RU2121873C1 - Method of water purification by ion exchange with counterflow ion exchanger recovery and device for its realization - Google Patents

Abstract

FIELD: purification of water and aqueous solutions by ion exchange. SUBSTANCE: device has a housing, layer of floating inert material, cylindrical partition coaxially installed in the housing with formation of free space between the layer of inert material and partition edge, main layer of ion exchanger located in the annular space between the housing and cylindrical partition, and an auxiliary layer of ion exchanger located inside the latter, water to be purified is fed by two flows. The first flow is directed upwards to the auxiliary layer of ion exchanger, transferred to the free space above the main layer, and then jointly with the second flow it is passed through the main layer downwards. EFFECT: protection of the main layer of ion exchanger against its pollution by suspended particles. 4 cl, 1 dwg

Description

 The invention relates to techniques for purifying water and aqueous solutions from impurities in the form of ions using ion exchange materials, ion exchangers, and can be used in ion exchangers used in the energy, chemical, food and other industries.

 The most economical way to remove dissolved impurities from water is the countercurrent ionization method, which consists in the fact that the source water and a solution of the reagent periodically introduced to restore the exchange capacity of the ion exchangers are fed into the filter in opposite directions. The use of countercurrent during ion exchange can significantly reduce the reagent consumption and improve the quality of purified water.

 To implement this technology, it is necessary to fulfill the basic requirements - ensuring the stillness of the ion exchanger layer when the reagent solution is supplied in the direction from the bottom up, the presence of free space in the filter to change the volume of the ion exchanger during the transition from one form to another during operation, as well as the possibility of periodic washing with the purpose of removing dirt and fines from the upper layer of ion exchanger.

 A known method of regenerating ion exchanger in a countercurrent ion exchanger filter, including loosening the ion exchanger layer and the blocking layer with washing water, supplying the reagent solution through the ion exchanger layer from the bottom up, and hydraulic clamping of the blocking layer by introducing the spent reagent solution into the upper part of the filter. The countercurrent ion exchange filter for regeneration of the ion exchange resin in this way consists of a housing, upper, lower and middle prefabricated distribution devices installed in it, fittings for supplying and discharging the source, purified and flushing water, as well as supplying and discharging a reagent solution. A plate with holes and reflectors is installed between the upper and middle collecting and distributing devices in order to reduce energy consumption and hydraulic clamping of the blocking layer during countercurrent regeneration of ion exchange resin. In this case, the free space in the filter is 70 - 100% of the volume of the ion exchanger loaded into the filter to provide loosening washing of the ion exchanger [USSR Author's Certificate N 1111815, 1993].

 The disadvantage of this method and the corresponding device is the complex design of the filter due to the presence of an average assembly and distribution device and a plate with holes and reflectors from expensive anti-corrosion materials, which leads to a decrease in maintainability and reliability of the device, an increase in the abrasion of the ion exchanger during the loosening washing of the latter, increase in hydraulic resistance during ionization of the source water.

 The closest technical solution is a method of countercurrent regeneration of ion exchange resin and a device for its implementation, which includes the supply of source water and a reagent solution periodically introduced to restore the exchange capacity of the ion exchange resin in opposite directions.

 The counterflow filter device consists of a housing, upper and lower prefabricated distribution devices installed in it, fittings that supply and discharge the source and purified water and the regeneration solution.

To prevent clogging of the slots of the assembly and distribution device in small fractions of ion exchanger during regeneration, a layer of inert material with a particle size distribution of at least 1.5 mm and a density of less than 1 g / cm ^{3 is} provided.

 Between the layer of ion exchanger loaded into the filter and the layer of inert material, free space is provided.

 The immobility of the ion exchanger when feeding the regeneration solution in the direction from the bottom up is ensured by the hydraulic method due to the preliminary raising and compaction of the ion exchanger layer to the inert material layer with a strong stream of purified water in the direction from the bottom up with a flow rate of 4 to 5 times the flow rate of the regeneration solution.

 Washing of the top layer of ion exchanger from dirt and fine fractions is carried out simultaneously with regeneration [Prospect of the Dow Chemical Company (USA). "The APCOR process. Countercurrent regeneration of ion exchange resins: a progressive technology that improves quality and reduces the cost of process water." 1993] - a prototype.

 With the obvious simplicity of the counterflow filter design, the disadvantages of this counterflow ion exchange regeneration method are the need for an additional pump to create a strong flow of purified water during preliminary compaction of the ion exchange resin layer before its regeneration, as well as increased diameters of pipelines providing regeneration supply and removal of spent regeneration solutions.

 The aim of the invention is to increase the efficiency and simplify the operation of a device with countercurrent regeneration of ion exchange resin.

 This goal is achieved by the fact that in the method of water purification by ion exchange with countercurrent regeneration of ion exchange resin, including the supply of source water through the layer of ion exchange resin from top to bottom, its periodic countercurrent regeneration and simultaneous washing of the contaminated upper layer of ion exchanger, from the bottom up supply of a regeneration solution, a distinctive feature is that the entire volume of the ion exchanger is divided into the main and auxiliary layers, over which provide free space 5 - 50% less than the volume in the auxiliary layer of ion exchanger, while the supply of the source water is carried out in two streams, one of which is supplied from the bottom up to the auxiliary layer of the ion exchanger, to displace it into the free space in order to protect the main layer of the ion exchanger from contamination by suspended solids present in the initial water, then together with the second flow through the main layer of ion exchanger from top to bottom. In this case, 20 - 70% of the total flow rate of the source water enters through the auxiliary layer of ion exchanger.

 The main layer of ion exchanger is pressed during its periodic regeneration in the upward direction by the hydromechanical method by supplying the initial water or spent regeneration solution to the auxiliary exchanger layer in the upward direction to displace it into the free space, while the contaminated auxiliary ion exchanger layer is washed and regenerated.

 In addition, the goal is achieved by the fact that in a device for water purification by ion exchange with countercurrent regeneration of ion exchange resin containing a filter housing, installed in it upper and lower collecting and distribution devices, fittings for supplying and discharging the source and purified water and regeneration solution, as well as an inert material layer located under the upper collection and distribution device, an ion exchanger layer, free space between the ion exchanger layer and the inert material layer, a distinctive feature is t about that inside the filter housing along its axis a cylindrical partition is installed, the cross-sectional area of which is 3-30% of the cross-sectional area of the filter and dividing its volume into peripheral and central chambers filled to the height of the cylindrical partition by the main and auxiliary layers of ion exchanger, the lower part of the cylindrical the septum is equipped with a switchgear and hermetically connected to the feed water supply fitting, while between the upper end of the cylindrical septum and the inert material layer Free space is envisaged, the volume of which is 5-50% less than the volume of the central chamber.

 The alleged invention is illustrated by the drawing, which shows a device for purifying water by ion exchange with countercurrent regeneration of ion exchange resin.

 The device comprises a filter housing 1, distribution and distribution devices, respectively, upper 2 and lower 3. A cylindrical partition 4 is installed inside the housing along the filter axis, dividing the filter volume into peripheral 5 and central 6 chambers, completely filled to the height of the partition 4 by the main and auxiliary layers of ion exchangers, respectively . The lower part of the cylindrical partition 4 is equipped with a switchgear 7 and is hermetically connected to the supply pipe of the source water or the spent reagent solution 8.

Under the upper collection and distribution device 2, a space 9 is provided for filling with an inert material with a particle size distribution of at least 1.5 mm and a density of less than 1 g / cm ³ . Between this space 9 and the upper end of the cylindrical partition 4 there is a free space 10, the volume of which is 5-50% less than the volume of the central chamber 6.

 The purified water is discharged through the nozzle 11, which also serves to supply the regeneration solution, and the nozzle 12, which also serves to supply part of the source water during its purification, serves to drain the spent reagent solution.

Example
When cleaning part of the source water through the nozzle 8, the switchgear 7 enters from the bottom up to the central chamber 6, forcing the auxiliary ionite layer out of it into the free space 10, then, together with another stream of the source water entering through the nozzle 12, is filtered from top to bottom through the main layer ion exchange resin located in the peripheral chamber 5. Purified water is discharged from the filter through the lower collection and distribution device 3 and then through the nozzle 11. Since the cross-sectional area of the central chamber is 3 - 30% of the area echeniya filter, the flow rate in the central chamber exceeds 1.5 - 3 times the flow velocity in the peripheral chamber, the latter of which is 3 - 15 l / s • m ^2. Due to this difference in flow rates, the auxiliary layer of ion exchanger from the central chamber 6 is displaced into the free space 10, forming the upper layer above the main layer of ion exchanger, protecting the latter from contamination by suspended solids. When the exchange capacity of the ion exchanger is depleted, the filter is turned off for regeneration. In this case, the auxiliary layer of ion exchanger under the influence of gravity from the free space 10 settles and fills the Central chamber 6 of the filter.

During the regeneration, for example, of ion exchange grade AB-17-8, a 4% sodium hydroxide solution is introduced into the lower collection and distribution device 3 through the nozzle 11, which is passed through the main layer of anion exchange resin in the peripheral chamber in the direction from the bottom up at the speed of solution 1, 4 - 1.5 l / s • m ² . The spent alkali solution is removed from the filter through the upper collection and distribution device 2 and then through the nozzle 12. The main layer of anion exchange resin is clamped hydromechanically. To do this, pre-source water or spent reagent solution is supplied to the central chamber 6 of the filter through the nozzle 8 and the switchgear 7 with a flow rate of 8-15 l / s • m ² . Under the action of this flow of water, the anion exchange resin from the central chamber 6 is forced into the free space 10, completely filling it and ensuring the immobility of the main layer of anion exchangers. At the same time, dirt and small fractions of anion exchange resin are removed from the auxiliary layer. With further regeneration of the anion exchange resin, the flow rate of the initial water or the spent reagent solution is reduced to 3 - 7 l / s • m ² .

The size of the slots in the upper switchgear 2 is provided in the range of 0.4 - 0.6 mm, and protection against the removal of the working fractions of the anion exchange resin from the filter is ensured by the presence under the upper collecting and distributing device 2 of a layer of inert material 9 with a particle size distribution of at least 1, 5 mm and a density of 1 g / cm ³ .

The washing of the main layer of anion exchange resin from the reagent solution is carried out similarly to the process of regeneration with ionized water in the direction from the bottom up with a flow rate of 2 - 4 l / s • m ² and a flow rate of initial water of 4 - 8 l / s • m ² to displace the auxiliary layer of ion exchanger chamber into the free space to clamp the main layer of ion exchanger.

 In a water purification device by ion exchange with countercurrent regeneration, a uniform charge consisting of strongly acidic cation exchanger or strongly basic anion exchange resin or a two-layer charge consisting of strongly and weakly acid cation exchangers or strongly and weakly basic anion exchangers can be used.

 Thus, the use of a method of water purification by ion exchange with countercurrent regeneration in ionite filters allows you to protect the main layer of ion exchanger from contamination with suspended solids present in the source water during its purification, and also provides countercurrent regeneration of the main ion exchanger in a stationary state due to hydromechanical clamping method, which increases the cleaning efficiency and simplifies the operation of the filter.

Claims (4)

 1. A method of purifying water by ion exchange with countercurrent regeneration of ion exchanger, comprising purifying the source water through an ion exchanger layer from top to bottom, periodic countercurrent regeneration and simultaneously washing the contaminated top ion exchanger layer by applying a regeneration solution from the bottom up through an ion exchanger layer, characterized in that for protect the main layer of ion exchanger from contamination with suspended solids present in the source water, its supply is carried out in two streams, one of which is directed from bottom to top in the entire the help layer of ion exchange resin for displacement into the free space located above the main layer of ion exchange resin, then together with the second stream is passed from top to bottom through the main layer of ion exchange resin.  2. The method according to p. 1, characterized in that when cleaning the source water in the auxiliary layer of ion exchanger direct 20 - 70% of its flow. 3. The method according to claim 1, characterized in that the clamping of the main layer of the ion exchanger during countercurrent regeneration from the bottom up is carried out by the hydromechanical method by preliminary displacing the auxiliary layer of the ion exchanger from the bottom up to the free flow of water, where it is simultaneously washed and regenerated, while the initial flow rate through the auxiliary layer of ion exchanger is maintained in the range of 8-15 l / s • m ² , followed by a decrease to 3-7 l / s • m ² . 4. A device for purifying water by ion exchange with countercurrent regeneration of ion exchange resin, comprising a filter housing, upper and lower collecting and distributing devices installed therein, fittings for supplying and discharging initial and purified water and a regeneration solution, an ion exchange layer, an inert material layer with particle size distribution with a composition of at least 1.5 mm and a density of less than 1 g / cm ³ located under the upper collection and distribution device, as well as the free space located between the ion exchanger layer and the inert material layer, characterized in that a cylindrical partition is installed along the axis along the axis of the filter housing, the cross-sectional area of which is 3-30% of the cross-sectional area of the filter housing and dividing its volume into peripheral and central chambers filled to the height of the cylindrical partition by the main and auxiliary layers of ion exchangers, the lower part of the cylindrical the septum is equipped with a switchgear and hermetically connected to an additional nozzle for supplying the source water, while between the upper end of the cylindrical partition and a layer of inert material provides free space, the volume of which is 5-50% less than the volume of the central chamber.