RU2758346C1 - Method for obtaining and selling alkaline water - Google Patents

Abstract

FIELD: alkaline water production.

SUBSTANCE: invention relates to the field of obtaining alkaline water and its sale using vending machines. The specified effect is achieved through the implementation of a method for the production and sale of alkaline water, including the disinfection of water and the oxidation of organic and organochlorine impurities in it by ozonation with recirculation, then its preliminary and fine purification, regulation of the degree of purification using a bypass line located parallel to the purification line, implementation the process of water electrolysis, which makes it possible to set a predetermined value of the pH of the catholyte, due to the coordinated regulation of the current strength of the electrolysis process and the flow of water, when taking a dosed portion of the catholyte at the outlet of the electrolyzer, removal of electrolysis products along the anolyte line, as well as along the catholyte line, directing it to the consumer, while the catholyte dispensing process is carried out along the dispensing line using dispensing or dosing equipment with the possibility of partial catholyte cutting off, and the dispensing line and container are made of materials that hydroxide ions.

EFFECT: obtaining alkaline water with specified parameters.

5 cl, 1 dwg

Description

The invention relates to the field of obtaining alkaline water and its sale using vending machines.

Currently, there are many ways known to prepare water for sale in vending machines. In most cases, this preparation is limited to water purification or purification and decontamination. So, for example, in vending machines, methods are widely used that have a cleaning and disinfection system (Product offer [Electronic resource] - URL: https://alivewater.ru/katalog/apparaty-pitevoj-vody (date of treatment 01/04/2021)). The disadvantages of these methods are the inability to regulate the properties of water, including its pH, and the limited options for delivering water to consumers.

There is also known a method of water preparation for retail vending machines, using coarse and fine filters, as well as an electrolysis device with a silver electrode, which makes it possible to obtain silver water with a given concentration of silver ions (RF patent for invention No. 2495496, IPC G07F 13/02). The disadvantage of this method is the impossibility of obtaining alkaline water.

The closest (prototype) in terms of the totality of essential features to the claimed invention is a method of preparing water for a vending machine, which has pre-filtration and ultrafine filtration of water, an electrolyzer for water treatment, with storage tanks for cation exchanger - alkaline water and anolyte - acidic water, which have water inlet and outlet for consumers, as well as a control system that includes a touch screen control (application WIPO 201910570779.3, publication number 110232780, IPC G07F 13/00, 09/13/2019). For pre-filtration, a membrane-type filter was used to separate mechanical impurities. For further water purification before the electrolysis process, a filter with granular activated carbon and KDF catalytic powder, which is an ultrafine filtration device, was used. The disadvantage of this method is the lack of a device for disinfecting the water entering the apparatus and the impossibility of obtaining and dispensing alkaline water with the specified parameters.

The task to be solved of the claimed invention is to eliminate the disadvantages of the above technical solution and achieve a technical result in relation to:

- disinfection of water entering the apparatus and oxidation of organic and organochlorine impurities in it;

- obtaining alkaline water with specified parameters;

- maintenance of a given level of catholyte pH in the electrolytic cell and on delivery to the consumer.

Achievement of the specified technical result in the claimed invention is achieved by implementing a method for producing and selling alkaline water, consisting of

the process of pre-filtration and ultrafine filtration of water, from the electrolysis process with the separation of its products into catholyte and anolyte, as well as their delivery to consumers.

At the same time, in the claimed method:

before purification, the source water is disinfected and organic and organochlorine impurities are oxidized in it by ozonation with stirring by the recirculation method,

the regulation of the degree of water purification, as well as the composition of the catholyte, is carried out using a bypass pipeline (line) located between the stages of fine and ultrafine water purification, for which water after each stage of purification is directed in the required amount to the next stage or to the inlet of the electrolyzer and / or to final dispensing line and / or returned for additional cleaning,

electrolysis is carried out according to a periodic scheme, water after cleaning is supplied to the inlet of the electrolyzer in portions, with a certain regulated flow rate, the catholyte in each portion is adjusted to the specified pH values by coordinated regulation of the electrolysis process current and the water flow rate at the inlet, catholyte with normalized to the specified value pH is taken in portions for delivery to the consumer,

at the outlet of the electrolytic cell, streams of catholyte and anolyte are formed, and the anolyte is discharged into the sewer or an intermediate tank, and the catholyte is brought to the specified pH values and in the required amount is sent for delivery to the consumer,

then the catholyte is dispensed in the range of pH values from 8 to 11 in a given volume and with predetermined pH values into a container made of materials deactivated with respect to hydroxide ions or with a deactivated inner surface with respect to hydroxide ions, while the catholyte is dispensed by pouring a continuous flow or partial selection of catholyte from the stream, or through an additional device.

For an unambiguous and more complete understanding of the description of the claimed invention, the following are clarifications and disclosures of the concepts and terms used above, as well as a description of the method.

The purpose of the proposed method is to obtain and sell alkaline water with pH values from 8.0 to 11. Such water can be used for various needs in various spheres of the national economy and primarily for medical purposes, in folk medicine, for the purposes of health improvement. Since in the claimed invention the production of alkaline water is carried out using an electrolytic process in the cathode space, this water is also called catholyte. Thus, the concepts of catholyte and alkaline water in this presentation are identical. On the other hand, in said electrolytic process, anolyte or acidic water is produced in the anode space. Such water can also be widely used, in particular for the healing of certain communities, which, for example, is reported in the text of the closest analogue to the claimed invention (prototype).

For the purposes of recovery, clean water is required, therefore, the claimed invention provides for a purification unit, which includes technologically linear devices for disinfection, pre-filtration and fine purification (filtration). Oxidation of organic and organochlorine substances dissolved in water, as well as its disinfection, is mainly carried out by ozonation, for which a storage tank with an ozone generator and with a recirculation line for mixing is used. In this description, by disinfection by the ozonation process we mean the simultaneous oxidation of organic and organochlorine impurities. The pre-filtration device is preferably a fine-pore membrane filter, and the fine filter is preferably a reverse osmosis filter. Parallel to the abovementioned cleaning technological line, an auxiliary technological line is located - a bypass, which has a connection with the main technological line in technological units between the cleaning stages, in front of the electrolyzer and, if necessary, behind the electrolyzer. This design allows you to flexibly adjust the composition of water in different places of the purification line, direct the streams for additional purification, and also regulate the concentration of catholyte at the outlet due to dilution. The described purification line, if necessary, depending on the composition of the source water, can be supplemented with deozoning devices, a pump, measuring and regulating devices and sensors, hydraulic accumulators. The bodies of the devices of the cleaning unit and pipelines, as well as additional devices, are mainly made of polymer and metal-polymer materials.

The purified water enters the electrolysis unit, and then, in portions, to the inlet of the electrolyzer, where it is electrolytically processed. The portion size is determined by the consumer's request or mainly by the amount of payment. In the near-electrode areas of the electrolyzer, water is converted to catholyte and anolyte or alkaline and acidic water. The electrolysis is carried out to certain predetermined pH values in each portion prepared for dispensing / sale. As a rule, these are values in narrow pH ranges, which can be 0.1-0.4 pH. For example, retail sale of alkaline water uses water with pH values between 9.4 and 9.8. The general range of adjustable pH values is in the range from 8.0 to 11.

Dispensing alkaline water with specified pH values in the pH range from 8.0 to 11. is a difficult task due to the low stability of hydroxide ions in weak and medium alkaline aqueous media, as well as interactions with active internal surfaces and impurities. This situation leads to the need to implement a special regime of control and regulation of the electrolysis process. In practice, with the periodic implementation of the method, such control and regulation is carried out with the dispensing of each portion, and with constant operation of the machine after a certain time or a certain number of dispensed portions of catholyte. Therefore, the electrolysis unit is equipped with a regulation system, which is equipped with sensors for the inlet and flow of water and amperage and, of course, with pH detectors. Based on the readings of the process sensors and the set pH values, the matching process parameters are determined. These parameters, first of all, are the current strength of the electrolysis process and the amount of water supply flow (water flow) at the inlet to the electrolyzer, as well as the purity of the water at the inlet to the electrolyzer. The parameters are consistent because changing one leads to changing the other. For example, an increase in the catholyte pH value can be achieved both by reducing the water consumption and by increasing the process current or by compensating changes in both parameters. Similarly, with regard to the purity of the water supplied to the electrolysis - an increase in purity leads to the possibility of a decrease in the current strength. In the practical implementation of the method in the machine, in many cases, it is convenient to establish and maintain a predetermined pH in portions, while the electrolyzer is switched on and the required amount of water is supplied to the inlet of the electrolyzer in coordination after payment, and the portion is dispensed after the catholyte reaches a predetermined pH value. Thus, the catholyte is isolated with the specified parameters, and then the required portion is selected in the separated catholyte. The selection of a portion is carried out by separating a part of the catholyte with a pH that has reached the specified values. The selected portion is delivered to the consumer. In these cases, the increase in pH is carried out due to the implementation of the electrolytic process at a constant flow rate / flow of water. It should also be clarified that water comes to the cell along one line - along the inlet line, but when it enters the cell, this main flow is divided into two: one is directed to the cathode space, and the other to the anode space. In this case, the regulation of the flow of incoming water can be carried out both on the common supply line to the electrolyzer, and on the branch lines to the cathode and anode spaces.

The regulation of the current strength of the electrolysis process and the flow rate (flow) of water is carried out on the appropriate devices. To regulate the current strength, in particular, rheostats or thyristor regulators are used; to control the water flow, for example, ball or needle valves with a mechanical drive are used. The details of the electrolyzer, including the body and the electrodes, are made mainly of stainless materials; the materials of the partitions between the electrode spaces are finely porous ceramics.

Anolyte is removed from the anode space of the electrolyzer through a separate line and sent to the sewer or intermediate storage tank. Catholyte is removed from the cathode space along a separate line and sent to the consumer. The catholyte is dispensed by pouring into containers (containers) made of materials deactivated with respect to hydroxide ions or with a deactivated inner surface with respect to hydroxide ions.

Bottled catholyte can be dispensed in several ways:

- the usual dispensing in one stream through the equipment of the machine, in particular through a valve with shut-off valves,

- portioned dispensing through the tap,

- dispensing with cut-off of the head portion - it is used when the pH value of the head portion is low.

Dispensing equipment is made of stainless steel or polymeric materials with decontaminated inner surfaces.

The process is controlled and monitored using a processor unit and process control sensors. The data received from the sensors is processed in the processor unit according to a special program, as a result of which the corresponding commands are sent to the control and / or executive devices. The executed commands carry out and support the process of operation of the machine, which is ultimately realized after payment in the delivery of a certain amount of alkaline water of a given pH value.

The claimed invention is a technical solution, since is a solution to the problem of achieving the claimed technical result by implementing the method, which consists in the implementation of actions on material objects with the help of material means. In this case, the material objects are water, ozone, catholyte, anolyte. Above these material objects, the actions of supply (for water, catholyte, anolyte), treatment with oxidizing agents (for water), purification by filtration, electrolytic treatment, separation of streams, regulation of supply and flow, batch delivery are carried out. All actions on the specified material objects are performed in time and in a certain sequence. At the same time, the totality of these actions - the essential features of this invention is technologically and functionally interconnected and united by a single creative concept.

This technical solution is industrially applicable in the field of obtaining alkaline water with desired properties and its sale using vending machines. The implementation of the proposed technical solution can be carried out by specialists with appropriate training. In the implementation of the method of obtaining and selling alkaline water, devices, devices and materials are used commercially available and available on the open market. Methods for implementing the technological scheme of the invention are methods of mechanical processing of metal and plastics, electric welding and thermal welding of plastics, plumbing, installation. The means of implementation are mechanical means, machine tools and hand tools for machining, welding equipment. Practical use of the method of obtaining and selling alkaline water is possible by any consumer.

The above set of essential features of the claimed invention and their disclosure allows us to conclude that the claimed technical result has been achieved, namely the achievement of the following technical advantages over the prototype:

1. Disinfection of water entering the apparatus and oxidation of organic and organochlorine impurities in it - is achieved by ozonation of source water by using an ozone generator using a recirculation line and with the possibility of further deozonation on devices that absorb ozone, for example, on activated carbon;

2. Obtaining alkaline water with the specified parameters - is achieved by carrying out electrolysis according to a periodic scheme with a portioned supply of water after cleaning to the inlet of the electrolyzer with a certain regulated flow rate, while the catholyte in each portion is brought to the specified pH values by coordinated regulation of the electrolysis process current and speed water flow at the inlet, catholyte with normalized to a given pH value is taken in portions for delivery to the consumer,

3. Maintaining the set pH level of the catholyte at delivery to the consumer is achieved by batch dispensing of the catholyte and taking of metered portions with the set pH values at the outlet from the electrolyzer, as well as making the line and equipment for dispensing the catholyte from materials deactivated with respect to hydroxide ions. In case of exceeding the pH value at the outlet, its values can be normalized by dilution with purified water using the bypass line.

The essential features of the claimed invention in common with the prototype are:

- the process of pre-filtration of the water purification unit,

- the process of ultrafine filtration of the water purification unit,

- process of water electrolysis with removal of catholyte and anolyte

- product dispensing process with inlet and outlet for catholyte and anolyte.

Distinctive from the prototype, essential features of the claimed invention or their characteristics are:

- the implementation of the disinfection of the source water and the oxidation of organic and organochlorine impurities in it by ozonation with a recirculation line;

- regulation of the degree of water purification, as well as the composition of catalite using a bypass line located between the stages of fine and ultrafine water purification, for which water after each stage of purification is sent in the required amount to the next stage or to the inlet of the electrolyzer and / or to the final dispensing line and / or returned for additional cleaning;

- implementation of the water electrolysis unit according to a periodic scheme, while the water after cleaning is supplied to the inlet of the electrolyzer in portions, at a certain regulated flow rate, the catholyte in each portion is brought to the specified pH values by coordinated regulation of the electrolysis process current and the water flow rate at the inlet, catholyte with a pH normalized to a predetermined value, they are taken in portions for delivery to the consumer;

- direction of the anolyte at the outlet from the electrolyzer to the sewer or storage tank;

- direction of the catholyte for delivery to the consumer after bringing the pH to the specified values;

- implementation of the dispensing of catholyte in the range of pH values from 8 to 11 in a given volume and with predetermined pH values into containers made of materials deactivated with respect to hydroxide ions or with a deactivated inner surface with respect to hydroxide ions, while the catholyte is dispensed by pouring a continuous flow or partial selection of catholyte from the stream, or through an additional device.

These essential features are distinctive from the prototype, since each of them is not contained in the set of essential features of the prototype, i.e. is not present in the list of features implemented in the prototype, and is not their characteristic.

As already shown above, the above-mentioned essential features distinguishing from the prototype, including their characteristics, ensure the achievement of the claimed technical result when using other essential features of the invention indicated in the description.

Thus, it is shown that the set of essential features of the claimed invention, allowing to achieve the claimed technical result, differs from the set of essential features of analogues, prototype, as well as other known data sources, i.e. the application of this set of essential features is not known to obtain the claimed technical result. In other words, the claimed invention is not known from the prior art.

In the course of studying the prior art of methods for producing alkaline water and selling it using vending machines, no technical solutions have been identified, the essential features of which, individually or in any combination, coincide with the distinctive essential features of the claimed invention and make it possible to achieve the claimed technical result. Thus, the lack of awareness of the influence of the distinctive essential features of the claimed invention on the claimed technical result is confirmed.

It should also be noted that the use of the entire claimed set of essential features, including the set of distinctive features, to obtain the claimed technical result should not be explicitly followed for specialists from the prior art, since does not constitute a combination, change or sharing of information contained in the prior art and / or general knowledge of a specialist.

Indeed, obtaining alkaline water with a given pH in the electrolyzer and maintaining it on delivery to the consumer does not follow explicitly from the prior art for specialists through the use of the following technical solutions:

- implementation of the dispensing of catholyte in the range of pH values from 8.0 to 11.0 in a predetermined volume and with predetermined pH values into containers made of materials deactivated with respect to hydroxide ions or with a deactivated inner surface with respect to hydroxide ions, while the dispensing of catholyte is carried out by pouring continuous flow or partial withdrawal of catholyte from the flow, or through an additional device;

- the implementation of electrolysis according to a periodic scheme, namely: water after purification is fed to the inlet of the electrolyzer in portions with a certain regulated flow rate, bringing the pH of the catholyte in each portion to the specified values by coordinated regulation of the current strength of the electrolysis process and the water flow rate at the inlet, catholyte with normalized to a predetermined pH value is taken in portions for delivery to the consumer.

The given technical solutions are, with respect to the confirmed achievement of the claimed technical result, non-standard and unknown solutions. In addition, these solutions or these sets of essential features should be considered along with the use of other essential features claimed in the claims in a single set.

An increase in the efficiency of the claimed technical result is achieved in the following modifications of the method, which characterize particular cases of its implementation:

1. The claimed and described above method for producing and selling alkaline water, characterized in that the pre-filtration process is carried out by mechanical filtration on a mesh or disc filter with pores of 10 microns.

2. The claimed and described above method for producing and selling alkaline water, characterized in that the ultrafine filtration process is carried out on a ceramic ultrafiltration module with a cut-off threshold of 0.1-0.01 microns.

3. The claimed and described above method for producing and selling alkaline water, characterized in that the catholyte is dispensed for bottling through a line and equipment made of stainless steel.

4. The claimed and described above method for producing and selling alkaline water, characterized in that the catholyte is dispensed in bulk in containers made of stainless steel.

The description of the claimed method is illustrated by a diagram showing the following designations of its processes:

1 - disinfection of source water by ozonation,

2 - mixing by recirculation,

3 - preliminary filtration,

4 - ultrafine filtration,

5 - regulation of the degree of water purification using a bypass line,

6 - electrolytic treatment,

7 - removal of anolyte,

8 - removal of catholyte,

9 - delivery of catholyte.

The claimed invention - "Method for producing and selling alkaline water" is carried out as follows.

The method of obtaining and selling alkaline water involves the sequential implementation of the following processes:

- disinfection of source water by ozonation 1 with stirring by recirculation method 2;

- preliminary filtration 3;

- ultrafine filtration 4;

- regulation of the degree of water purification, as well as the composition of the catalite is carried out using the bypass line 5;

- implementation of electrolytic processing 6;

- removal of anolyte 7 and catholyte 8;

- delivery of catholyte 9.

To implement an effective process for obtaining alkaline water by the method of electrolytic decomposition, water of a high purity is used. Otherwise, energy consumption increases and the electrolyzer becomes clogged with precipitated salts, which leads to the need for additional cleaning. Therefore, the source water is thoroughly purified. First, the water is treated with ozone, for which an ozone generator, for example, high-voltage or ultraviolet, is used. To increase the efficiency of the process, recirculation of ozonized water is used. In this process, water is not only disinfected, but also organic and organochlorine impurities are oxidized. Then the water is directed to a pre-filter with a ceramic membrane with an impurity cut-off value of 0.1-0.01 microns. The next stage of cleaning is cleaning on an ultrafine filter. In practice, this is mainly a reverse osmosis filter. An auxiliary process line or bypass is located parallel to the main cleaning line. This line is connected to the main technological line in the technological units between the purification stages, in front of the electrolyzer and, if necessary, after the electrolyser. This design allows you to flexibly adjust the composition of water in different places of the purification line, as well as direct the streams for additional purification and control the concentration of catholyte at the outlet by dilution. The purified water is fed to the inlet of the electrolytic cell, where it is electrolytically processed to the specified catholyte values. The inlet is equipped with a water flow control device, mainly a ball or needle valve, which can be made with a mechanical drive. Behind this inlet, the flow of water is divided into two, one is directed to the cathode, and the other to the anode space of the electrolyzer. Anolyte and catholyte come out of the anode and cathode spaces of the electrolyzer through the corresponding lines. These lines are equipped with devices for the outlet of these products, which can be used, for example, ball or needle valves. The electrolyzer also contains devices for regulating the current strength and the amount of water flow at the inlet. Regulation of the current strength is carried out using a rheostat or thyristor controller. The product outlet is carried out in portions along two lines - one for the catholyte, the other for the anolyte, each of which can be provided with regulating devices similar to the inlet. The specified pH values in catholyte are achieved by coordinated regulation of water flow and current strength. Dispensing in portions is determined by the specifics of the automatic sale of alkaline water, which is carried out in portions, depending on the amount of payment. Therefore, the pH control is carried out on each portion of the prepared and dispensed water. Dispensing water with a predetermined pH value is associated with pH measurement, current regulation, as well as selection and withdrawal of a portion of alkaline water with specified characteristics. In this case, substandard water with lower or higher pH values is sent to the drain. The concentration of hydroxide ions in alkaline water in the pH range from 8.0 to 11.0 is very sensitive to the material of the container into which it is collected, due to the interaction of hydroxide ions with active centers and impurities on the inner surface. Therefore, the catholyte can only be poured into containers with a deactivated inner surface or made of inactive materials, for example, in a container made of stainless steel. In practice, the catholyte is bottled mainly in containers - stainless steel bottles.

Example 1

At the entrance to the production and sale system, water has the following characteristics: pH from 6 to 7.5, iron content from 0.1 to 2 mg / dm ³ , manganese content from 0.1 to 1 mg / dm ³ , permanganate oxidizability from 0 , 5 to 2 mg O ₂ / dm ³ , the presence of traces of chlorine and organochlorine compounds. To obtain alkaline water with pH values from 9.4 to 9.8, ozonation is first carried out in a closed container by treatment with ozone while stirring the mixture by recirculation. Then the water is purified on filters of preliminary and ultrafine purification. Purified water with characteristics - pH from 6 to 7.5, iron from 0.01 to 0.1 mg / dm ³ , manganese from 0.01 to 0.05 mg / dm ³ , permanganate oxidizability from 0.5 to 1 mg About ₂ / dm ³ , the absence of chlorine and organochlorine compounds, enters the inlet of the electrolyzer with a working volume of 1 liter. In the electrolytic cell, water is subjected to electrolytic treatment according to a periodic technological scheme, i.e. with periodic dosed supply of water to the inlet of the electrolyzer and flexible coordinated regulation of the parameters of the current strength and the volume of water supply in order to maintain the specified pH value in the catholyte at the outlet from the electrolyzer. In this case, the current strength was 5-8 A, the volume of water supply was 0.3-1 m ³ / hour, and the pH was 9.4-9.8. The catholyte with the specified pH value is supplied for dispensing to consumers in bottling. The filling is carried out in portions in the amount corresponding to the payment made by the consumer.

Example 2

The implementation of the method of obtaining and selling water with pH values from 8.9 to 9.0 was carried out similarly to example 1. The water at the inlet had the following characteristics: pH from 5 to 6.5, iron from 5 to 15 mg / dm ³ , manganese from 0.5 to 2 mg / dm ³ , permanganate oxidizability from 5 to 7 mg O ₂ / dm ³ , the presence of traces of chlorine and organochlorine compounds. At the entrance to the electrolyzer, the water had the following characteristics: pH from 5 to 6.5, iron from 0.05 to 0.3 mg / dm ³ , manganese from 0.01 to 0.1 mg / dm ³ , permanganate oxidizability from 1 to 5 mg О ₂ / dm ³ , absence of chlorine and organochlorine compounds. Electrolytic treatment of water took place at a current of 3-5 A and a flow rate at the inlet of 0.6-1.5 m ³ / hour. The pH of the catholyte at the outlet of the electrolytic cell was 8.9 to 9.0.

Example 3

The implementation of the method of obtaining and selling water with pH values from 10.5 to 11.0 was carried out similarly to example 2. The initial water had the following characteristics: pH from 7 to 8, iron from 3 to 7 mg / dm ³ , manganese from 0.8 to 1 mg / dm ³ , permanganate oxidizability from 7 to 8 mg O ₂ / dm ³ , the presence of traces of chlorine and organochlorine compounds. The water at the entrance to the electrolyzer had the following characteristics: pH from 7 to 8, iron from 0.2 to 0.3 mg / dm ³ , manganese from 0.08 to 0.1 mg / dm ³ , permanganate oxidizability from 3 to 5 mg О ₂ / dm ³ , absence of chlorine and organochlorine compounds. Electrolytic treatment of water took place at a current of 7-10 A and a flow rate at the inlet of 0.1-0.5 m ³ / hour. The pH value of the catholyte at the outlet of the electrolytic cell was 10.5-11.0.

Example 4

The implementation of the method of obtaining and selling water with pH values from 9.4 to 9.5 was carried out in a vending machine in the same way as in Example 1. The input to the machine was supplied with water with the following characteristics: pH from 6 to 7, iron from 0.1 to 0.3 mg / dm ³ , manganese from 0.1 to 0.3 mg / dm ³ , permanganate oxidizability from 0.5 to 0.8 mg O ₂ / dm ³ . After ozonation and purification on a prefiltration filter, the water characteristics were: pH from 6 to 7, iron from 0.01 to 0.1 mg / dm ³ , manganese from 0.01 to 0.08 mg / dm ³ , permanganate oxidizability from 0.1 to 0.5 mg O ₂ / dm ³ . The obtained water was divided into 2 streams by means of a bypass: 75% of the water was directed to the inlet to the electrolyzer, 25% was directed to the output to normalize the sold catholyte.

The above examples of examples should not be construed as limiting the scope of the invention. On the contrary, variations, modifications and equivalents to the described examples are also possible within the scope of the rights set forth in the claims.

The above description of the implementation of the invention and examples of its implementation confirm the achievement of the claimed technical result in the process of implementing the invention. They also show the causal relationship of essential features between themselves and the achieved technical result.

It also follows from the above description that the achievement of the technical result is possible only with the implementation of the entire set of essential features, which also confirms the technical solution to the problem of implementing the invention.

Claims (12)

1. A method of obtaining and selling alkaline water, consisting of a process of preliminary filtration and ultrafine filtration of water, from an electrolysis process with the separation of its products into catholyte and anionite, as well as their delivery to consumers, characterized in that before purification, the source water is disinfected and organic and organochlorine impurities are oxidized in it by ozonation with stirring by the recirculation method, regulation of the degree of water purification, as well as the composition of the catholyte, is carried out using a bypass line located between the stages of fine and ultrafine water purification, for which water after each stage of purification is directed in the required amount to the next stage or to the inlet of the electrolyzer and / or to the final dispensing line and / or returned for additional cleaning, electrolysis is carried out according to a periodic scheme, water after purification is supplied to the inlet of the electrolyzer in portions, with a certain regulated flow rate, the catholyte in each portion is adjusted to the specified pH values by coordinated regulation of the electrolysis process current and the water flow rate at the inlet, the catholyte is normalized to the specified value pH is taken in portions for delivery to the consumer, at the outlet of the electrolytic cell, streams of catholyte and anolyte are formed, and the anolyte is discharged into the sewer or an intermediate tank, and the catholyte is brought to the specified pH values and in the required amount is sent for delivery to the consumer, then catholyte is dispensed in the range of pH values from 8.0 to 11.0 in a given volume and with predetermined pH values into containers made of materials deactivated with respect to hydroxide ions, or with a deactivated inner surface with respect to hydroxide ions, while the catholyte is dispensed by pouring continuous flow or partial withdrawal of catholyte from the flow, or through an additional device. 2. The method according to claim 1, characterized in that the pre-filtration process is carried out by mechanical filtration on a mesh or disc filter with pores up to 10 microns. 3. The method according to claim 1, characterized in that the ultrafine filtration process is carried out on a ceramic ultrafiltration module with a cut-off threshold of 0.1-0.01 microns. 4. The method according to claim 1, characterized in that the catholyte is dispensed into the filling through the line and on equipment made of stainless steel. 5. The method according to claim 1, characterized in that the dispensing of the catholyte for filling is carried out in containers made of stainless steel.

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