RU2151104C1 - Process of water purification and gear for its implementation - Google Patents

Abstract

FIELD: equipment for purification of natural water for drinking water supply, of sewage, of water in circulating water supply and for cleaning of water from oil products. SUBSTANCE: water is treated in chambers of gear positioned in path of flow of purified water. Electromagnetic system made of insoluble and non-insulated flat electrodes manufactured in the form of U-shaped zigzags in which space flat electrodes forming solenoid are installed perpendicularly is placed in first and third chambers. Such design ensures treatment of water by activating-electrodestructive action in complex electric and electromagnetic fields mutually crossing one another in space at some angle and having different gradients of intensity of resulting electromagnetic fields. In second chamber water is treated in electric coagulator with soluble electrodes with slots and with altering polarity of cathode and anode. Potential applied to electrodes of electric coagulator is equal to potential across terminals of insoluble and non-insulated electrodes of first and third chambers. EFFECT: enhanced efficiency of purification of natural water, sewage and especially polluted industrial waste water, total avoidance of passivation processes on surface of soluble electrodes in electric coagulator. 3 cl, 6 dwg

Description

 The present invention relates to techniques for the purification of natural waters for drinking water supply, wastewater and water in water recycling systems, as well as for the purification of water from oil products, and can be used for the treatment of highly contaminated industrial effluents in the engineering, mining and oil refining industries.

 Known methods of water purification, which include treating it with an ozone-containing gas with a uniform application of a non-uniform electric field with medium intensity and with the movement of the flow of processing water in a direction perpendicular to the direction of the electric field, in the direction of decreasing its intensity / see a. with. 1130533, cl. C 02 F 1/46, 1982 /.

 A known method of water purification, selected as a prototype and described in a. with. 1130534, class C 02 F 1/46, 1982. This method involves electrical treatment with alternating current using a soluble anode, the electrical treatment being carried out in a constant magnetic field of 600-800 Oe, the induction vector of which is perpendicular to the direction of electric current in the treated water.

 Known electrocoagulator, selected as a prototype of the claimed technical solution / device / and described in A.C. N 994427, class. C 02 F 1/46, 1983. The known electrocoagulator comprises a housing with vertical plate soluble electrodes disposed therein, inlet and outlet water pipes. The electrodes are made with holes located in adjacent electrodes in a shaft order. An air distributor is located under the set of electrodes.

 The disadvantage of this method and the electrocoagulator is ineffective water treatment due to additional equipment for supplying and distributing air, additional operating costs for the acquisition and qualified care of this compressor equipment, in addition, introducing air into the water, before electrocoagulation, coupled with its own gas evolution , during the operation of the electrocoagulator, it reduces the yield of dissolved metal in current, these measures are aimed at reducing the formation of a passivating film on e ektrodah insufficiently effective and provide additional costs, without eliminating the causes of the passivation film on the electrode surface.

 The purpose of the invention is to increase the efficiency of purification of natural and wastewater, purification of particularly contaminated industrial effluents in the engineering, oil and gas and processing industries, mining and processing industries, simultaneously with high efficiency of various water treatment, to achieve the complete absence of passivating processes on the surface of soluble electrodes in electrocoagulator.

 This goal is achieved by the fact that in the method of water purification, including the treatment of water in an electromagnetic field, when the potential is applied to the soluble electrodes in the electrocoagulator, according to the invention, the water is initially subjected to an activating-electrodisstructive effect in mutually intersecting, complex, electric and electromagnetic fields, with the applied potential to insoluble and non-insulated electrodes equal to the potential applied to the electrocoagulator electrodes, then water is treated in an electric a coagulator with soluble electrodes with varying polarity on the cathode and anode, after which the water is subjected to an activating-electrode-destructive action in mutually intersecting complex electric and electromagnetic fields, with the potential applied to insoluble and non-insulated electrodes equal to the potential applied to the electrocoagulator electrodes, and exposure to weak electric current.

 This goal is achieved in that in a water purification device comprising a housing with vertical plate, soluble electrodes / cathode and anode / electrocoagulator placed therein and insoluble, non-insulated electrodes of electromagnetic systems separated by partitions into chambers lined with electrically conductive material communicated with each other using openings for the flow of purified water. In one of the chambers there are vertical, plate-like, soluble electrocoagulator electrodes, on the plate-shaped electrodes of which slots are made, and when viewed from the plane of the electrode, it looks like a zigzag. In other chambers located on both sides of the first chamber, electromagnetic systems of insoluble and non-insulated flat electrodes are placed. In this case, some insoluble and non-insulated, ribbon-shaped, flat electrodes are made in the form of U-shaped zigzags, in the space of which, as if embracing, other insoluble and non-insulated vertical flat electrodes that form a solenoid are perpendicularly mounted.

 It is the claimed constructive implementation and their placement in the chambers of the device, in the direction of the purified water, where the first chamber contains an electromagnetic system of insoluble and non-insulated electrodes, some in the form of U-shaped zigzags, others - vertical, in the form of a solenoid, in the second, middle soluble plate electrodes of the electrocoagulator are placed, and in the third chamber, an electromagnetic system of insoluble and non-insulated electrodes is again placed, one in the form of U-shaped zigzags, and the other - in the form of a solenoid, according to the method of treating water in the first chamber, an activating-electrodistructural effect is provided in complex electric and electromagnetic fields in mutually intersecting in space at an angle to each other and with a different intensity gradient of the resulting electromagnetic fields, with the potential applied to insoluble and uninsulated electrodes equal to the potential applied to the electrocoagulator electrodes. In the second, middle chamber, water treatment is carried out in an electrocoagulator with soluble electrodes with slots with varying polarity at the cathode and anode. And in the third chamber, the water is again subjected to an activating-electro-destructive effect in complex electric and electromagnetic fields intersecting in space. The above features ensure the achievement of the purpose of the invention, this allows us to conclude that the claimed invention is interconnected by a single inventive concept. Comparison of the claimed technical solutions with the prototype made it possible to establish compliance with their criterion of "novelty." In the study of other known technical solutions in the art, similar features were not identified in the claimed inventions, and therefore they provide the claimed technical solution with the criterion of "inventive step".

The drawings depict the inventive device:
in FIG. 1 shows a section of a device;
in FIG. 2 shows a sectional view of the device in plan;
in FIG. 3 shows a section of an electrocoagulator;
in FIG. 4 shows a section through a chamber 4 with an electromagnetic system;
in FIG. 5 shows a fragment of a section of an electrocoagulator with electrodes;
in FIG. 6 shows a block of soluble zigzag electrodes.

 A water purification device comprises a housing 1, the capacity of which is divided by partitions 2 and 3 into chambers 4, 5 and 6, inlet 7 and outlet 8 nozzles. Chambers 4, 5 and 6 with partitions 2 and 3 are lined with an insulating electrically conductive material 9. In one middle chamber 5, an electrocoagulation chamber, vertical, lamellar, soluble electrodes are placed 10. The electrodes 10 have slots 11 and when they look at the plane of the sheet, the plate electrode 10 has kind of zigzag. The electrodes 10 are connected to the current collector 12 with a special clamp. In other chambers 4 and 6, located on both sides of the first chamber 5, electromagnetic systems of insoluble and non-insulated flat electrodes 13 and 14 are placed. Insoluble and non-insulated, ribbon-like, flat electrodes 13 are made in the form of U-shaped zigzags in the space of which as if embracing, insoluble and non-insulated flat electrodes 14 are perpendicularly mounted, the installation of electrodes 14 in the space of U-shaped electrodes 13 form a solenoid. The electrodes 13, 14 are connected by conductors 15 to a power source with a potential equal to the potential applied to the electrocoagulator electrodes. In the partitions 2 and 3, holes 116 are made for the flow of treated water into the following chambers of the device.

 The device operates as follows: the source water through the pipe 7 is supplied to the lower part of the first chamber 4, where water in an upward flow passes in the space at the same time between the U-shaped zigzags of insoluble, uninsulated, metal electrodes 13 and perpendicular to the space between the U-shaped electrodes , flat metal insoluble and non-insulated electrodes 14, which form a solenoid. When the potential is applied to the insoluble, non-insulated flat electrodes 13 and 14, equal to the potential applied to the electrodes of the electrocoagulator 10, the water is subjected to an activating-destructive effect in complex electric and electromagnetic fields in mutually intersecting in space, at an angle to each other and with different sizes, inhomogeneous gradient of the intensity of the resulting electromagnetic fields, with the ratio of the maximum intensity to the minimum 2 - 12. Insoluble and non-insulated The electrodes, ribbon-shaped, flat with U-shaped zigzags, are installed and assembled in such a way that the currents passing through the electrodes form the vertical component of the electromagnetic field, and the gradient of the vertical component formed by the electromagnetic field is directed along the moving treated water, vertical electrodes 14, when current flows through them, they form the electromagnetic field of a separate conductor and the resulting / total / field, the intensity vector of which is directed perpendicular about the tension vector of the electrode system 13, and also perpendicular to the direction of the moving treated water. Under the influence of a whole complex of effects on a single molecule of an aqueous solution, with various impurities, the molecule is subjected to a powerful destructive effect of mutually intersecting electromagnetic fields, together with a number of simultaneous additional effects of weak electric currents passing through the volume of the treated water during its washing of uninsulated conductors with current, flowing weak currents in the aquatic environment, also induce additional weak electromagnetic fields in the moving water volume Acting at the molecular micro level. Due to the fact that the models of water systems are almost impossible to reproduce repeatedly for all indicators with great accuracy, the processes occurring in the water volume are poorly studied, or not fully studied. Water with a completely changed structure, when processed by the whole complex of influences in the primary processing chamber 4, enters the electrocoagulator chamber 5, in which soluble, plate electrodes 10 are placed with slots 11 made in them, giving the shape of an electrode in the form of a zigzag / Fig. 1 and FIG. 6 /, the electrodes 10 are mounted parallel to each other with alternating current polarity. The electrodes 10 are installed in the grooves in the insulating lining 9, the distance between the electrodes 10 is 8 to 12 mm, depending on the quality of the source water. After leaving the chamber 4, the treated source water is exposed to a new complex effect in the electrocoagulator, with the simultaneous dissolution of the metal of the electrodes 10, saturation of the water volume with aluminum or iron hydroxide / by quality necessity / together with the anodic dissolution of the metal in the volume, an electromagnetic field formed by passing current through the water volume and currents passing through the sections of the electrode 10 having slots 11, which create a zigzag shape, the current value of each zigzag section and the electrode is not the same and increases in arithmetic progression by the amount of current in a separate section of the zigzag electrode, reaching a maximum at the current collector 12. As a result, the gradient of the field strength around an individual section of the flat electrode and the gradient of the field strength of the sum of parallel sections are also not the same and changes upwards in arithmetic progression, to the point of removal of current in the electrode. This design of the electrodes with their installation according to a certain scheme, which allows to obtain electromagnetic fields of various configurations and sizes, makes it possible at the same time, already in the electrocoagulator, to achieve a high effect of water purification. In addition, slots 11 in the electrodes, dividing the electrode into sections, allow current to flow in one direction to create a total electromagnetic field around parallel sections, the intensity vector of which is perpendicular to the direction of water movement, the volume of water being treated, when it moves along the electrodes, is repeatedly processed perpendicular to its movement by the electromagnetic field of each section, the total value of the gradient of the field strength of each subsequent section changes proportionally, reaching a poppy the current collector 12. In addition, the slots in the electrodes allow the treated water to actively circulate, mix with the volume of water of adjacent sections of the interelectrode space, as it moves, and simultaneously be treated with a concentrated electromagnetic field in a narrow section of the slot 11, with a sharp increase in tension and repeated repetition of this effect, according to the number of slots 11 in the electrode 10. There is a powerful ionization in the electromagnetic field of the bubble of the released gas, which contributes more deeply water purification, since the treated gas acquires new qualities in the electromagnetic field.

 The treated water in two chambers 4 and 5 with the initially destroyed structure with a metal hydroxide, as a reagent in a finely dispersed state with a partially removed, partially captured by the stream of purified water by gas, enters the chamber 6, where the water is subjected to an activating-electrocoagulating action in complex, electric and electromagnetic fields in mutually intersecting in space, at an angle to each other, and with a varying inhomogeneous gradient in the intensity of the resulting electromagnets field, with the applied potential to insoluble and non-insulated electrodes equal to the potential applied to the electrodes 10 of the electrocoagulator. Under repeated complex exposure in the field of non-insulated flat metal insoluble electrodes 13 and 14, dissolved contaminants in the volume of water form powerful large flakes of suspended particles on the particles of dissolved metal hydroxide, the rate of their further deposition sharply increases compared to the usually traditional processing scheme, which allows achieving deep water purification from difficult to remove substances that are not removed by the usual method of electrical processing and other cleaning methods used. The design of the chambers in a single housing 1 of the device allows you to influence water systems in a continuous, inextricable flow, electrically connected to each other through the water volume of the treated water. All of the above measures at the same time prevent the formation of a passivating layer of carbonate deposits on the surface of the soluble electrode 10, which impede the normal operation of the electrocoagulator. A deep complex effect on the structure of the water system at the molecular level allows the device with an electrocoagulator to operate with high efficiency and, at very low current densities, to obtain the maximum possible cleaning effect.

Claims (3)

 1. A method of water purification, comprising treating water in an electromagnetic field with the application of potential to soluble electrodes in an electrocoagulator, characterized in that the water is initially subjected to an activating-electrodestructive effect in complex electric and electromagnetic fields that intersect in space at an angle to each other and with different the largest non-uniform gradient of the intensity of the resulting electromagnetic fields, then the water is treated in an electrocoagulator with soluble electrodes with varying polarity at the cathode and anode, after which the water is subjected to an activating-electro-destructive action for the second time in complex electric and electromagnetic fields that intersect in space at an angle to each other and with a different inhomogeneous intensity gradient of the resulting electromagnetic fields, with the potential applied to insoluble and non-insulated electrodes, equal to the potential applied to the electrocoagulator electrodes.  2. A device for water purification, comprising a housing with vertical plate soluble electrodes of an electrocoagulator placed therein, inlet and outlet water pipes, characterized in that the housing capacity is divided by partitions into chambers that are interconnected by openings for water passage, while in the middle chamber an electrocoagulator with vertical plate soluble electrodes is placed, in which slots are made in such a way that when viewed from the plane of the electrodes, they have a zigzag shape, and in others, On the cameras located on both sides of the middle chamber, electromagnetic systems are placed, each of which is made of insoluble and non-insulated flat electrodes, and some insoluble and non-insulated flat electrodes are made in the form of U-shaped zigzags, in the space of which other insoluble and non-insulated vertical flat electrodes forming a solenoid, while a potential equal to the potential applied to the terminals e is applied to insoluble and non-insulated electrodes ektrokoagulyatora with soluble electrodes.  3. The device according to p. 2, characterized in that the walls of the chambers are lined with electrically conductive material.

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