RU2795908C1 - Alkaline water receiving and selling machine - Google Patents

Abstract

FIELD: vending machines.

SUBSTANCE: invention relates to vending machines for issuing purified water with desired properties to consumers. The machine for receiving and selling alkaline water consists of a water purification unit, a water electrolysis unit with catholyte and anolyte lines, a control and monitoring unit, and a catholyte dispensing device. At the same time, the machine is equipped with a water-jet ejector, and from the catholyte output line from the electrolyser, a separate catholyte supply line to the water purification unit is made with connection to the technological elements of this unit in front of the ultrafiltration device to implement an alkaline environment in this device.

EFFECT: increase in the degree of water purification is achieved.

8 cl, 1 dwg

Description

The invention relates to the field of vending machines, namely to vending machines for issuing purified water with desired properties to consumers.

Currently, there are many water vending machines in which water is purified, its properties are regulated and prepared for sale. In most cases, these are vending machines with water disinfection and purification units and a water dispensing unit. So, for example, vending machines for the retail sale of water for bottling, which have a cleaning and disinfection system, are widely used (Product offer [Electronic resource] - URL: https://alivewater.ru/katalog/apparaty-pitevoj-vody (accessed 01/04/2021) ). The disadvantages of these machines are the inability to control the properties of water, including its pH and the limited options for issuing water to consumers.

Also known is a water retailer 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 No. 2495496, IPC G07F 13/02). The disadvantage of this apparatus is the inability to obtain alkaline water (water with pH>8).

A big problem for obtaining alkaline water is also the purification of the source water from organic impurities that are somehow present in it. To solve this issue, it is known to use a method consisting in the decomposition of organic compounds of wastewater with ozone in the near-cathode space saturated with hydroxyl ions, i.e. in an alkaline environment (WIPO Publication No. 2005103391, Japan, IPC C02F 9/00, 2005). The essence of the method lies in the bubbling of ozone through wastewater, into which DC electrodes are lowered. The disadvantages of the method and design are: low productivity due to contamination of the electrodes with decomposition products and the complexity of additional placement of such equipment due to the need to increase the technological volume of the machine.

It is known from the scientific literature that the oxidation of organic water impurities occurs more intensively in an alkaline medium. It is likely that this occurs due to the effect on organic compounds of the ozonide ion - O ₃ ^- , which is the strongest oxidizing agent and is formed during the decay of ozone in an alkaline environment (V. F. Kozhinov, I. V. Kozhinov. Water ozonation. [Electronic resource] - URL: https://helpiks.org/2-71562.html (date of access 03/25/2022) This property ensures the high ability of ozone to oxidize organic water pollutants in an alkaline environment (Oxidation by ozone. [Electronic resource] - URL: https ://ru-ecology.info/term/49568/ (date of access 03/25/2022) Above, when characterizing the prior art, an example was given of treatment of organic wastewater in an alkaline environment (WIPO Publication No. 2005103391, Japan. IPC C02F 9/ 00, 2005. However, the data given in these sources are only of a scientific, fundamental nature and do not allow putting into practice the pattern of increased oxidizability of organic compounds by ozone in an alkaline environment.

Also known is a vending machine for water, having devices for 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 an inlet and outlet of water for consumers, as well as a control system, including touch screen control. A membrane-type filter was used as a pre-filter to separate mechanical impurities. For further purification of water in front of the electrolyser, a filter with activated carbon and KDF catalytic powder was used, which is an ultrafine filtration device (WIPO application 201910570779.3, publication number 110232780, IPC G07F 13/00, 09/13/2019). The disadvantage of this apparatus is the absence of a device for disinfection of water entering the apparatus and the impossibility of obtaining and issuing alkaline water with the specified parameters.

The closest (prototype) in terms of essential features to the claimed invention is an automatic machine for obtaining and selling alkaline water, consisting of:

water purification unit, including pre-filtration and ultra-fine water filtration devices,

water electrolysis unit with catholyte and anolyte outlet,

block of the control system with a programming device,

as well as devices for issuing catholyte and anolyte with their inlet and outlet.

At the same time, the water purification unit has a disinfection device with a recirculation line, as well as a bypass line located parallel to the purification line and allowing water to be supplied or added to the electrolyzer, as well as for dispensing water with a given degree of purification, a water electrolysis unit that allows you to set and maintain a set pH value catholyte, due to the coordinated regulation on the corresponding devices of the current intensity of the electrolysis process, as well as the water flow during the isolation and selection of a dosed portion of the catholyte at the outlet of the electrolyzer, at the outlet of the electrolyzer there is an anolyte output line and a catholyte line directing it for delivery to the consumer, a control unit and control, contains a processor unit and sensors for the implementation of the parameters of the machine, and the device for issuing catholyte contains:

- dispensing line supply and dispensing window into the spill with dispensing and / or dosing and / or partial cut-off equipment, while the dispensing line is made of materials deactivated with respect to hydroxide ions,

- at least one window and one line for dispensing water bottles and/or accessories (RF patent No. 2758347, IPC G07F 13/00, 2021). Here it should be noted that in the present invention, as a pre-filtering device, in particular, devices with a filtering membrane are used, in which the pore size varies in the range of 0.1 - 0.01 μm. In such a case, the filtration membrane may be referred to as an ultrafiltration membrane, and the pre-filtration device as an ultrafiltration module or an ultrafiltration device. The disadvantage of the described machine is the insufficient purification of water from organic impurities at the pre-filtration stage, which in turn leads to an increase in the time and number of preventive measures for cleaning the membranes of the pre-filtration device itself, as well as the ultrafine purification device and the electrolyzer.

The objective of the claimed invention is to eliminate the disadvantages of the above technical solution and achieve a technical result in relation to increasing the degree of water purification from organic impurities at the ultrafiltration stage, as well as expanding the arsenal of technical means of automatic machines for receiving and selling water.

The achievement of the specified technical result in the claimed invention is achieved through the implementation of the machine for the production and sale of alkaline water, consisting of

a water purification unit, including a disinfection device with a recirculation line, an ultrafiltration device, an ultrafine purification device and a bypass line located parallel to the purification line and allowing water to be supplied or added to the electrolyzer, as well as for issuing water with a given degree of purification,

a water electrolysis unit with catholyte and anolyte lines, which allows you to set and maintain the set pH value of the catholyte, due to the coordinated regulation of the current intensity of the electrolysis process on the corresponding devices, as well as the water flow during the isolation and selection of a dosed portion of the catholyte at the outlet of the electrolyzer,

at the same time, at the outlet of the electrolyzer, there is an anolyte output line and a catholyte line directing it for delivery to the consumer,

a control and monitoring unit containing a processor unit and sensors for implementing the parameters of the machine,

characterized in that

to supply the purified water to the inlet compartment of the ultrafiltration device, a water-jet ejector is made, through which the ozone-air mixture simultaneously flows to ozonize this water,

from the catholyte output line from the electrolyzer, a separate catholyte supply line to the water purification unit is made with connection to the technological elements of this unit in front of the ultrafiltration device for the implementation of an alkaline environment in this 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 design.

The purpose of the proposed vending machine is the automatic production and sale of alkaline water with pH values from 8.0 to 11.0. recovery. 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 are identical in this presentation. On the other hand, in said electrolytic process, anolyte or acid water is produced in the anode space. Such water can also be widely used, in particular in medicine.

For the purposes of rehabilitation, clean, disinfected water is required, therefore, the claimed invention provides a purification unit, including technologically linearly located devices for disinfection, preliminary filtration or ultrafiltration, as well as ultrafine purification. Disinfection is mainly carried out by ozonation. Ozonation is carried out in a contact container, into which an ozone-air mixture is supplied from an ozone generator. The supply is carried out mainly through a water jet ejector. A recirculation line is additionally connected to the line for supplying ozone to the contact container for better mixing of ozone with the source water. This line is located between the outlet and the inlet of water in the contact container. In this description, disinfection by ozonation is understood to mean the simultaneous oxidation of organic and organochlorine impurities. The contact capacitance can also serve as a storage capacitance.

From the contact container, water with oxidation products of organic and organochlorine impurities is sent to the ultrafiltration device. It should be noted here that, as a rule, it is not possible to achieve complete oxidation of organic and organochlorine impurities. Therefore, the supply of water from the contact container to the ultrafiltration device is carried out through a water jet ejector with the supply of an ozone-air mixture. It is known from practice that the use of ejectors for supplying gas-liquid mixtures is more efficient in terms of productivity and degree of mixing than other common methods - parallel supply of gas and liquid components or bubbling.

The ultrafiltration device is preferably a filter with a fine porous membrane, the pore size of which varies in the range of 0.01 - 0.1 μm. Filtration conditions are as follows: differential pressure 0.05 - 0.6 MPa, flow rate of the ozone-air mixture through the ejector 8×10 ^-5 - 56×10 ^-5 m ³ /s (0.3 - 2 m ³ /hour), area filtration surface 0.15 - 2 m ² , content of dissolved ozone in the mixture 0.01 - 1 g/m ³ . During filtration in the inlet compartment of the ultrafiltration device, oxidation products of organic and organochlorine impurities can accumulate. These products clog the pores of the ultrafiltration membrane, which interferes with the filtration process. To avoid this, a line for supplying liquid from the inlet compartment to the contact container is organized, which is equivalent to organizing a second recycling line into the contact container. Recycling can be done by partial activation of the bypass line. The implementation of recycling allows to reduce surface contamination of the ultrafiltration membrane. To regulate the pressure in the inlet compartment of the filter on the recycling line (the second recycling line - the line for returning the filtered liquid to the contact container), a throttle can be installed, and a drain can be made to remove contaminants from the system.

The filtrate from the ultrafiltration device is fed into the ultrafine cleaning device. The ultrafine cleaning device is preferably a reverse osmosis filter. Here, it is also possible to organize the return of filtered water through the bypass devices back through the system and the discharge of contaminants. The differential pressure on the filter is 0.4 - 2 MPa, the filtration surface area is 0.15 - 2 m ² .

The claimed invention takes into account the data on the increase in the oxidizing power of ozone in an alkaline environment, given earlier in the review of the prior art. According to the invention, an alkaline environment in the inlet compartment of the ultrafiltration device is created by introducing into this compartment the catholyte obtained in the electrolyzer as a target product. To do this, an additional separate pipeline line is made in the machine for receiving and selling alkaline water, connecting the outlet from the cathode space of the electrolyzer with the technological elements of the water purification unit located in front of the ultrafiltration device. These technological elements can be a contact tank, an entrance to a contact tank, a recycling line. Thus, the catholyte also has a secondary technological function, and an additional separate pipeline line ensures the implementation of this function, which makes it possible to increase the degree of water purification from organic impurities at the ultrafiltration stage. Said separate pipeline line can have shut-off and control valves at both ends, and from the side of connection to the technological elements of the water treatment unit, it has an inlet device. This inlet device can be made as an ejector, a nozzle or an injector.

Parallel to the above-mentioned cleaning technological line, an auxiliary technological line is located - a bypass, which 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 electrolytic cell. The described purification line, if necessary, depending on the composition of the source water, can be supplemented with deozonizing devices, a pump, measuring and control devices and sensors, hydraulic accumulators. If additional purification from ozone is required, carbon adsorbents are used. The housings of the devices of the cleaning unit and pipelines, as well as additional devices, are mainly made of stainless steel, polymeric and metal-polymeric materials.

The purified water enters the electrolysis unit, where it is electrolytically processed, while the water in the near-electrode regions is converted into catholyte and anolyte or alkaline and acidic water. The electrolysis is carried out up to certain, given pH values. As a rule, these are values in narrow pH ranges, which can be 0.1 - 0.4 pH. For example, for the retail sale of alkaline water, water with pH values from 9.4 to 9.8 is used. The general range of adjustable pH values is in the range from 8.0 to 11.0.

The issuance of alkaline water with specified pH values in the range from 8.0 to 11.0 is not an easy task due to the low stability of hydroxide ions in slightly and medium alkaline aqueous media, as well as interaction with active internal surfaces and impurities. This situation leads to the need for a special regime of control and regulation of the electrolysis process. In practice, during the periodic operation of the machine, such control and regulation is carried out with the issuance of each portion, and with the 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 control system, which is equipped with sensors for the inlet and flow of water and current strength and, of course, a pH measuring device. Based on the indications of the process sensors and the set pH values, the determination of consistent process parameters is carried out. 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 pH value of the catholyte 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 reducing the current strength. In the practical operation of the machine, in many cases it is convenient to establish and maintain the set pH in portions, while the electrolyzer is turned on and the required amount of water is supplied to the electrolyzer inlet in a coordinated manner after payment, and the portion is dispensed after reaching the set pH value in the catholyte. Thus, the catholyte is isolated with the given parameters, and then the necessary portion is selected in the selected catholyte. The selected portion is delivered to the consumer. In these cases, the increase in pH is carried out by carrying out the electrolytic process at a constant flow/flow of water. It should also be clarified that water approaches the electrolyzer along one line - along the input line, but when it enters the electrolyzer, this main flow is divided into two: one goes to the cathode space, and the other to the anode. In this case, the regulation of the flow of incoming water can be carried out both on a common supply line to the electrolyzer, and on branching lines to the cathode and/or anode space.

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

From the anode space of the electrolytic cell, the anolyte is removed through a separate line and sent to the sewer or storage tank. In particular, the anolyte from the storage tank can also be used for washing or disinfecting individual devices of the machine. Catholyte is removed from the cathode space along a separate line and sent for delivery to the consumer. The issuance of catholyte is carried out in bottling in a window specially equipped for this or in bottles with an internal decontaminated surface in another window. In the same or another (third) window, it is also possible to issue / sell various accessories. Catholyte in bottling can be dispensed according to several schemes:

- the usual issuance of a jet through the equipment of the machine, in particular through a valve with shut-off valves,

- portion delivery through the crane,

- issuance with cutting off the head portion - is used at a reduced pH value of the head portion.

Dispensing equipment is made of stainless steel or polymer materials with decontaminated internal surfaces.

The control and monitoring unit contains a processor unit, and sensors for implementing the parameters of the machine. The operation of the vending machine for receiving and selling water is controlled by numerous sensors. The data received from the sensors is processed in the processor unit according to a special program, as a result of which commands are sent to the corresponding control and/or actuating devices. The executed commands carry out and support the process of operation of the machine, which is ultimately realized after payment for the issuance of a certain amount of alkaline water of a given pH value.

The catholyte dispensing device solves the problem of maintaining a given alkalinity during dispensing due to the rapid organization of dispensing and the use of materials deactivated with respect to hydroxide ions. As a material of tubes and nozzles of the dispensing device, as well as containers for dispensing, as a rule, stainless steel is used. Reduction of dispensing time is performed by reducing the dispensing path and electrolysis time.

The claimed invention is a technical solution, because is a solution to the problem of achieving the claimed technical result by creating a device consisting of structural elements that are technologically and structurally interconnected. At the same time, the set of essential features of this invention - a system of devices - is united by a single creative concept. Parts (elements) of the device are in a constructive unity and functional relationship, and their joint use leads to the creation of a new device with a new purpose and function - an automatic machine for obtaining and selling alkaline water.

This technical solution is industrially applicable in the field of vending machines, namely, vending machines for issuing purified water with desired properties to consumers. The implementation of the proposed technical solution can be carried out by specialists with appropriate training. In the implementation of the machine for obtaining and selling alkaline water, devices, devices and materials manufactured by the industry and being on the open market are used. Methods for implementing the invention are methods of mechanical processing of metal and plastics, electric welding and thermal welding of plastics, metalwork, installation. The means of implementation are mechanical means, machine tools and manual tools for machining, welding equipment. The use of vending machines for the production and sale of alkaline water is possible for 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, an increase in the degree of water purification from organic impurities at the ultrafiltration stage due to better mixing of the ozone mixture with water, as well as due to better oxidizability of organic impurities by ozone in an alkaline environment with the coordinated implementation of these processes. In turn, the implementation of the purpose of the invention is confirmed:

- obtaining alkaline water with specified parameters through the use of an electrolyzer with the implementation of a comprehensive control of the parameters of the water electrolysis process and coordinated regulation of the water supply and current strength, while the coordination is carried out according to the readings of the sensors, and the change in the water flow and current strength is performed by appropriate control devices;

- maintenance of a given pH level of the catholyte at the dispensing to the consumer due to batch dispensing of the catholyte and selection of dosed portions with predetermined pH values at the outlet of the electrolyzer, as well as the implementation of 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 to the set values by diluting with purified water using a bypass line.

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

- implementation of a water-jet ejector for supplying treated water to the inlet compartment of the ultrafiltration device and simultaneously processing it with an ozone-air mixture,

- implementation of a separate catholyte supply line from the catholyte output line from the electrolyzer to the water purification unit with connection to the technological elements of the unit in front of the ultrafiltration device for the implementation of an alkaline environment in this device.

These essential features are distinctive from the prototype, because each of them is not contained in the totality of the 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, these essential features, which are distinctive from the prototype, including their characteristics, ensure the achievement of the claimed technical result when using other essential features of the invention specified in the description.

Thus, it is shown that the set of essential features of the claimed invention, which makes it possible to achieve the claimed technical result, differs from the set of essential features of analogues, a prototype, as well as other known data sources, i.e. it is not known the application of this set of essential features 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 state of the art of machines for controlling the issuance of liquids, devices for preparing drinks, as well as machines for obtaining and selling alkaline water, 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 allow achieve the claimed technical result. Thus, the lack of knowledge 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 does not follow explicitly for specialists from the prior art, because is not a combination, modification or sharing of the information contained in the prior art, and / or the general knowledge of a specialist.

Indeed, the organization/implementation of the line for the removal of a part of the catholyte from the electrolyzer, which is connected via a separate line to the water purification unit and this connection is located in front of the ultrafiltration device for the implementation of an alkaline environment in this device, does not follow explicitly for specialists from the prior art due to the use of technical solutions, which are listed above as essential features different from the prototype.

Thus, regarding the confirmed achievement of the claimed technical result, a non-standard and unknown technical solution is:

- implementation of a water-jet ejector for supplying purified water to the inlet compartment of the ultrafiltration device with simultaneous processing of it with an ozone-air mixture,

- implementation of a separate catholyte supply line from the catholyte output line from the electrolyzer to the water purification unit with connection to the technological elements of water purification before the ultrafiltration device for the implementation of an alkaline environment in this device.

These distinguishing essential features should be considered together with the use of other declared essential features.

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

1. The machine for the production and sale of alkaline water claimed and described above, characterized in that the disinfection device is a contact container into which the ozone-air mixture is fed through a water jet ejector.

2. The claimed and described above machine for the production and sale of alkaline water, characterized in that the ultrafiltration device contains a ceramic filtration membrane with a cut-off threshold of 0.1 - 0.01 μm.

3. The machine for the production and sale of alkaline water claimed and described above, characterized in that the supply of the dispensing line to the dispensing window, as well as the dispensing and / or dosing equipment, are made of stainless steel.

4. The machine for the production and sale of alkaline water claimed and described above, characterized in that the supply of the dispensing line to the dispensing window for bottling, as well as dispensing and / or dosing equipment, are made of materials with a deactivated inner surface with respect to hydroxide ions.

5. The machine for receiving and selling alkaline water claimed and described above, characterized in that one window located on the front panel of the machine is intended for issuing bottles of water and accessories.

6. The machine for receiving and selling alkaline water claimed and described above, characterized in that different windows located on the front panel of the machine are designed to dispense water bottles and accessories.

7. The machine claimed and described above for the production and sale of alkaline water, characterized in that the connection of the catholyte supply line to the technological elements of the water purification unit is made in the form of an ejector or a branch pipe or an injector.

The description of the claimed method is illustrated by a diagram, which shows the following symbols:

1 - water purification unit,

11 - disinfection device with a contact container,

12 - recirculation line,

13 - ultrafiltration device,

14 - ultrafine cleaning device or reverse osmosis filter,

15 - bypass,

16 - second bypass recycling line,

17 - catholyte line inlet device in the water treatment unit,

2 - electrolysis unit,

21 - electrolyzer,

22 - water inlet to the electrolyzer,

23 - anolyte outlet,

24 - catholyte output,

25 - current regulator in the electrolyzer,

26 - water flow regulator at the inlet to the cell,

3 - anolyte line,

4 - catholyte line,

41 - catholyte output line from the electrolyzer to the water treatment unit,

42 - window for dispensing catholyte into bottling,

43 - window for dispensing bottles with catholyte or accessories,

5 - control and monitoring unit,

51 - processor unit,

52 - control sensors.

The claimed invention - "Automatic machine for the production and sale of alkaline water" is carried out as follows.

The machine for receiving and selling alkaline water consists of a water purification unit 1, an electrolysis unit 2, an anolyte line 3, a catholyte line 4, a control and monitoring unit 5. The water purification unit is designed to purify the source water before electrolytic treatment and contains a disinfection device with a contact capacity 11, as well as a recirculation line 12, an ultrafiltration device 13, an ultrafine purification device, mainly a reverse osmosis filter 14, a bypass 15, a second recycling line 16. The ultrafiltration device also contains a device for entering or connecting the catholyte line to the technological elements of the water purification unit 17.

First, water is disinfected by ozonation. The required degree of disinfection at this stage is achieved by recycling. The ozone-air mixture is introduced into the contact container, mainly through the ejector. Then carry out ultrafiltration from impurities and finally ultrafine filtration. The bypass line allows you to flexibly rebuild the treatment scheme depending on the composition of the source water and intermediate filtrates, as well as partially control the water output. Part of the bypass line can be used as a second line for recycling filtered water into a contact container. The electrolysis unit contains an electrolytic cell 21 equipped with a water inlet 22. After this inlet, the water flow is divided into two, one is directed to the cathode and the other to the anode space of the cell. Anolyte and catholyte exit from the anode and cathode space of the cell, respectively, along lines 3 and 4. From the catholyte outlet line from the electrolyzer, the catholyte outlet line to the water purification unit 41 departs. also contains devices for regulating the current strength 25 and the amount of water flow at the inlet 26.

Water is decomposed in the cell to form anolyte and catholyte with specified pH values. One of the outlets of the electrolyzer is the beginning of the catholyte line, and the other is the beginning of the anolyte line. The anolyte is sent to the drain or to some storage tank, and the catholyte line is led to the issuance to the consumer. At the end of the catholyte line on the front panel there is a window for dispensing catholyte into bottling 42 and a window for dispensing bottles with catholyte or accessories 43. The control and monitoring unit contains a processor unit 51 and control sensors 52 distributed over control points.

Example 1

To obtain alkaline water with pH values from 9.4 to 9.8, an automatic machine is carried out, consisting of a water purification unit, an electrolysis unit, an anolyte line, a catholyte line, a control and monitoring unit. The machine is connected to the water supply and the water supply is opened. The water had the following characteristics: pH 7.5 - 7.8, iron content from 0.3 - 0.5 mg/l, manganese content 0.1 - 0.2 mg/l, permanganate oxidation from 5 to 7 mg O ₂ /l , the presence of traces of chlorine and organochlorine compounds. Water entered the water purification unit, where it was purified and disinfected by treatment with an ozone-air mixture using an ejector and using recirculation of the ozonized water flow. Then the water was purified on an ultrafiltration device with a pore size in the range of 0.01 - 0.1 μm, and then on a reverse osmosis filter. The structure of the ultrafiltration membrane is tubular, the filtration surface area is 1.0 m ² . The design of all reverse osmosis membranes is the same; it is made of a web wound in the form of a roll, the filtration area of a four-inch reverse osmosis membrane is 8 m ² . In this case, the differential pressure on the ultrafiltration membrane was 0.05 - 0.06 MPa, and on the reverse osmosis membrane 0.4 MPa. Purified water with characteristics: pH 7.5 - 7.8, iron content 0.01 - 0.015 mg/l, manganese 0.01 - 0.015 mg/l, permanganate oxidation 0.01 - 0.012 mg O ₂ /l, no chlorine and organochlorine compounds, entered the electrolytic cell with a working volume of 1 liter. In the electrolyzer, water was 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 of the electrolyzer. In this case, the current strength was 5-8 A, the volume of water supply was from 0.3 to 0.5 m ³ /hour, and the pH at the outlet of the cell was from 9.4 to 9.8. The catholyte with the indicated pH value was supplied to consumers for bottling. Bottling was carried out in the amount of payment made by the consumer in stainless bottles. To maintain the cleaning and electrolysis parameters constant, the inlet compartment of the ultrafiltration device and its membranes are cleaned once every 3 months.

Example 1.2.

The implementation of the machine for the production and sale of water with pH values from 8.0 to 8.4 was carried out analogously to example 1. But in contrast to it, a separate catholyte supply line was made between the catholyte output line from the electrolyzer and the water purification unit, and this line was connected by connecting to the ozonized flow recirculation line into a contact container. The water entering the machine had the following characteristics: pH 6 - 6.5, iron 0.1 - 02 mg / l, manganese 0.05 - 0.07 mg / l, permanganate oxidizability 3 - 3.5 mg O ₂ / l, the absence of chlorine and organochlorine compounds, was fed to the inlet of the electrolytic cell with a working volume of 1 liter. In the electrolyzer, water was 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 of the electrolyzer. In this case, the current strength was 3-5 A, the volume of water supply was from 0.5 to 0.8 m ³ /hour, and the pH at the outlet was from 8.0 to 8.4. The catholyte with the indicated pH value was supplied to consumers for bottling. Bottling was carried out in the amount of payment made by the consumer in stainless bottles. To maintain the cleaning and electrolysis parameters constant, the inlet compartment of the ultrafiltration device and its membranes are cleaned once every 4 months.

Example 2

The implementation of the machine for obtaining and selling water with pH values from 8.0 to 8.4 was carried out analogously to example 1, but the surface area of the filtration was 2 m ² . In this case, the differential pressure on the ultrafiltration membrane was 0.6 MPa, and on the reverse osmosis membrane 2 MPa, the value of the differential pressure was 0.20 - 0.25 MPa. The water entering the machine had the following characteristics: pH 6.5 - 6.8, iron 15-18 mg / l, manganese 6 -7 mg / dm ³ , permanganate oxidation 10 - 13 mg O ₂ /l, the presence of traces of chlorine and organochlorine compounds. The water at the entrance to the electrolyzer had the following characteristics: pH 6.5 - 6.8, iron 0.01 - 0.015 mg/l, manganese 0.01 - 0.014 mg/l, permanganate oxidizability 1 - 1.5 mg O ₂ /l , absence of chlorine and organochlorine compounds. Electrolytic water treatment took place at a current strength of 4-6 A and an inlet flow rate of 0.6-1.5 m ³ /hour. The pH value of the catholyte at the outlet of the cell was 8.0 to 8.4. Bottling is carried out in the amount of payment made by the consumer into containers made from materials deactivated with respect to hydroxide ions. To maintain the cleaning and electrolysis parameters constant, the inlet compartment of the ultrafiltration device and its membranes are cleaned once a month.

Example 2.1.

The implementation of the machine for the production and sale of water with pH values from 8.0 to 8.4 was carried out analogously to example 2. But in contrast to it, between the catholyte output line from the electrolyzer and the inlet compartment of the ultrafiltration device, a separate catholyte supply line was made to this compartment, and the supply of this line is carried out through a branch pipe, in front of the ejector of the ultrafiltration device. The water entering the machine had the following characteristics: pH from 7.8 to 8.2, iron 10-12 mg / l, manganese from 0.30 - 0.35 mg / l, permanganate oxidizability 8 - 9 mg O ₂ / l, the presence of traces of chlorine and organochlorine compounds. The water at the inlet to the cell had the following characteristics: pH 7.8 - 8.2, iron 0.05 - 0.07 mg/dm ³ , manganese 0.010 - 0.012 mg/dm ³ , permanganate oxidizability 1.0 - 1.3 mg O ₂ /dm ³ , absence of chlorine and organochlorine compounds. Electrolytic water treatment took place at a current strength of 2 - 3 A and an inlet flow rate of 0.6-1.5 m ³ /hour. The pH value of the catholyte at the outlet of the cell was 8.0 to 8.4. Bottling was carried out in the amount of payment made by the consumer into containers made from materials deactivated with respect to hydroxide ions. To maintain the cleaning and electrolysis parameters constant, the inlet compartment of the ultrafiltration device and its membranes are cleaned once every 2 months.

Example 3

The implementation of the machine for receiving and selling water with pH values from 10.5 to 11.0 was carried out analogously to example 2, but the value of the differential pressure was 0.55 - 0.6 MPa. The water entering the machine had the following characteristics: pH 8 - 8.5, iron 10-12 mg / dm ³ , manganese 3-4 mg / dm ³ , permanganate oxidation 8 - 10 mg O ₂ / dm ³ , the presence of traces of chlorine and organochlorine compounds. The water at the inlet to the cell had the following characteristics: pH 8 - 8.5, iron 0.010 -0.015 mg/dm ³ , manganese 0.04 - 0.05 mg/dm ³ , permanganate oxidizability 1.0 - 1.5 mg O ₂ /dm ³ , absence of chlorine and organochlorine compounds. Electrolytic water treatment took place at a current strength of 7-10 A and an inlet flow rate of 0.1-0.5 m ³ /hour. The pH value of the catholyte at the outlet of the cell ranged from 10.5 to 11.0. The issuance of catholyte was carried out in a special window of the machine in stainless steel bottles filled with it. To maintain the cleaning and electrolysis parameters constant, the inlet compartment of the ultrafiltration device and its membranes are cleaned once a month.

Example 3.1.

The implementation of the machine for the production and sale of water with pH values from 10.5 to 11.0 was carried out analogously to example 2. In contrast to this example, between the catholyte output line from the electrolyzer and the inlet compartment of the ultrafiltration device, a separate catholyte supply line was made into the contact container, and this line was supplied through an injector.

The water entering the machine had the following characteristics: pH from 8.0 to 8.5, iron from 5 to 7 mg / dm ³ , manganese 1.0 - 1.8 mg / dm ³ , permanganate oxidation 6-8 mg O ₂ /dm ³ , the presence of traces of chlorine and organochlorine compounds. The water at the inlet to the cell had the following characteristics: pH 8.0 - 8.5, iron from 0.012 - 0.015 mg/dm ³ , manganese from 0.04 - 0.05 mg/dm ³ , permanganate oxidizability from 1 to 2 mg O ₂ /dm ³ , absence of chlorine and organochlorine compounds. Electrolytic water treatment took place at a current strength of 6-8 A and an inlet flow rate of 0.1-0.5 m ³ /hour. The pH value of the catholyte at the outlet of the cell ranged from 10.5 to 11.0. The issuance of catholyte was carried out in a special window of the machine in stainless steel bottles filled with it. To maintain the cleaning and electrolysis parameters constant, the inlet compartment of the ultrafiltration device and its membranes are cleaned once every 2 months.

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

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

From the above description it also follows that the achievement of a technical result is possible only when the entire set of essential features is implemented, which also confirms the technical solution of the problem of implementing the invention.

Claims (16)

1. An automatic machine for receiving and selling alkaline water, consisting of a water purification unit, including a disinfection device with a recirculation line, an ultrafiltration device, an ultrafine purification device and a bypass line located parallel to the purification line and allowing water to be supplied or added to the electrolyzer, as well as to issue water with a given degree of purification, a water electrolysis unit with catholyte and anolyte lines, which allows you to set and maintain the set pH value of the catholyte, due to the coordinated regulation of the current intensity of the electrolysis process on the corresponding devices, as well as the water flow during the isolation and selection of a dosed portion of the catholyte at the outlet of the electrolyzer, at the same time, at the outlet of the electrolyzer, there is an anolyte output line and a catholyte line directing it for delivery to the consumer, a control and monitoring unit containing a processor unit and sensors for implementing the parameters of the machine, as well as a catholyte dispensing device, which contains: - supply of the dispensing line and the dispensing window into the spill with dispensing equipment, and/or dosing, and/or partial cut-off, while the dispensing line is made of materials deactivated with respect to hydroxide ions, - at least one window and one line for dispensing water bottles and/or accessories, characterized in that to supply treated water to the inlet section of the ultrafiltration device, a water-jet ejector is made, through which an ozone-air mixture is simultaneously supplied to ozonize this water; ultrafiltration for the implementation in this device of an alkaline environment. 2. The machine according to claim 1, characterized in that the disinfection device is a contact container into which the ozone-air mixture is fed through a water jet ejector. 3. Machine according to claim. 1, characterized in that the ultrafiltration device contains a ceramic filtration membrane with a cut-off threshold of 0.1-0.01 microns. 4. The machine according to claim 1, characterized in that the supply of the dispensing line to the dispensing window into the spill, as well as the dispensing and / or dosing equipment, are made of stainless steel. 5. The machine according to claim 1, characterized in that the supply of the dispensing line to the dispensing window into the spill, as well as the dispensing and / or dosing equipment, are made of materials with a deactivated inner surface with respect to hydroxide ions. 6. The machine according to claim 1, characterized in that one window located on the front panel of the machine is intended for dispensing water bottles and accessories. 7. The machine according to claim 1, characterized in that different windows located on the front panel of the machine are designed for dispensing water bottles and accessories. 8. The machine according to claim 1, characterized in that the connection of the catholyte supply line to the technological elements of the water purification unit is made in the form of an ejector, or a branch pipe, or an injector.

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