SU1134234A1 - Method of regenerating two-section ion-exchanger - Google Patents

Abstract

1. METHOD FOR REGULATING TWO-INTAKE IONITE FILTER, including vyhlenie ionite, passing a regenerative solution simultaneously through an ion exchanger located in the central chamber, and ion exchanger placed in a peripheral chamber, subsequent washing of the ion exchanger with ionized water and discharging the last of the filter, characterized in that, in order to reduce heating and increasing the efficiency of the method, before washing, feed water is supplied to the peripheral chamber, ionized by passing through the upper layer of the ion exchanger, located Then, the stream of ionized water in it is divided into two streams, one of which is fed to the upper part of the central chamber, the other is passed through the lower layer of the ion exchanger into the peripheral tube and both streams are passed through the lower part of the filter. 2. Method POP.1, characterized in that the pressure in the filter water during washing is maintained not lower than 0.1 MPa, CO 4; ND CO

Description

The invention relates to a process for the purification of water and aqueous solutions using ion-exchange materials for ion exchangers from soluble ionized impurities and can be used in two-way ion-exchange filters used in industrial power engineering, chemical, food and other industrial sectors. A known method of regenerating iopite in a two-way or two-chamber filter, in which, after treatment with reagents, the ion exchanger is first washed with an ionized liquid in the same direction in which the regeneration solution is introduced, then the washing ionized liquid is fed in the opposite direction lj. The disadvantage of the known method is the high consumption of the ionized washing liquid, which makes it necessary to install bulky tanks for the storage of the ionized liquid. The closest to the proposed method is the regeneration of an ion-exchange two-way filter, including the supply of a regeneration solution to the central and peripheral chambers simultaneously, followed by washing of the ionized water, which is then diverted to the drainage. In a known method for washing an ion exchanger from regeneration products, ionized water is supplied from a tank, which is also used to power the deaerator during the filter 2 regeneration period. This allows a slight decrease in metal consumption and the manufacture of the tank, but does not eliminate the cost of fittings and pipelines connecting the tank to the filter. However, the positive water after the central chamber then flows into the peripheral chamber, from where through the middle distributor is diverted to the drainage. In this case, the ion exchanger placed in the lower part of the filter is in the stagnant one and its removal is extremely slow. This causes an excessive duration of the washing operation and the over-expenditure of ionized water for its own needs. The purpose of the invention is to increase the efficiency of the process by eliminating tanks for storing ionized water and reducing the duration of the process. This goal is achieved by the fact that according to the method of regeneration of a two-way ion-exchange filter, which includes passing the regeneration solution simultaneously through an ion exchanger located in the central chamber, the ion exchanger located in the peripheral chamber, followed by washing with ionized water and discharging the last of the filter, feed the stream to the peripheral chamber source water, ivive by passing through the upper layer of the ion exchanger located in it, then the stream of ionized water is divided into two streams, one of which is under They are placed in the upper part of the central chamber, the other is passed through the underlying layer of the ion exchanger in the peripheral chamber and both flows are discharged through the lower part of the filter. It is advisable to maintain the pressure of water in the filter during washing not less than 0 MPa. As the water pressure in the filter decreases below a specified value, the possibility of more ionized water entering the drainage through the peripheral chamber in addition to the central chamber increases. This pressure, equal to 0.1 Sh, is the sum of the required water pressure at the pump inlet (0.03-0.04 MPa), pressure loss to overcome local resistance in caps, fittings, fittings, pipelines (0.04-0 , 05 MPa) and the required margin (0.01-0.03 MPa). The specified water pressure in the filter (0.1 MPa) is created by opening the valve installed in the pipeline to the flush water outlet for the appropriate amount. The value of the upper pressure limit of water in the filter is determined by the pressure of the source water entering the filter by means of a pump and the allowable pressure of water in the filter, based on the conditions of its mechanical strength. The drawing shows a device for carrying out the method. The device consists of a two-way ion-exchange filter 1, a pump 2 for supplying source water for ionization and loosening of an ion exchanger, a pump 3 for supplying source water for regeneration. and washing the ion exchanger from the products of regeneration. The filter contains a cylindrical housing 4 with bottoms, a cylindrical partition 5, dividing the internal volume of the filter into a peripheral chamber 6, most of which is filled with an ion exchanger, and the central chamber 7, completely filled with an ion exchanger, a water cushion 8 in the peripheral chamber, prefabricated devices 9 and 10, installed respectively in the upper part of the peripheral chamber and the central chamber, the drainage-distributing device 11 with the caps 12, located in the middle part of the peripheral chamber, and the drainage distributor The device 13 is installed at the bottom of the filter. Pipe 14 is used to supply source water. Pipe 15 - for input of source water for loosening of ion exchangers, pipes 16 and 17 for regeneration and washing of ion exchangers, pipes 18-21 for supplying ionized water from the peripheral chamber to the central, pipes 22-24, respectively, for draining the spent reagent solution, rinsing and washing water . The device also contains an ejector 25 for sucking the concentrated reagent solution through pipe 26 and preparing a regeneration solution. An example of the method. The regeneration of an ion exchanger in a two-way countercurrent sodium 1.0 ion filter with a diameter of 1.0 m, loaded with cation exchange resin KU-2, is carried out as follows. Initially, the ion exchanger is loosened by supplying raw water in the amount of 4.0 m / h for 15 minutes by pump 2 through pipes 14, 15 and 19 to collecting and distributing device 11, which it passes through the cap 12 to the cationite layer and when moving from the bottom upwards, it is washed away from the contaminants and fines retained by it. The washing water through the collecting and distributing device 9 is removed to the drainage through the pipe 23. After the washing is completed, an 8% sodium chloride solution is passed through the collecting and distributing devices 9 and 10 simultaneously to collect the ionization capacity of the cation exchanger 1: 3-1: 4, as a result of which a hydraulic clamping of the cation exchanger layer in the filter is provided during regeneration. The removal of the spent sodium chloride solution together with the regeneration products is carried out through the caps 12, the collecting-distributing device 11 into the drainage through the pipe 22. The speed of the regeneration solution is 4 m / h. The duration of the pass regeneration solution 30 minutes An 8% sodium chloride solution is prepared using an ejector 25 from a 26% solution sucked through pipe 26 and feed water supplied by pump 3 through pipe 16. Extract the ion exchanger from the reagent solution to the regeneration products proiz. water by supplying raw water (for example, clarified by sodium cationation) in the amount of 4j8 by pump 3 through pipes 16 and 17 through the upper collecting and distributing device 9 to the peripheral chamber 6. The speed of movement of the wash water in the ion exchanger layer to the level of the caps 12 is maintained equal to 12 m / h, below the level of caps of 4.0 m / h. A part of the obtained ionized water, for example, cleared during sodium cationization, in an amount of 3.2, through the caps 12 of the middle collection switchgear 11, by pump 2 through pipes 18-21 and the upper collection switchgear 10 are introduced into the central chamber 7 The speed of movement of the washed ionized water in the central chamber is maintained at 8 m / h. The washing waters from the peripheral and central chambers are discharged into the drainage through the lower drainage distributor 13 and the pipe 24. The duration of the washing of the cation exchanger is 45 minutes. The water pressure in the filter during washing is maintained not lower than O, 1 MPa. Thus, using the initial water in the two-way filter for washing the ion, the part of which, after ionizing the filter in the peripheral chamber, is sent to the central (countercurrent) ion chamber for washing the ion exchanger, it completely eliminates the need for own needs and avoids installation of bulky tanks, i.e. to reduce the consumption of metal for their production, as well as for the installation of additional 51134234

fittings and piping zones, and due to this, it is reduced by removing the wash water by more than twice the length of the cut-off bottom of the filter, eliminates washing and, consequently, the flow of water with the possibility of stagnant washing.

Claims (2)

1. METHOD FOR REGENERATING A TWO-WAY IONINE FILTER, including loosening the ion exchanger, passing the regeneration solution simultaneously through the ion exchanger located in the central chamber, and the ion exchanger located in the peripheral chamber, subsequent washing of the ion exchanger with ionized water and removal of the latter from the filter, characterized in that, In order to shorten the duration and increase the efficiency of the method, before washing, a feed stream is fed into the peripheral chamber, ionized by passing through the upper layer. the ion exchanger located in it, then the ionized water stream is divided into two streams, one of which is fed to the upper part of the central chamber, the other is passed through the underlying layer of ion exchanger in the peripheral chamber, and both streams are solidified through the lower part of the filter. 2. The method according to claim 1, characterized in that the pressure. Water in the filter during washing support at least 0.1 MPa. > 11>