RU37985U1 - PORTABLE DEVICE FOR ELECTROCHEMICAL LIQUID TREATMENT - Google Patents

Description

Portable device for electrochemical liquid treatment

The utility model relates to the field of applied electrochemistry, in particular to portable devices for the electrochemical treatment of water and / or aqueous solutions with the aim of directionally changing their properties. The utility model is intended for use by a wide range of individual consumers, including private practitioners, and in various medical institutions, sanatoriums, rest homes, scientific laboratories in various operating conditions - both stationary and field.

The need to process water in order to provide the ability to manage its properties, purify it and improve its quality is the norm. In addition, obtaining solutions with specific, for example, disinfecting properties, is an urgent need of a person under any possible circumstances of his work and life. In the conditions of centralized water supply or upon receipt of solutions on an industrial scale, such problems are solved with the help of stationary units of relatively high productivity. However, at present, there is currently no effective tool for solving such problems if it is necessary to obtain a small number of solutions for various purposes, and even more so in the field.

Known portable installations that provide the processing of a small amount of water or aqueous solutions, implement the principle of placing the electrode system in a limited volume of water.

Known portable device for processing liquid, comprising a housing with an electrode system disposed in it, made in the form of a cylindrical coaxial inner anode, an external cathode and a diaphragm mounted between them (RF Patent No. 2040479, C 02 F 1/46, publ. 27.07.95) . Current leads are also located in the housing, and the device is equipped with a current source.

In the known device, it is possible to process solutions of various chemical compositions in the anode and cathode chambers, and, in addition, by changing the current parameters, it is possible to change the characteristics of the anolyte and catholyte, and to obtain the target product from both the cathode and the anode chambers.

C02F 1/46

standing, which increases energy consumption. Also in the known device it is impossible to obtain water or a solution that is a product of sequential processing, for example, first at the cathode, and then at the anode. In addition, in the known device, the properties of the obtained solutions depend on its absolute size and size ratio in the interelectrode space, and the use of each specific sample of the device, in particular in medicine, requires special research to standardize the resulting solutions and the actual device for electrochemical conversion of water or solution.

Portable electric water treatment devices implementing the flow principle of operation are also known in the cascade electrochemistry. However, the implementation of this principle in known installations leads to an increase in size, since the housing of the installation contains a tank with treated water, from which water flows by gravity into the electrode chamber of the device and is displayed to the consumer (Japanese Application No. 56152786 A, C02F 1/46, 1981). In addition to increasing the size of the installation, it is not possible to simultaneously obtain solutions from the anode and cathode chambers. It is also impossible to obtain solutions subjected to sequential electrochemical treatment, first in one and then in another electrode chambers.

A Microwater device is known that implements the flow principle of processing in the anode and cathode chambers (US Patent No. 5, 051, 161, C25B15 / 02, 1991), but this device has significant dimensions and is difficult to use as a portable one. In addition, in this device, the electrochemical processing stage is included in a permanent hydraulic strapping scheme, which allows you to receive products only with established characteristics. The known installation also does not provide for the possibility of processing in the electrode chambers of different compositions of solutions and in different modes, including the sequential processing of the solution, first in one and then in the other electrode chambers.

The closest technical solution is a portable device containing a body of dielectric material with electrodes placed in it - a cylindrical internal anode, an external cylindrical cathode mounted coaxially, a diaphragm located between the electrodes that separates the interelectrode space into the anode and cathode chambers, and current leads; moreover, the diaphragm is made of cylindrical ceramic based on aluminum and zirconium oxides and is mounted coaxially to the electrodes, the anode, cathode and diaphragm are rigidly connected to the electrode-diaphragm block, the anode and cathode chambers of the electrode-diaphragm block are equipped with means for input and output of the processed fluid, the block itself is rigidly fixed in the housing. Housing

made with holes in which quick-disconnect hydraulic connections and an electrical connector are sealed. Quick-disconnect hydraulic connections (for example, nipple ones) from the inside of the case are connected to the input and output means of the anode and cathode chambers of the electrode-diaphragm block, from the outside of the case hydraulic connections are connected to flexible pipelines, and the electrical connector inside the case is connected to current leads, and to the external the sides of the case - with a power source (RF patent No. 2204530, C02F1 / 461, 2003). This technical solution, called by the authors "STEL-Compact-01, is selected as a prototype.

The application of the known solution allows us to solve a wide range of problems, to ensure the effective treatment of water and / or aqueous solutions in various conditions using various modes.

The technical result of using this utility model is to increase the stability of the hydraulic circuit of the installation by eliminating the locking and regulating elements, simplify maintenance of the installation during its operation and provide the possibility of obtaining stable values of the parameters of the resulting solutions, as well as increase the life of its operation by reducing the contamination of hydraulic lines .

The specified technical result is achieved by the fact that in a portable device for electrochemical processing of a liquid containing a container for the liquid to be treated, a container for collecting anolyte and collecting catholyte, an electrode-diaphragm block made of a cylindrical inner anode, an external cylindrical cathode and a cylindrical diaphragm located between them ceramics based on aluminum and zirconium oxides, dividing the interelectrode space into an anode and cathode chambers, anode and cathode chambers electrode-d Afragmenny block are equipped with means for input and output of the processed fluid, the block itself is rigidly fixed in the housing, the housing is made with holes, and the unit contains quick-disconnect hydraulic connections and an electrical connector that are sealed in the openings of the housing, quick-disconnect hydraulic connections on the inside of the housing are connected to the means input and output of the anode and cathode chambers of the electrode-diaphragm block, the electrical connector inside the housing is connected to the current leads of the electrode-diaphragms a unit, and on the outside of the case with a power source, and the device contains a hose for supplying a processed fluid, a hose for catholyte outlet, anolyte outlet hose and an auxiliary hose, the hoses being made in the form of flexible pipelines, and the hose for supplying the processed fluid connects the container for the processed fluid with input means for the cathodic or anodic and cathodic chambers through quick-disconnect hydraulic connections on

equal connections on the outer side of the casing, and the anolyte and catholyte outlet hoses connect the anode and cathode chamber outlet means via quick disconnect connections on the outer side of the casing, respectively, to the containers for collecting the anolyte and catholyte, the hose for supplying the initial solution to the installation is made of at least 1900 mm of flexible tubes with an external diameter of 3 and an internal -1 mm, the anolyte outlet hose is made of a silicone tube with a length of at least 900 mm with an outer diameter of 2 and an inner diameter of 1 mm, and the catholyte outlet hose is made length of silicone tube with at least 900mm outside diameter 2 and an inner diameter of 1 mm, and the apparatus further comprises a hose for the output portion of the catholyte formed in the form of a flexible tube of 1200 mm in length with an outer diameter and an inner diameter of 1.5 0.3 mm. In addition, the container for the processed fluid may further comprise a pneumatic supercharger.

The outer and inner surfaces of the cylindrical diaphragm, as well as the outer surface of the anode, the inner surface of the cathode can be polished, and quick-disconnect hydraulic connections are made in the form of nipple joints.

With this implementation, all the advantages of the known solution are retained. The electrode-diaphragm block is placed inside the dielectric casing, which increases the safety of the installation and reduces its dimensions, since the dimensions of the casing depend only on the dimensions of the electrode-diaphragm block and do not affect the performance of the installation. The block itself is a rigid structure that maintains the constancy of the interelectrode distance, the coaxial arrangement of the elements of the block, which ensures the stability of the characteristics of the liquid processing and simplifies the maintenance of the device. The device may contain various means for supplying and removing processed fluids from the electrode chambers. They can be made in the form of various types of nozzles located either on the body of the electrodes themselves (or in the holes on the surface of the electrodes), or be part of a design that provides a rigid connection of the electrodes. The presence of liquid inlet and outlet means from the electrode chambers makes it possible to operate the device with a parallel liquid flow in them, or with countercurrent flow, which extends the functionality of the device. The device case is made with holes in which quick-disconnect hydraulic connections and an electrical connector are hermetically sealed. Sealing eliminates the ingress of liquids into the housing, which improves the operational characteristics of the device and increases its safety. The presence of an electrical connector allows the use of various power sources, both portable and stationary, which also extends the functionality of the device.

Quick-disconnect hydraulic connections provide the ability to quickly mount and disassemble the device. At the same time, the flow of liquid to the processing, as well as the removal and collection of processing products, is carried out through flexible pipelines using containers that are included in the equipment set of the device.

The device contains an auxiliary hose, which is made in the form of three segments of a flexible tube with an external diameter of 3 and an internal diameter of 1 mm connected by a tee. This allows you to mobile change the processing scheme of the initial solution.

The diaphragm of the block is made of cylindrical ceramic based on aluminum and zirconium oxides and mounted coaxially to the electrodes. Such a diaphragm is strong, resistant to aggressive reagents, has a constant pore size, has a hydrophilic surface, which reduces the likelihood of electrolysis gas bubbles adhering to the working surfaces of the diaphragm. The material of the diaphragm makes it possible to produce diaphragms of a sufficiently small thickness, which makes it possible to reduce energy consumption by reducing the interelectrode distance. However, even with a small thickness, such diaphragms have sufficient strength, and can withstand a relatively high pressure drop without changing their shape. This extends the functionality of the installation and provides standard characteristics of the resulting solutions. In addition, the diaphragm is easily regenerated from hardness salts, which are the main cause of contamination of the diaphragms during the processing of aqueous solutions.

The outer and inner surfaces of the cylindrical diaphragm, as well as the outer surface of the anode, the inner surface of the cathode are polished. This embodiment allows you to reliably operate the device in any position - horizontal, vertical, inclined. At the same time, the pressure of the processed liquid is sufficient for the effective removal of electrolysis gas bubbles and their presence does not affect the characteristics of the processing process.

In the device, it is advisable to use an electrode-diaphragm block containing a cylindrical coaxially mounted internal anode, an external cathode and a diaphragm made of ceramic based on aluminum and zirconium oxides, may also contain various additives, for example, yttrium oxide. The diaphragm divides the interelectrode space into the anode and cathode chambers. Aperture thickness from 0.5 to 0.7 mm. The electrodes are made of insoluble material during electrolysis: titanium electrodes coated with a mixture of ruthenium dioxide and titanium dioxide (ORTA), or titanium electrodes coated with noble metals, with coatings of manganese, tin, cobalt oxides can be used as anode materials; polished titanium, tantalum or zirconium, pyrographite coating or glassy carbon, and others can be used as cathode materials. The cathode, anode and diaphragm can be mounted in dielectric bushings. The bushings are made with the possibility of sealing the electrode chambers and the bushings are made channels communicating with the anode and cathode chambers, and the channels are displayed on the side surface of the bushings and equipped with nozzles. The magnitude of the interelectrode distance can be 2.5-4.2 mm.

The anode can be made in the form of one solid part or hollow inside, composed of several parts, which can be made of one or different materials, and interconnected using various methods (depending on the material), such as laser beam welding, vacuum welding, mechanical connection, etc. An axial channel can be made in the bushings, in which the anode is hermetically mounted, while threads can be made on the end parts of the anode, which allows you to place devices for fixing the block elements, which can be made in the form of clamping washers and nuts, on the ends of the bushings. Also, current leads can be connected to the end parts of the anode, and their placement will ensure uniform polarization of the anode.

It is advisable to use in the device electrode-diaphragm units of plants that have passed certification and produce certified disinfectant and sterilizing solutions. Can be used electrode-diaphragm blocks, described, for example, in the patents of the Russian Federation No. 2042639, 2078737.2145940 or US patent No. 5, 635,040.

The execution of the hose for supplying the initial solution to the installation of at least 1900 mm from a flexible tube with an external diameter of 3 and an internal 1 mm, and the output hoses of anolyte and catholyte from silicone tubes with a length of at least 900 mm with an external diameter of 2 and an internal diameter of 1 mm, allows to provide the required the hydraulic mode only through the use of hydrostatic pressure (the capacity of the processed fluid is set at a level exceeding the level of the housing with the electrode-diaphragm block by 0.5 - 1.5 m), since the hydraulic lines have a fixed flow resistance, and to exclude from the hydraulic circuit shut-off and regulating members, which require monitoring during operation, as noncompliance their operation causes instability characteristics of the resulting solutions. In the event that the conditions do not allow the use of the level difference of the installation elements, you can use the pneumatic supercharger of the tank of the processed fluid.

In FIG. 1 schematically shows an electrode-diaphragm block housed in a housing.

In FIG. 2 and 3 show the connection diagrams of the device, allowing to obtain disinfectant and washing solutions.

The device for processing liquid (Fig. 1) contains a housing 1, in which, using elastic (foam) gaskets 2, an electrode-diaphragm block is fixed. The block is made of an external cylindrical cathode 3, an internal cylindrical anode 4 (its end parts are shown in Fig. 1) and an annular diaphragm between them, dividing the interelectrode space into the anode and cathode chambers (not shown in Fig. 1). The anode, cathode and diaphragm are placed coaxially and rigidly fixed in the sleeves 5. On one sleeve 5 there are nozzles b and 7, on the other - nozzles 8 and 9. The nozzles 7 and 8 provide the input and output (or output and input) of the treated fluid, respectively cathode chamber, and nozzles 6 and 9, respectively, in the anode. Holes 10, 11, 12 and 13 are made in the housing, in which quick-disconnect hydraulic connections are sealed, connected inside the housing

respectively, with nozzles 8, 6, 7, and 9. A hole 14 is also made in the housing, in which an electrical connector is sealed that is connected inside the housing with current leads (not shown in FIG.).

The device also contains flexible pipelines 15,16,17 (FIGS. 2 and 3), a container for the fluid to be processed 18, a container for collecting anolyte 19, a container for collecting catholyte 20, a battery 21. The device may include an additional hose 22 made of three segments flexible tube 22a, 22b and 22c connected by a tee 23, and may also contain a hose to divert part of the catholyte 24, a device for creating excess pressure (not shown in the figures).

Depending on the conditions of the problem being solved, various hydraulic piping of the device elements and its operation are carried out.

In FIG. 2 shows a diagram of the hydraulic strapping of the device to obtain a disinfectant solution - anolyte of a neutral electrochemically activated type ANK (pH 6.8 - 7.8, redox potential relative to the silver chloride reference electrode (ORP) - plus 400 - plus 800 mV, the concentration of oxidants in the range of 100 - 400 mg / l) from the initial solution of sodium chloride with a concentration of 0.5 - 5.0 g / l.

This solution can be used in accordance with the existing permissions of the Research Institute of Disinfectology in dental offices, in clinics, in rural hospitals.

to the quick-disconnect hydraulic connection 12, which provides the supply of the medium to be processed into the cathode chamber, a tank 18 with the initial solution to be processed is connected using a flexible pipe 15 — a hose for supplying the liquid to be treated. From the hydraulic connection 10, the solution subjected to processing in the cathode chamber using the auxiliary hose 22a and 22b is fed to the hydraulic connection 13, which provides the solution in the anode chamber. From the hydraulic connection 11, the finished solution through a flexible pipe 17 - anolyte outlet hose enters the tank for collecting anolyte 19 (anolyte is the target product). The tee 23 of the auxiliary hose through a section 22c is connected to the output hose of a part of the catholyte 24 to drain part of the solution processed in the cathode chamber into a container for collecting catholyte 20.

The feed solution for processing from the tank 18 is provided either by supplying the tank 18 with a device for increasing pressure, or due to hydrostatic pressure. In this case, as shown in the figure, the container 18 is located at a height of 0.5 -1.5 m with respect to the plane in which the housing 1 is located.

Fig. 3 shows a diagram of the hydraulic strapping of the device to obtain an anolyte type A disinfectant solution (pH less than 5.0, ORP - plus 800 - plus 1200 mV, the oxidant content of 180-500 mg / l) and type K catholyte detergent solution (pH more than 9, ORP - minus 700 - minus 820 mV). Solutions are produced in countercurrent of the treated liquid (initial sodium chloride solution) in the anode and cathode chambers of the electrode-diaphragm block.

To quick-disconnect hydraulic connections 12 and 13 (Fig. 3), providing a supply of the medium to be applied to the anode and cathode chambers, by means of a flexible pipe 15 of the feed solution supply hose - and by means of an additional hose made of segments of the flexible tube 22a, 22b and 22c connected by a tee 23, a container 18c is connected with the initial solution to be processed. From the hydraulic connection 10 through a flexible pipe 16 — the catholyte outlet hose — a solution is discharged that has been processed in a cathode chamber (type K catholyte, i.e. with a pH of more than 9) and is fed to the catholyte collection tank 20. A ready-made solution from the hydraulic connection 11 ( type A anolyte, i.e., with a pH of less than 5) through a flexible pipe 17 - anolyte outlet hose - enters the tank 19 to collect the anolyte.

The connector 14 of the housing 1 is connected to the battery 21. The feed solution for processing from the tank 18 is provided either by supplying the container 18 with a device for increasing pressure (not shown in the figure), or due to hydrostatic pressure. In this case, the container 18 is located at a height of 0.5 - 1.5 m with respect to the plane in which the housing 1 is located.

The utility model is illustrated by the following examples, which, however, do not exhaust all the possibilities of its implementation.

The device according to a utility model is included by the authors in the STEL-Compacf series of devices and is intended to produce an electrochemically activated anolyte ANK or A, as well as catholyte K from the initial aqueous solution of sodium chloride with a concentration of from 0.5 to 5.0 g / l. To prepare the initial solution, either chemically pure salt and distilled (or purified for hemodialysis) water are used, or ordinary table salt and ordinary tap water, or natural fresh water from surface or underground water sources.

The electrode-diaphragm block of the device used in the examples contained a cylindrical inner anode with a diameter of 8 mm, a ceramic diaphragm made of ceramic based on a mixture of aluminum oxides, zirconium, promoted with yttrium (80 and a total of 20% by weight, respectively) 0.7 mm thick and 210 mm long , with a pore size of 0.8 μm, and an outer cylindrical cathode with an inner diameter of 14 mm. The electrodes and diaphragm were coaxially mounted in dielectric bushings. Axial channels were made in the bushings, in which the end parts of the anode with the thread applied to them were placed. The rigidity of the structure was ensured by gaskets and clamping elements - washers and nuts located at the ends of the bushings. Two channels were made in each sleeve, providing separate input and corresponding output of the solution to be processed into the anode and cathode chambers of the block. The interelectrode distance was 3 mm. The volumes of the electrode chambers are 10 ml of the cathode chamber and 7 ml of the anode chamber. The interelectrode distance is 3 mm.

Example 1. The device was used to obtain anolyte and catholyte from an initial solution of sodium chloride with a concentration of Zg / l in accordance with the scheme shown in FIG. 2. Table 1 shows the data on the prototype and on known installations of the same purpose.

When the same processing parameters were reached, the device according to the utility model entered the operating mode within 1 min after connecting, while the prototype device required an average of 15-20 minutes to install the shut-off and control elements of the hydraulic circuit in the required position. In addition, and when the device is working according to the prototype, as the practice of its use shows, it is necessary to periodically check the parameters of the obtained solutions, since the locking and regulating elements spontaneously change the process hydraulics over time, and when using the device according to the utility model, the hydraulics did not change. It should also be noted that the hydraulic lines of the installation according to the utility model have an increased service life (their operating time without fouling more than doubled).

Comparative technical characteristics of electrochemical plants Table 1 wok

com, to simplify the maintenance of the installation in the process of its operation and to ensure the possibility of obtaining stable values of the parameters of the resulting solutions, as well as to increase the resource of its operation by reducing the contamination of hydraulic lines.

Claims (5)

1. A portable device for the electrochemical treatment of a liquid, comprising a container for the liquid to be treated, containers for collecting anolyte and collecting catholyte, an electrode-diaphragm block made of a cylindrical internal anode, an external cylindrical cathode and a cylindrical diaphragm made of ceramic based on aluminum oxides and located between them zirconium dividing the interelectrode space into the anode and cathode chambers, the anode and cathode chambers of the electrode-diaphragm block are equipped with means for inputting and water of the processed fluid, the unit itself is rigidly fixed in the case, the case is made with holes, and the unit contains quick-disconnect hydraulic connections and an electrical connector that are sealed in the openings of the case, quick-disconnect hydraulic connections from the inside of the case are connected to the input and output means of the anode and cathode chambers the electrode-diaphragm block, the electrical connector inside the case is connected to the current leads of the electrode-diaphragm block, and on the outside of the case, from the source m of power, and the device contains a fluid supply hose, a catholyte outlet hose, anolyte outlet hose and an auxiliary hose, the hoses being made in the form of flexible pipelines, and the fluid supply hose connects the container for the fluid to be processed with the input means of the cathode or anode and cathode chambers through hydraulic quick couplings on the outside of the casing, and the anolyte and catholyte outlet hoses connect the output means of the anode and cathode chambers through the quick couplings on the outside to the side of the housing, respectively, with containers for collecting anolyte and catholyte, characterized in that the hose for supplying the initial solution to the installation is made of at least 1900 mm long from a flexible tube with an external diameter of 3 and an inner diameter of 1 mm, the anolyte outlet hose is made of a silicone tube with a length of not less than 900 mm with an outer diameter of 2 and an inner diameter of 1 mm, and the catholyte outlet hose is made of a silicone tube with a length of at least 900 mm with an outer diameter of 2 and an inner diameter of 1 mm, and the device further comprises a hose for outputting catholyte, made in the form of a flexible tube with a length of at least 1200 mm with an external diameter of 1.5 and an internal diameter of 0.3 mm. 2. A portable device for electrochemical processing of a liquid according to claim 1, characterized in that the container for the liquid to be treated further comprises a pneumatic supercharger. 3. A portable device for the electrochemical treatment of liquids according to claims 1 and 2, characterized in that the outer and inner surfaces of the cylindrical diaphragm, as well as the outer surface of the anode, and the inner surface of the cathode are polished. 4. A portable device for electrochemical processing of liquid according to claim 1, characterized in that the quick-disconnect hydraulic connections are made in the form of nipple connections. 5. A portable device for electrochemical processing of liquid according to claim 1, characterized in that the auxiliary hose is made in the form of three pieces of a flexible tube with an outer diameter of 3 and an inner diameter of 1 mm connected by a tee.