RU2072325C1 - Method of desalting water - Google Patents

Abstract

FIELD: freshening of water. SUBSTANCE: method includes the following operations: passage of water (naturally occurring or waste water) through ammonium and hydrocarbonate ionites, deaeration accompanied with absorption of volatile components with water; recovery of cationite with salt concentrate and then with exhausted anionite recovery solution; preparation of salt concentrate by concentrating liquid phase obtained after heat treatment of mixture of exhausted cationite solutions and its preliminary treatment with alkali reagent; recovery of anionite with solution obtained after absorption of volatile components from water deaeration stage and heat treatment of mixture of exhausted cationite recovery solutions. As a result, total salt content in water is 2.0-2.3 times reduced, including magnesium ion content 2.7-3.5 times, sodium ion 2.1-2.4 times, and chloride ion 2.0-2.3 times reduction. Volumes of recovery solutions to be treated are reduced by a factor of 1.1. EFFECT: increased desalting degree; reduced power consumption; simplified process. 2 cl, 1 dwg, 1 tbl

Description

 The invention relates to the desalination of natural and wastewater by ion exchangers and can be used in the power industry, chemical, oil refining and other industries.

A known method of desalination of water, providing for its sequential filtration through hydrogen cation exchange resin and anion exchange resin. The salinity of demineralized water by the method is 20 mg / L. Cation exchanger regeneration is carried out according to a two-stage scheme with a mixture of carbon ammonium salt and ammonia, and then with a solution of nitric acid. The spent carbon-ammonium salt solution is evaporated, the precipitate is separated, and the volatile components formed during evaporation are absorbed by water and used to prepare new portions of the cation exchange resin regeneration solution. The mother liquor, which is a soda concentrate with impurities of sodium bicarbonate and ammonium ions, is used to regenerate anion exchange resin. The spent regeneration solution of nitric acid, containing its excess, ammonium nitrate, magnesium and calcium, is neutralized and used to produce nitrogen fertilizers. When desalting water according to the method, the total volume of spent regeneration solutions of cation exchange resin and anion exchange resin to be processed (a value that largely determines the energy intensity of water desalination technology) is about 10 m ³ per 1 m ^{3 of} ion exchanger.

 The disadvantages of the method are the relatively high salinity of demineralized water and significant energy consumption during the disposal of spent regeneration solutions of ion exchangers.

The purpose of the invention is to increase the degree of desalination of water by reducing the content of Mg ²⁺ , Na ⁺ , Cl ^- ions, reducing energy intensity and simplifying the process.

The goal is achieved in that the source water NH ₄ ⁺ - is cationized and HCO ₃ ^- - anioned, after the anionized water, it is deaerated when heated with absorption of volatile components by water, the cation exchange resin is regenerated in succession with a salt concentrate and spent anion exchange solution containing carbon ammonium salts and ammonium salts of strong acids; the salt concentrate is obtained by concentrating the liquid phase after heat treatment of the mixture of spent regeneration solutions of cation exchange resin obtained by its regeneration with the indicated reagents, and the salt concentrate spent on the regeneration of cation exchange resin is pretreated with an alkaline reagent, which is used as alkali metal hydroxides, regeneration of the anion exchange resin is carried out with a solution of carbon ammonium salts obtained by absorption volatile components with water from the stages of processing the mixture of waste regeneration solutions of cation exchange resin and deaeration of water.

 The introduction of an alkaline reagent (alkali metal hydroxide) in the salt concentrate spent on the regeneration of cation exchange resin changes the composition of the mixture of spent regeneration solutions of cation exchange resin in such a way that the softening depth of the mixture increases due to the removal of magnesium ions in the form of magnesium hydroxide and calcium ions in the form of a sparingly soluble calcium sulfate, and the ratio of alkali metal ions to strong acid anions changes so that all strong acid anions are bound by alkali metal ions and there are no conditions for the formation of amm Niine salts of strong acids in the solution heat treated. The latter provides an increase in the degree of recovery of ammonia in the processing of spent regeneration solutions, and therefore, an increase in the concentration of the regeneration solution of carbon ammonium salt without additional consumption of ammonia, which increases the depth of regeneration of ion exchangers and leads to a decrease in the salt content in desalted water.

An increase in the softening depth of the spent regeneration solutions of cation exchanger and, consequently, the salt concentrate obtained during their processing, on the one hand, and consecutive regeneration of the cation exchanger with a deeply softened salt concentrate and the spent regeneration solution of anion exchange resin, on the other hand, increase the degree of regeneration of cation exchanger and increase the degree of desalination water by reducing the content of cations Mg ²⁺ , Na ⁺ .

 The use of the spent regeneration solution of anion exchange resin directly for the regeneration of cation exchange resin, the combination of deep softening processes of spent regeneration solutions of cation exchange resin and the removal of volatile components greatly simplifies the process of desalination of water.

 In addition, the elimination of the stage of processing the spent regeneration solution of anion exchange resin, the use of washing water of anion exchange resin to wash the cation exchange resin from the regenerating agent leads to a reduction in energy consumption.

 The desalination of water according to the proposed method is presented in the drawing, where 1 cation exchange resin and 2 anion exchange filter; 3 deaerator; 4 - absorption column; 5 and 6 containers; 7 and 8 devices, respectively, for heat treatment (7) and concentration (8).

 The method is as follows.

 The source water is sequentially filtered through cationite 1 and anionite (2) filters. Ionized water enters the deaerator 3. Volatile products from the deaerator are absorbed by the water in the absorption column 4, and desalted water is sent to the consumer.

At the stage of NH ₄ cationization of water (1), there is an exchange of metal cations contained in it for an NH ₄ ⁺ ion. The cation exchange filter is turned off and regenerated when sodium ions pass through (1 mEq / l).

 Anions of strong acids are extracted from water during its filtration through anion exchange resin (2) in bicarbonate form. When passing through the filtrate of Cl-ions (0.5 mEq / L), the anion exchange resin is removed for regeneration.

Carrying out the final technological operation of deaeration of NH ₄ - HCO ₃ -ionized water by heating in a deaerator (3) allows to obtain desalted water and a reagent for the regeneration of anion exchange resin ammonium salt. Desalted water with an average ion content, mEq / L: Na ⁺ - 0.08 0.10; hardness 0.04 0.06, including Mg ²⁺ 0.02 0.03; Cl ^- 0.12 0.16 and a salinity of 6.7 8.9 ml after the deaerator (3) is sent to the consumer. The unstable carbon-ammonium salt decomposes upon heating to form NH ₃ and CO ₂ . Gaseous volatile products are absorbed by water in the adsorption column 4. An additional amount of carbon dioxide is introduced into the system to obtain the carbon ammonium salt in the form of ammonium bicarbonate. The resulting solution is sent to a container 5 and then used to regenerate the anion exchange resin.

 The regeneration of cation exchange resin is carried out sequentially with a salt concentrate obtained by processing the spent regeneration solutions of cation exchange resin of the previous water desalination cycle, and the spent regeneration solution of anion exchange resin containing carbon ammonium salts and ammonium salts of strong acids.

The solution of the salt concentrate worked out as a result of the regeneration of cation exchanger is treated with an alkaline reagent (alkali metal hydroxide) to a pH of 10.5 to 12.0 in a tank 6. In this case, the solution is softened by removing magnesium ions in the form of poorly soluble magnesium hydroxide and depending on the composition of the initial water (calcium content) partial removal of calcium ions in the form of calcium sulfate. After separation of the precipitate, the spent solution of the salt concentrate is mixed with the spent regeneration solution of anion exchange resin passed through the cation exchange resin during its regeneration, washing water is added, and the mixture is processed by heat treatment 7 with absorption of volatile components (CO ₂ , NH ₃ ) with water and concentration of the liquid phase after NH ₃ removal and CO ₂ using one of the known methods (evaporation, electrodialysis) [8] to obtain a salt concentrate used to regenerate cation exchange resin in the next water desalination cycle.

 When mixing the spent regeneration solutions of cation exchange resin and subsequent heat treatment of the mixture, it is further softened due to the formation of a poorly soluble precipitate of calcium carbonate. After separation of the precipitate before concentration of the liquid phase, excess alkalinity is removed by neutralizing the solution with acid to pH 5. The solution can also be neutralized after the concentration step.

The regeneration of anion exchange resin is carried out with a solution of carbon ammonium salt obtained by the absorption of volatile components (NH ₃ , CO ₂ ) with water from the stages of processing spent regeneration solutions of cation exchange resin and the stage of water deaeration. The use of the entire amount of carbon ammonium salt formed during NH ₄ ⁺ HCO ₃ ^- ionization of water and the processing of spent regeneration solutions of cation exchange resin to restore the capacity of anion exchange resin allows increasing the depth of regeneration of anion exchange resin without additional costs, which, in turn, leads to an increase in the degree of water desalination for by reducing the average concentration of chloride ions in demineralized water.

 Characterization of materials and reagents used in the desalination of water: sodium hydroxide GOST 11078 78; potassium hydroxide GOST 9285 78; carbon dioxide GOST 8050 76; anion exchange resin AB 17 8 GOST 20301 74; KU 2 8 cation exchanger GOST 20298 74.

An example of a specific implementation. Ion containing water was desalted, mEq / L: Ca ²⁺ 6.4; Mg ²⁺ 1.6; Na ⁺ 4.0; HCO ₃ ^- 6.0; Cl ^- 3.0; SO ₄ ² 3.0 and free carbon dioxide 1.20 mmol / L.

Water of the specified composition was filtered through cation exchange resin (KU 2 resin in NH ₄ form). When slipping into the sodium ion filtrate (1 mEq / l), the filter was turned off for regeneration.

The anions of strong acids, water is removed by filtration NH ₄ ^- - kationirovannoy water through the anion exchanger AB 17 HCO ₃ ^- form. Anion exchange resin was turned off for regeneration when a breakthrough into the filtrate of 0.5 mEq / l of chloride ions.

The volume of ion exchangers was, cm ³ : cation exchange resin 66; anion exchange resin 82.

 As a result of sequential cationization and anionization, 6 L of water was treated.

Then it was heated to 100 ^o C. After distillation of volatile components (ammonia, carbon dioxide), desalted water containing ions was obtained, mEq / l: Na ⁺ 0.09; Ca ²⁺ 0.02; Mg ²⁺ 0.03; Cl ^is 0.14. The average salinity of demineralized water is 7.8 mg / L.

Volatile components were absorbed by water mixed with the spent solution of the previous regeneration and a solution was obtained with a volume of 100 ml of the following composition, mmol / l: NH ₃ 1080; CO ₂ 1080.

Anion exchange resin was regenerated with 100 ml of the resulting solution of volatile components (carbon ammonium salt) with concentrations, mmol / l: NH ₃ 1080; CO ₂ 1080. The filter was washed with 220 ml distilled water. The spent regeneration solution of anion exchange resin and water are washed, respectively, used for the regeneration and washing of cation exchange resin. The process was carried out without breaking the flow between anion exchange and cation exchange filters.

Cation exchange resin was regenerated sequentially with a solution of a salt concentrate with a volume of 200 ml of the following composition, mEq / l: Na ⁺ 957; Ca ²⁺ 1.0; Mg ²⁺ 2.0; Cl ^- 84,6; SO ₄ ² 114 and spent 100 ml of anion exchange resin regeneration solution. Then, cation exchange resin was washed with 220 ml of anion exchange resin water. The spent salt concentrate with a volume of 220 cm ³ and the mixture of the spent anion exchange resin solution passed through cation exchange resin and washing water were collected separately. The salt concentrate spent on the regeneration of cation exchanger was treated with 3.1 ml of a sodium hydroxide solution with a concentration of 3000 mmol / L to a solution pH of 12.0, and after separation of the precipitate, it was mixed with the spent anion exchange resin that was passed through the cation exchanger during its regeneration and washing water. The mixture was processed by heat treatment, heating to 100 ^o C. Volatile components (ammonia, carbon dioxide) were trapped in water and the solution was collected in a container containing a solution of carbon ammonium salt from the stage of deaeration of water. After a repeated desalination cycle of 6 l of water, its deaeration and absorption of volatile components, 100 ml of a solution of carbon ammonium salt containing mmol / l were obtained: NH ₃ 1080; CO ₂ 1080, which was used to regenerate the anion exchange resin in the next water desalination cycle.

After distillation of the volatile components (CO ₂ , NH ₃ ), the mother liquor is sedimented, the precipitate is separated, the liquid phase is concentrated by evaporation and neutralized with hydrochloric acid to pH 5. The costs of hydrochloric acid are 11.8 mEq / L. Get 234 ml of a concentrate of salts of the following composition, mEq / l: Na ⁺ 957; Ca ²⁺ 1.0; Mg ²⁺ 2.0; Cl ^- 846; SO ₄ ^{2 -} 114. 200 ml of the concentrate was used to regenerate cation exchange resin in the next water desalination cycle, and the residue was discarded.

 Indicators of water quality and specific volumes to be processed spent in the regeneration of ion exchange solutions for desalting water according to the proposed method, depending on the quality of the source water are presented in the table.

 It follows from the table that, regardless of the content of salts, bound and free carbon dioxide in the source water, the ratios of cations (sodium ions and hardness ions) and anions (strong acid anions and carbonic acid anions), the degree of desalination of water by reducing the content of magnesium and sodium ions , chloride ions increased and the specific volumes of spent regeneration solutions, which determine the energy consumption of the process, are reduced. So, the salinity of demineralized water is reduced by 2.0 2.3 times, and due to the decrease in the content of magnesium cations by 2.7 3.5 times (which is especially important when preparing water for medium-pressure boilers in the power system), sodium 2.1 2.4 times, chloride ions in 2.0 2.3 times, and the volume of spent regeneration solutions, and therefore the energy consumption for their processing reduced by 1.1 times.

 The use of a spent regeneration solution of anion exchange resin for the regeneration of cation exchange resin eliminates the stage of its processing, which reduces energy consumption and greatly simplifies the process of water desalination.

 When desalting water according to the proposed method, it is possible to reduce the consumption of reagents (alkali metal hydroxide) by using spent regeneration solutions of stage II anion exchange resin as an alkaline reagent for the case when the desalination scheme according to the proposed method is a scheme of a water preparation stage in a general two-stage scheme for producing demineralized water for production needs.

Claims (2)

1. A method of desalting water, including NH ₄ cation and HCO ₃ anionization, deaeration of water after ionization by heating with absorption of volatile components by water, regeneration of cation exchange resin, processing of the spent regeneration solution of cation exchange resin by heat treatment with absorption of volatile components by water and concentration of the liquid phase to obtain a salt concentrate, regeneration of anion exchange resin by a solution obtained by the absorption of volatile components by water from the stages of water deaeration and heat treatment of the spent regeneration solution ra cation exchanger, characterized in that, in order to increase the degree of desalting by lowering the content of ions Na ^+, Mg ^{2 +,} Cl ^+, reduce power consumption and simplify the process of cation exchanger regeneration is performed sequentially concentrate salts and spent regenerant anion containing ugleammoniynye salt and ammonium salts of strong acids, a salt concentrate is obtained by concentration of the liquid phase after heat treatment of a mixture of spent regeneration solutions of cation exchange resin obtained by its regeneration with the indicated agents, moreover, the salt concentrate worked out during the regeneration of cation exchanger is preliminarily processed with an alkaline reagent.  2. The method according to claim 1, characterized in that the alkali metal hydroxides are used as the alkaline reagent.

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