UA18984U - Method for two-stage deaeration of water - Google Patents

Abstract

A method for two-stage deaeration of water comprises desorption of corrosion-active gases, which is carried out at first by thermal treatment of water with subsequent discharge of a part of corrosion-active gases after the thermal water treatment. At the second stage desorption is carried out by chemical absorption of oxygen dissolved in water by bonding oxygen dissolved in water with transition metals, which are in reduced form in complex ionite radical undissolved in water.

Description

Description of the invention

The method refers to multi-stage methods of water preparation, for example, for thermal power 2 equipment, by deaeration and deoxygenation of water, for which a combination of treatment stages is an essential characteristic.

A known method of two-stage processing, in particular of industrial water | see Russian patent Mo2240986, IPC

СО2Е3/00, date of publication of the application 27.11.2004), according to which water is passed through a porous medium containing a transition metal, fed into an instant degassing tank, and the resulting partially deaerated water is treated with 70 ozone. In this method, palladium is used as a transition metal.

Implementation of the method in connection with the low concentration of the transition metal requires equipment of significant dimensions. The use of palladium as a transition metal in the method leads to significant material costs. Water treated by this method contains a significant amount of ozone, which leads to accelerated corrosion of thermal power equipment. 15 A known method of two-stage deaeration of water | see application for the invention of Russia Mo2004135791/15, IPC СО2Е1/20, date of publication of the application 2006.05.061), according to which the desorption of dissolved corrosive-active gases is carried out first in a vacuum deaerator, the vapor formed is removed through the vapor removal pipeline, the deaerated water is removed to the tank accumulator of the vacuum deaerator, then the water is deaerated in the high-pressure deaerator, the deaerated water is taken to the accumulator tank of the high-pressure deaerator. 20 Implementation of the method requires equipment of large dimensions, which works in a complexly regulated technological mode, requires the use of additional equipment for creating a vacuum, associated with the laboriousness of operating the installation according to the method.

The task of the development is to create a method of two-stage water deaeration, in which, through empirically selected treatment operations, modes of their execution, and applied reagents, a reduction in the dimensions of the equipment is ensured, as well as a simplification of the process of managing the water treatment method. -at

To implement this task, the method of two-stage deaeration of water involves the desorption of corrosive-active gases, first by thermal treatment of water, followed by removal of part of the corrosive-active gases after thermal treatment of water.

What is new in the method is that the second stage of desorption processing is carried out by chemical absorption of C 30 oxygen dissolved in water by binding oxygen dissolved in water with transition metals that are in a reduced form in a water-insoluble complex ionite radical.

Due to the use of new features of the method along with known ones, the implementation of the method in the equipment does not require the use of large-sized equipment such as a deaerator, which operates at the limit of the boiling point of water, i.e., a complexly regulated technological mode. The implementation of the method also does not require the use of additional 35 equipment to create a vacuum, and is not related to the complexity of operating the installation according to the method. --

In specific variants of the implementation of the method, the heat treatment of water before binding the oxygen dissolved in the water is carried out to a temperature of 55-6520.

As a result of the application of such features of the method, the two-stage water deaeration process is optimally divided into two stages, as a result of which the capacities and dimensions of the equipment for the implementation of these 373 stages are minimized, and the reduction of the water heating temperature from 99 to 55-6592С significantly reduces the energy costs for the implementation of the necessary water deaeration . :z» In specific variants of the implementation of the transition metal quality method, which is in a reduced form in the water-insoluble complex ionite radical, Ge is used.

Use in the method as a transition metal, which is in a reduced form in the water-insoluble complex radical ionite Ge, simplifies the implementation of the method and reduces costs for the recovery of the transition metal. (ee) In specific variants of the method, the second stage of desorption is carried out cyclically depending on the content of oxygen dissolved in water after the second stage of desorption and when the content of dissolved oxygen in water increases by more than 5 Ohmkg/l, the second stage of desorption is suspended to replace or restore the transition metal, that (ee) 50 is in the reduced form in the water-insoluble complex ionite radical.

T» The application of such new features of the method in certain specific variants of the application optimizes the process of recovery of the transition metal used in the method.

In specific variants of the implementation of the method, the second stage of desorption is carried out cyclically depending on the content of oxygen dissolved in water after the second stage of desorption, and when the content of oxygen dissolved in water exceeds the maximum permissible level, the filtration rate of the processing water is reduced to the level at which recovery of the transition metal present in treated water with organic impurities and sodium salts.

The application of such new features of the method in certain specific variants of the application ensures the recovery of the transition metal used in the method in the process of water treatment by using organic impurities and sodium salts present in the treated water, which further simplifies the implementation of the method.

The method is illustrated by an example of its implementation.

At the first stage of deaeration, the water is first heated, for example in a water-water heat exchanger, with non-contact heat transfer through a heat transfer surface. After passing through the heat exchanger, the water is heated to a certain temperature (602), and as a result of the decrease in the solubility of gases, conditions are created for their desorption, which is carried out in the coarse degassing unit. A closed container is used as a coarse degassing unit, the upper part of which contains a pipeline for discharging gases into the atmosphere. A significant part of the corrosive-active gases from the coarse degassing unit are discharged into the atmosphere with the help of the indicated pipeline after the thermal treatment of the water.

The second stage of processing is based on the chemical method of absorption by binding oxygen dissolved in water with transition metals in a reduced form. At the same time, as a result of oxidation-reduction processes occurring in the filter through which water is passed, the metal in the filter with variable valence is transferred into oxidized form. The resin "ZY-2-8" is used as the specified sorbent, which has a fairly high oxygen absorption capacity. The sorbent uses an ionite complex with a transition metal introduced into the ionite phase.

The process of chemical absorption of oxygen, which is carried out at the second stage, can be represented in the form of the following equation:

K.Mevidn7OotiNgO-» KeMe(ON) tou; where K is a water-insoluble complex ionite radical;

Me is a transition metal.

In specific variants of the implementation of the method, He is used as a transition metal that is in a reduced form in a water-insoluble complex ionite radical.

As the water filters through the transition metal layer, more and more of it will change into an oxidized form, accordingly, the content of oxygen dissolved in the treated water will increase. | when the content of oxygen dissolved in water exceeds 5 Ωkg/l, the second stage of desorption is suspended to replace or restore the transition metal, which is in a reduced form in the water-insoluble complex ionite radical.

The regeneration process to restore the absorption capacity can be carried out by passing a reducing agent solution, for example, sodium thiosulfate, through a layer of filter material:

K.Me(OH)z-Ma»5205-»KeMe(OH)opMma»zOdtnNoo, where K is a water-insoluble complex ionite radical; WITH

Me is a transition metal.

After passing the regeneration solution, the filter material layer is washed from excess reagent and regeneration products, for example by passing water from top to bottom, after which the second stage of desorption is restored. And co

Claims (2)

The formula of the invention by F 1. The method of two-stage deaeration of water, which includes the desorption of corrosive gases, which is carried out firstly by heat treatment of water, followed by the removal after heat treatment of water of part h of corrosive gases, which is distinguished by the fact that at the second stage, desorption is carried out by chemical absorption of dissolved in to water oxygen by binding oxygen dissolved in water with transition metals that are in a reduced form in the water-insoluble complex ionite radical. " 2. The method according to claim 1, which differs in that the thermal treatment of water is carried out to a temperature of 25-65260 before binding the oxygen dissolved in the water. - c C. The method according to claim 1, which differs in that Ge is used as a transition metal that is in a reduced form in a water-insoluble complex ionite radical. "» 4. The method according to claims 1, 2, which is characterized by the fact that the second stage of desorption is carried out cyclically depending on the content of oxygen dissolved in water after the second stage of desorption and when the content of oxygen dissolved in water exceeds 50 μg/l, the second stage of desorption suspended to replace or restore the transition metal, which is in a reduced form in the water-insoluble complex ionite radical. co 5. The method according to claims 1, 2, which differs in that the second stage of desorption is carried out cyclically depending on the content of oxygen dissolved in water after the second stage of desorption and when the content of oxygen dissolved in (se) water exceeds the maximum allowable limit, reduce the filtration rate of the treated water to the level at which recovery of the transition metal by organic impurities and sodium salts present in the treated water is ensured by so 50. c" Official Bulletin " Industrial property". Book 1 "Inventions, useful models, topographies of integrated microcircuits", 2006, M 11, 15. 11.2006. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. p. 60 b5