 1 is carried out upstream of the water flow (i.e., with the flow of regeneration solution from bottom to top). For this purpose, valves 21, 19, 14, 22 are opened and the regeneration solution of sulfuric acid is fed from above into filter 2 through its upper distribution device and removed from below through its lower drain and open valve 19.

Next, the regeneration solution after filter 2 is fed from below into filter 1 through the open valves 19, 14 and is discharged through the upper drain of filter 1 and the open valve 22. The speed of the regeneration solution is 10-15 m/hour. The specific consumption of sulfuric acid is 1.05-1.15 from stoichiometry (depending on the concentration of calcium ions in the source water). First, 4095 of the total amount of acid regeneration solution is passed in the form of a 195th solution, then 4095 - in the form of a 296th solution. The rest of the regeneration solution is passed in the form of a 595% acid solution. After the end of regeneration, the valves 21, 22 are closed. 70 After the actual regeneration of the filters, wash the filters 1.2 from the regeneration solution. Filter 1 is washed with open valves 13, 23 with the source water, which is supplied at a speed of 10-15 m/hour until the acidity is reached, which corresponds to the acidity of the filtrate in the operating mode of filter 1. Filter 2 is washed with softened water. after washing the filter 1, valves 13, 14, 15, 24 are opened for softened water, and if softened water is used from the parallel working unit 7/5 filters or from the softened water tank, valves 25, 15, 24 and filter washing 2 are opened carried out in parallel with washing of filter 1. After washing, valves 24, 23, 15 and 25 are closed. 12 th x their "4 - th 32-- o n 10 only that 5 V- r 20 n

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Claims (2)

The formula of the invention 1. The method of water preparation, which includes filtering the source water through two series-connected H-cationite filters of the first and second stages and successive regeneration of the filters with an acid regeneration solution, which is fed into the filter of the second stage parallel to the flow of water, which differs in that , that the filtration of the source water is carried out before calcium ions pass through the water outlet from the first-stage filter and "" the regeneration of this filter is carried out countercurrent to the flow of water with the regeneration solution that comes out " after the parallel-current regeneration of the second-stage filter. 2. The method according to claim 1, which differs in that sulfuric acid is used as an acid. - Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated microcircuits", 2005, M 6, 15.06.2005. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. (22) ma 70 So 60 b5