RU45995U1 - WATER TREATMENT PLANT - Google Patents

Abstract

The utility model relates to the field of industrial water treatment for technical purposes, in particular, for water heating equipment of boiler houses and cogeneration plants. The treatment consists in chemical purification of water by the ion-exchange method. The technical solution is aimed at reducing the cost of the regeneration of filters by reducing the consumption of salt and the volume of pumped solution. The water treatment plant contains Na-cation exchange filters connected to pipelines for supplying and discharging water, and a filter regeneration system. What is new is that in the regeneration system the filters are interconnected by jumpers with valves so that the washing water of one filter can be fed to the loosening of another filter. The system contains a measuring tank with an aqueous reagent solution, connected by pipelines to filters. The measuring tank is installed above the level of the filters and is equipped with an indicator of the level of the liquid in it. The level gauge is graduated in the form of a scale. The scale contains labels corresponding to portions of the supplied solution at various concentrations, for example, at a reagent concentration of 8, 9.1 0 wt.% In solution.

Description

The utility model relates to the field of industrial water treatment for technical purposes, in particular, for water heating equipment of boiler houses and cogeneration plants. The treatment consists in chemical purification of water by the ion-exchange method.

A known method of water purification [1], including a set of technological processes. The ultimate goal of operations is to bring the quality of the water entering the water supply network from the water supply source to the indicators established by the standards.

Also known is the technology of water purification in water treatment plants designed to soften water [2]. At the plants, water is chemically treated by ion exchange. The water treatment plant consists of Na-cation exchange filters connected to pipelines for supplying water from a water supply source and for withdrawing softened water to a consumer.

Due to ion exchange in the filters, the water pumped through them is softened. Periodically, filter regeneration is required, as The ion exchange process worsens and filtering properties are lost. The regeneration of the filters is carried out with a solution of sodium chloride (NaCl), pumping it through the filters. A typical process of chemical water purification in a Na-cathonite filter consists of the following repeating operations: water softening, loosening of the filter material, regeneration of the filter material, and washing of the filter material.

The salt consumption for the preparation of the regeneration solution can be 150-375 kg / m ^{3 of} water [2], depending on the degree of mineralization of the treated water. Various methods are known for reducing salt consumption for the regeneration of Na-cationic filters in water treatment plants: counter-current and step-counter-current regeneration, reuse of the spent salt regeneration solution, heating the salt regeneration solution with softened water, and cation exchange resin regeneration with increasing concentration.

The objective of the claimed utility model is to reduce the cost of the regeneration process by reducing the consumption of salt and the volume of pumped solution.

To solve the problem, the design of the water treatment plant has been amended to allow the use of a washing solution of one filter for the operation of loosening the filter material in another filter.

The essence of the utility model is as follows.

The water treatment plant contains Na-cation exchange filters connected to pipelines for supplying and discharging water, and a filter regeneration system.

What is new is that in the regeneration system the filters are interconnected by jumpers with valves so that the washing water of one filter can be fed to the loosening of another filter. The regeneration system contains a measuring tank with an aqueous reagent solution, connected by pipelines to filters. The measuring tank is installed above the level of the filters and is equipped with a level indicator, graduated in the form of a scale. The scale contains labels corresponding to portions of the supplied solution at various concentrations, for example, at a reagent concentration of 8, 9, 10 wt.% In solution.

The drawing shows the claimed Water treatment plant with a filter regeneration system.

The installation consists of filters 1 and 2 and pipelines connected to them with valves 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 and 13. A measuring tank 14 with a water measuring tube 15 is installed above the filters. Arrows A and A ₁ indicates the direction of the raw water supply. Arrows B and B ₁ indicate the direction of discharge of water used to loosen the filter material. The arrows C and C ₁ indicate the direction of the exit of chemically purified water or the exit of the wash solution after regeneration of the filter.

Installation works as follows.

The chemical water treatment workflow can take place on filter 1 or filter 2, or simultaneously on both filters. In the first case, valves 4, 10 and 12 are open, the rest are closed. In the second case, valves 7, 11 and 13 are open, the rest are closed. In the third case, valves 4, 7, 10, 11, 12 and 13 are open, the rest are closed.

The regeneration of the filters is as follows.

We start the process with filter 1. The first operation is the loosening of the filter material. To do this, open the valves 7, 11, 9, 10 and 3, the rest should be

closed. In arrow A ₁ , water is supplied, which sequentially passes through open valve 7, filter 2, valves 11, 9, 10 and countercurrently moves upstream of filter 1. Having passed the filter, water is discharged through valve 3 from the pipeline in the direction of arrow B.

After loosening, they proceed directly to the regeneration. All valves close and open one valve 5. In this case, from the measuring tank 14, a solution of sodium chloride (regeneration solution) flows by gravity into the filter 1. Since the water supplied for loosening must leave the filter, the valve 12 is opened for the time necessary to completely fill the filter with regeneration solution. The solution is left in the filter 1 for several hours until the filter properties are completely restored.

In the next step, two operations are performed simultaneously: washing the filter material in the filter 1 and loosening in the filter 2. To do this, open the valve 4 for supplying washing water to the filter 1 (arrow A). The valves 10, 11, 8 and the valve 9 located on the jumper between the filters are also opened. In this case, the wash water displaces the regeneration solution into the filter 2. The regeneration solution has a still rather high salt concentration. It enters the filter 2 from the bottom upstream, loosening the filter material. Simultaneously with loosening, regeneration of the filter material by NaCl ions occurs. The economic effect is due to the fact that the spent regeneration solution is not thrown out of the installation to the outside, as provided for by the current standard rules, but is used again productively. The solution is fed into another filter, where it not only loosens the filter material, but also carries out its partial regeneration. This allows significant salt savings during filter regeneration.

Thus, the process of filter regeneration 1 ends. With open valves 4, 10 and 12, a regular process of chemical water purification takes place on the filter. Untreated water enters the pipeline in arrow A, and chemically purified water comes out at the outlet of the filter from the pipeline in arrow C, ready for use.

At this time, on the filter 2 with the closed valves 5 and 9, the regeneration process continues, similar to the above process on the filter 1: from the measuring tank 14 into the filter 2 the regeneration solution is poured (first open

gate valves 6, 11 and 13, and 7 and 8 are closed; then, with closed valves, the filter is treated with regeneration solution). After regeneration, the solution is fed with the length of the loosening of another filter. To ensure the continuity of the chemical water treatment process, it is necessary to have a unit of several filters connected by jumpers on the installation. Then it will be possible to provide continuous water purification and consistently carry out the regeneration of filters, effectively using a regeneration solution.

Installation of the claimed design was made and tested in operation at the boiler room of a large industrial enterprise. Over 700 tons of salt were saved per year.

Sources of information:

1. Soviet encyclopedic dictionary. M., "Soviet Encyclopedia", 1983, p.232.

2. Bych E.S. Reuse of salt solutions for filter regeneration. The journal "Industrial Energy" No. 1, 1987, S. 21-22 - prototype.

Claims (6)

1. A water treatment plant containing Na-cation exchange filters connected to pipelines for supplying and discharging water, and a filter regeneration system, characterized in that in the regeneration system the filters are connected by jumpers with valves so that washing water of one filter can be supplied to loosening another filter. 2. Installation according to claim 1, characterized in that the system comprises a measuring tank with an aqueous reagent solution connected by pipelines to filters. 3. Installation according to claim 1, characterized in that the measuring tank is installed above the level of the filters. 4. Installation according to claim 1, characterized in that the measuring tank is equipped with a level indicator. 5. Installation according to claim 3, characterized in that the level gauge is graduated in the form of a scale. 6. Installation according to claim 4, characterized in that the scale contains labels corresponding to portions of the supplied solution at different concentrations, for example, at a reagent concentration of 8-10 wt.% In solution.