RU2333157C1 - Device for electrochemical treatment of liquid mediums and method of its usage - Google Patents

Abstract

FIELD: technological processes; chemistry.

SUBSTANCE: device contains direct current source with pole selector switch and unipolar electrodes, one passive and at least two active ones, at that passive electrode is installed in reservoir made of ion-conducting material, and active electrodes are fixed at brackets that have been installed on this reservoir. Method of device usage consists in immersion of active electrodes into processed medium, and passive one is placed into reservoir filled with water, at that reservoir with passive electrode is installed in the centre of treatment zone, and active electrodes - in radial directions in respect to this reservoir.

EFFECT: simplification of device design; provision of its compactness at high efficiency of treatment and expansion of technical resources.

4 cl, 1 dwg

Description

The inventions relate to the processing of liquid media by electrochemical unipolar activation (ECA), which allows to give these media stable and metastable properties that vary in a wide range, and can be used in various fields of human activity, in particular in everyday life, in medicine, in agriculture, etc. P.

Known devices for ECA - treatment of liquids, the main unit of which is an electrochemical reactor made in the form of an electrolyzer, divided by a diaphragm from an ion-permeable material into two chambers, a cathode and anode, in each of which there are unipolar electrodes connected to the corresponding pole of a direct current source ( for example, Patent RF No. 2221753, С02F 1/46, publ. 2004) (1).

The disadvantages of such installations are their large dimensions and the small effect of the electrostatic field on the medium being treated due to the large interelectrode distance, which reduces the efficiency of ECA; limited technological capabilities.

Known devices for ECA-processing of liquids in which the disadvantages of solution (1) are partially eliminated by reducing the interelectrode distances and increasing the number of plate electrodes, for example, a flow ECA containing a packet of plate electrodes, cathodes and anodes, and filtering diaphragms separating them (US Pat. RF No. 2167822, С02F 1/46, publ. 2001) (2)

The disadvantages of such devices are their difficulty in manufacturing and the limited possibilities of their use due to the small processing zone.

The closest to the proposed technical essence and the achieved result is an ECA-processing device for liquid media, in particular waterlogged soil, containing a direct current source with a pole switch and unipolar electrodes, active, i.e. acting on the processed medium, and passive, i.e. isolated from the medium to be treated, and the device contains several active electrodes and a single passive electrode located inside the tank with water, the bottom of which is made of ion-conducting material, and the walls are made of insulating material (AS USSR No. 1308219, A01B 47/00, publ. 1987 g.) (3).

The method of using this device is that several active electrodes are immersed in the medium to be treated, and a single passive electrode is immersed in a container filled with water made of an insulating material with a bottom made of ion-permeable material, which is in contact with this medium, while the active electrodes are placed throughout processing zone, and a container with a passive electrode is placed above them.

The device and method (3) are taken as prototypes of the proposed device and method of its use. The disadvantages of these solutions are the complexity of the design of the device and its large metal consumption, as well as the limited scope of both the device and the method.

An object of the invention is to simplify the design of the device and ensure its compactness with high processing efficiency, as well as expanding technical capabilities and, as a consequence, the scope.

The technical result is achieved by the fact that in a device for electrochemical processing of liquid media containing a direct current source with a pole switch and unipolar electrodes, at least two active and one passive, the passive electrode being placed inside a tank filled with an aqueous solution or water with a bottom of a waterproof ion-conducting material , new is that the said container is made with walls of a waterproof ion-conducting material, which increases the volume of the electrostatic field while the active electrodes are quickly connected to the brackets of at least two mounted on this container in radial directions, which simplifies its design and operation, provides compactness due to collapsible manufacturing, as well as versatility due to multivariate assembly.

To increase the efficiency, the active electrodes are made in the form of pipes and / or plates, flat or arched, the surface of which is mesh, and / or perforated, and / or solid, which also allows you to vary the value of the electrostatic field due to the contact surface area, and also further increase its versatility.

The technical result is also achieved by the fact that in the method of using the proposed device, comprising immersing at least two active electrodes in the medium to be treated, and a single passive electrode in a container filled with an aqueous solution or water with a bottom of a waterproof ion-conducting material in contact with this medium, something new is that a container with a passive electrode, made with walls of a waterproof ion-conducting material, is immersed in the medium to be processed in the center of the treated zone They are, and the active electrodes are installed in at least two radial directions relative to the capacitance, which ensures an increase in the processing efficiency of the medium due to a more uniform distribution of the electrostatic field over the treatment zone.

The technical effect is also ensured by the fact that the active electrodes in the form of tubes and / or plates, flat or arched, with a mesh surface, perforated, solid, are installed with an interval between them oppositely to each other in each radial direction in a sequence from the center to the periphery, first mesh then perforated, then continuous, at least one in each direction, which also increases the processing efficiency due to a more uniform distribution of the electrostatic field, um increase in the degree of electrochemical activation and the reduction of electrolysis, ie increase the redox potential of the environment.

An example embodiment of the invention is shown schematically in the drawing.

A device for ECA-processing of liquid media, in particular water, aqueous solutions, waterlogged soil, contains a direct current source 1 with a pole switch 2 and 3, to which the unipolar electrodes 4 and 5 are connected, respectively. The electrode 4, which is passive, i.e. not interacting with the medium being processed, it is made single and placed in a container 6 made with walls and a bottom of a moisture-proof ion-conducting material and filled with water or an aqueous solution. The electrodes 5, which are active, i.e. interacting with the medium, made in an unlimited number, but not less than two, depending on the volume of the medium, while they can have a tubular shape with a tubular electrode 4, in particular for processing large areas of soil. Mostly the electrodes 5 are made in the form of plates, flat or arcuate, the working surface of which can be made mesh, and / or perforated, and / or solid. The electrodes 5 are connected quickly with a bracket 8, while they can be rigidly mounted on it, and can be freely suspended, and the bracket 8 can be simultaneously an electric collector connected to the pole 3. Brackets 8, the number of which is determined depending on the size of the processing zone , but not less than two, are mounted on the tank 6 in radial directions, through quick disconnect connections.

A method of using the described device is as follows.

The device is autonomous, i.e. not tied to a specific electrolyzer, and can be used in any container or without it, in particular in soil. To use the device, it is pre-assembled, for which, depending on the size of the processing zone, for example, tank 7, brackets 8 are mounted on the tank 6, and electrodes 5 are mounted on them, the number of brackets, electrodes on each of them and the intervals “a” between them determined by calculation or empirically. For a more uniform distribution of the electrostatic field with a large volume of medium 9 and, accordingly, a large number of electrodes 5 (at least three on each bracket), the electrodes are mounted on the bracket in the sequence from the center to the periphery: mesh, then perforated, then continuous, at least one on each bracket. With a smaller number of electrodes 5, any of the modifications may be absent.

The assembled device is immersed in the medium to be processed, for example, in the electrolyzer 7, while the container 6 is installed in the center of the treated zone, and the electrodes 5 are placed over the entire volume of the medium 9 in radial directions opposite to the electrode 4 and relative to each other in each direction. The electrodes 4 and 5 are connected to the poles 2 and 3. The capacity 6 is filled with water or connected to a source of running water (not shown), the device is ready for operation.

The essence of the process of electrochemical activation of a liquid through the proposed device is as follows.

During the electrochemical treatment of a liquid medium, for example, water or its solutions in an electrolytic cell 7 or waterlogged soil, a reagentless change in acid-base (pH), redox (eh) and other parameters of the liquid occurs, which gives it new functional properties, in t .h. catalytic and biocatalytic activities, various during cathodic or anodic processing.

During cathodic treatment, “-” is applied to active electrodes 5 and “+” to passive electrode 4, as a result of which liquid 9 in electrolyzer 7 (or in soil) turns into catholyte, which is saturated with reduction reaction products, namely metal hydroxyls formed from dissolved salts, hydroxides, hydrogen.

An example of basic reduction reactions in the cathode zone:

OH ^- + H ₂ O → H ₃ O ₂ ^- + H ₅ O ₃ ^- + H ₇ O ₅ + ....

MeCl + OH ^- → MeON + Cl ^-

During anode treatment in the zone of (+) electrodes 5, the anode zone (anolyte) is saturated with oxidation products, including acids synthesized from dissolved salts, oxygen, and chlorine.

Examples of basic oxidative reactions in the anode zone:

Oxygen compounds of chlorine, in addition to their own high oxidizing ability, also participate in the reactions of catalytic oxidation of biological media, thereby causing significant biocidal activity.

In addition, during unipolar electrochemical processing of liquid media, in addition to electrochemical reactions on the electrodes, the water system is activated (excited) and it acquires excess internal potential energy.

In addition to structural energy changes in the environment and its acquisition of excess internal potential energy, there are other factors affecting the catalytic and biocatalytic activity of anolyte and catholyte, namely

- the formation of long-lived dissipative structures formed in the space charge region near the surface of the electrodes, both free and in the form of hydrated shells of ions, molecules, radicals, atoms, which gives the anolyte and catholyte the catalyst properties of both chemical and biochemical reactions, as it contributes to a change activation energy barriers between interacting components;

- the formation of highly active unstable products of electrochemical reactions, the time of which is limited to several hours (for example, free radicals);

- the activated state of the treated water system by the unipolar electrochemical method is manifested by the anomalous reactivity of catholyte and anolyte in redox reactions, in their catalytic, biocatalytic activity during interactions at the phase boundary, etc.

When unipolar electrochemical treatment of the aquatic environment:

- in the cathode zone, the catholyte acquires an alkaline reaction (from the initial pH of about 7 units to a pH of 8.0 ÷ 12 units). Its redox potential ЕН sharply decreases (from the initial еН within the range of 100-200 mV to -50 ÷ -700 mV on the scale of the indicator platinum electrode relative to the silver-silver reference electrode), the content of dissolved gases of chlorine, carbon dioxide, oxygen decreases, and the concentration of hydrogen increases ;

- in the anode zone, the acidity of the system increases from the initial to pH 2 ÷ 6 units. eH increases from the initial to 300–1200 mV. The content of chlorine and oxygen increases.

The proposed device together with the method of its use is the easiest to manufacture and use in comparison with the known analogue, while it is compact and versatile, can be used in all areas of human activity, in particular for the destruction of pests and pathogens, to increase biological activity the human or animal body, as well as plant seeds, to increase soil fertility, etc., in an environmentally friendly and harmless way, i.e. without the use of chemicals.

Claims (4)

1. Device for electrochemical processing of liquid media, containing a direct current source with a pole switch and unipolar electrodes, a single passive and at least two active, and the passive electrode is placed in a tank filled with water or an aqueous solution, made with a bottom of a waterproof ion-conducting material, characterized in that the capacitance for the passive electrode is made with walls of a waterproof ion-conducting material, and the active electrodes are quickly connected to the brackets, p at least two mounted on the container in the radial directions. 2. The device according to claim 1, characterized in that the active electrodes are made in the form of pipes and / or plates, flat or arched, the surface of which is mesh, and / or perforated, and / or solid. 3. The method of using the device for the electrochemical treatment of liquid media, comprising immersing at least two active electrodes in the medium to be treated, and a single passive electrode in a container filled with water or an aqueous solution, having a bottom of ion-conducting material in contact with this medium, characterized in that a container with a passive electrode made with walls of ion-conducting material is immersed in the medium to be treated in the center of the treated zone, and active electrodes are placed around it, at least her least two radial directions. 4. The method according to claim 3, characterized in that the active electrodes, made in the form of pipes and / or plates, flat or curved, with a mesh surface, perforated or solid, set in each radial direction with an interval between them, opposite to each other, in a sequence from the center to the periphery, first mesh, then perforated, then solid, at least one in each direction.