LT4935B - Method and device for treatment of water - Google Patents

Abstract

The invention is in the field of water purification. The water stream is activated by a magnetic field followed by electroflotation to separate water from solids; then the water is illuminated by light, the wave band length of which is 0.15-600 m and is impacted by electrofield E and magnetic field H sinphasic impulses of 0.01-400 Hz. The process is finished by treating water with a magnetic field. The water processing equipment has a supply pipe with magnets attached, the pipe is connected with a tank that has electrodes inside, alternatively connected with the power supply poles. The tank contains pulp disposal, a container for relatively clean water, and the container is connected with the coaxial dielectric barrel, which has magnetic permittivity, two electrodes and an inductive coil inside. The barrel is covered with clear vinyl, has a light source above and a discharge pipe with magnets and a filter.

Description

The present invention relates to the field of water treatment, namely to the production of drinking water from open water sources and to the treatment and decontamination of industrial and domestic wastewater, in particular to the treatment of water flux by light, magnetic and electric fields. The invention can be applied to water purification for technical and other purposes.

Known water treatment method in which effluent is irradiated with ultraviolet radiation modulated in the frequency range of 12-25 kHz and simultaneously subjected to high voltage electrical pulses (Patent RU

1114623, publ. September 23, 1984).

The disadvantage of this method is that a high level of purity of the water stream cannot be achieved because it is not possible to selectively influence the ionic composition of the water stream. In addition, the reaction rate is temperature dependent.

A water flow processing system based on the effects of electric and magnetic fields on a moving fluid flow using a power supply adapted to variable coil length, diameter and impedance is known (WO 9714655, publ. 24.04.1997). This system is used to remove mineral deposits.

The closest is the water treatment method, which involves treating the water stream with a coagulating reagent followed by electrical discharge pulses with a specific energy of 15 kJ / dm ³ , flotation, biological treatment and sorption by carbon filters (Patent RU 2099290, publ. 199712 20).

The disadvantage of this method is the high specific cost per unit volume of energy, the use of reagents and biological treatment.

The object of the invention is to completely eliminate the reagents to obtain the required purity of water at a reduced cost of a specific volume of 30 vol.

The object is achieved in that in a water flow treatment method comprising flotation, impulse effect of the electric and magnetic field and separation of impurities by filtration, the flow of water is first activated by magnetic field, followed by electroplotation and separation of the slurry, Length is selected in the range 0.15-600 μίη, and is affected by the electric field E and magnetic field H with pulsed onset pulses. Completes water treatment with magnetic field and filtration.

The device for treating the flow of water has a feed tube on which magnets are attached. The water supply pipe is connected to a tank containing electrodes, connected every second to the same poles of the first power supply. The upper part of the tank is equipped with a sludge drainage device and a relatively clean water collector, which is connected via an internal tank to an external tank (housing). The first reservoir is equipped with a first electrode, and the outer reservoir is equipped with a second electrode. A hermetically sealed inductance coil is mounted on the outer surface of the inner reservoir which is enclosed by the outer reservoir. The cross-section of the outer reservoir (housing) is covered with a transparent plate so that there is a space between the inner reservoir cross-section and the transparent plate for the fluid to pass from the inner reservoir to the outer reservoir. A light source is placed on the outside of the plate. At the opposite end of the outer reservoir is a tubular outlet with an outlet tube containing magnets and a filter. The first and second electrodes are connected to opposite poles of the second power supply, and the inductance coil is connected to the third power supply.

The inner reservoir is made and mounted inside the outer reservoir such that its feed cut area is equal to the working incision area between the inner reservoir outer wall and the outer reservoir inner wall, as well as the working incision area between the inner reservoir cross section and the transparent plate.

The inner reservoir and the outer reservoir are made of dielectric magnetically permeable material and are coaxially connected.

The invention is illustrated in the drawings, in which FIGS. 1 is a general diagram of the proposed method and apparatus, FIG. 2 is an electrical diagram of the proposed method and device, FIG. 3 shows an overall view of a method for treating the water flow of a particular device, FIG. 4 is a vertical axial section of a housing for illuminating a stream of water and simultaneously acting on electric and magnetic fields.

The proposed method is based on a water flow treatment sequence and comprises the sequential steps of water flow activation (step A, Fig. 1) with weak magnetic field H _b electroplating (step B), sludge removal, and obtaining relatively clean water. The water is then illuminated simultaneously (stage C) by light I of wavelength range from far infrared to vacuum ultraviolet in the range of 0.15600 gm and is affected by electric field E and magnetic field H with pulsed onset pulses. The optimum effect is obtained by using crossed fields. The water flow treatment is completed (step D) by a second addition of water to the weak magnetic field H2 and filtration.

In the proposed process, the water stream is purified by a complex of physico-chemical processes accompanying the operation of the water stream simultaneously with light irradiation and pulsed electric and magnetic fields without the use of reagents.

The pulses of electric field E and magnetic field H are selected according to the characteristics of the water flow to be treated: they can be high-current or low-current and their frequency is selected in the range 0.01 - 400 Hz. Amplitude, frequency, width, phase, etc. of pulses of electric field E and / or magnetic field H, etc. can be modulated and also pulses can be in wave mode.

The wavelength of light is selected according to the nature and level of the contamination, from far infrared to vacuum ultraviolet in the range 0.15-600 μτη., The waves can be modulated in the frequency range 0.1-20 kHz, can be both wide-spectrum and monochromatic.

The proposed method may be implemented by a device having a feed tube 1 (Fig. 3) on which magnets 2 (permanent or electromagnets) are mounted. The feed tube 1 is connected to a capacitance 3, within which are located electrodes 4, for example plates, which are connected to the same pole of the same high-current power supply 5 (Fig.2). A device (not shown in the drawing) is provided in the upper part of the container for discharging the sludge formed during the electroplating process in the form of rigid foams.

The upper part 3 has a collector 6 for relatively clean water, communicating through a grid or slits to the surface of the water to be treated. The collector 6 is connected to an internal reservoir 7 (Fig. 4), for example a cylindrical material made of dielectric high magnetic permeability material. A first electrode 8 is mounted on the outer wall of the inner reservoir 7, e.g. A second electrode 10 (counter-electrode), such as a ring, is mounted on the inner wall of the outer reservoir 9 made of dielectric high-magnetic permeability material near the outlet of the water flow. The first and second electrodes 8, 10 are connected to different poles of the second power supply 11. The outer surface of the inner reservoir 7 is wound by winding to form a hermetically insulated inductor 12 connected to a third power supply (generator) 13. The inner reservoir 7, together with the inductance coil 12 surrounding it, is enclosed by an outer reservoir.

9. The inner reservoir 7 is coaxially mounted on the holders inside the outer reservoir 9, which forms a cylindrical body, the cross-section of which is covered by a transparent plate 14 such that there is a continuous fluid passage between the inner reservoir 7 and the outer reservoir 9 The inner reservoir 7 is made and mounted inside the outer reservoir 9 so that its feed cut area is equal to the working area between the outer wall of the inner reservoir 7 and the inner wall of the outer reservoir 9, as well as the working area between the transverse and transparent plate. 14. On the outside of the plate 14, a light source 15 is connected to the fourth power source Ιό on the axis 7,9 of the reservoirs. At the opposite end of the external reservoir 9 is a tubular outlet 17 connected to an outlet pipe 18 (Fig.3) having magnets 19 and a filter 20. The inputs of the power supplies 5, 11,13,16 are connected to the corresponding outputs of the control unit 21 (Fig.2). .

In order to treat the flow of water with the device described above, a voltage of 1.7-2.5 V is applied from the power supply 5 to the electrodes 4 at a current density of 25-100A / m ² and changing the poles at a frequency of 0.01 Hz. A voltage of 0.01 to 400 Hz is applied from the power supply 11 to the electrodes 8, 10, generating pulses of electric field E of no longer than 5 gs. The inductance coils 12 supply current from the power supply 13 to produce a pulse of magnetic field H of a voltage of about 100 V in the frequency range of 0.01 to 400 Hz, such that the phases of the magnetic pulses H and electrical pulses E overlap; turns on the light source 15.

The treated water stream is fed through a feed tube 1, which in step A is activated by a magnetic field Hi, whereby equilibrium * 5 between the atoms and the excited elementary particles breaks down, including the anisotropy of force interactions and manifests itself in In this state, the flow of water enters the vessel 3 (stage B), where it supplies electrical pulses from the power supply 5 to the electrodes 4 with a voltage of 1.7-2.5 V and a current density of 25-100 A / m ² , changing poles 0, At 01 Hz.

The electric field formed on the electrodes 4 causes the following processes: sorption, extraction, flotation, ion exchange, crystallization. This results in electrocatalytic purification and decontamination of the water stream with flotation of solid impurities from the water. At the end of this stage, the bubbles on the electrodes flotate the solid impurities, collect the particulates, and help to colloid the particles by separating them in the form of a stiff foam, and the stream of relatively clean and clear water from the tank 4 flows into the collector 6.

From the collector 6 via a connecting pipe, the water flow through the inner reservoir 7 to the outer reservoir 9 enters the operating range of the simultaneously operating electric field E generated by the electrodes 8, 10, the magnetic field H generated by the inductor 12 and the light source 15. The electric field E and the magnetic field H act on the flow of water in pulses whose phases at the beginning of the pulses coincide.

Under the conditions of electric E and magnetic H fields and in the presence of oxygen and hydrogen produced on the electrodes, oxidation-reduction processes take place, and at the same time photochemical processes take place under the influence of light. It was found that the most efficient treatment is performed under the operating conditions of crossed fields.

The control unit 21 and power supplies 5, 11, 13, 16 regulate all basic treatment parameters depending on the nature of the contamination and the purpose of the water to be treated.

Subsequently, the water flow through the conduit 17 in the outer reservoir 9 of the coaxial housing passes into the outlet conduit 18 (step D), where the flow is additionally subjected to a weak magnetic field H ₂ , analogous to the magnetic field Hi in the feed pipe 1. Inlet 5 and outlet 3, as well as the flow rate of water in the inner and outer reservoirs of the coaxial housing 7.9, are uniform.

In the listed steps, the solid impurities released are collected by filtration and the water stream becomes biologically active after magnetic activation.

A concrete example of a water treatment method implementation.

Purified open water, containing: 20-40 mg / l of suspended matter, 1000-500 units / ml of bacterial flora and BOD of 100 mg / l.

The initial flow was fed by spontaneous flow (= 300 mm / s) through a dielectric feed tube 1 (Fig.3). The aqueous stream treated with a weak magnetic field (0.001 A / m) in the dielectric feed pipe 1 mounted two magnets aid falls within about 0.5 m ³ volume of tank 3 (this corresponds to 5 m ³ / h. Capacity).

The bottom of the capacitance 3 is provided with flat electrodes 4 with a total area of 25 m ^{2 in} this particular example and a height of at least 1/2 of the capacitance 3. A voltage of 1.7-2.5 V is applied to the electrodes connected to the same power supply pole every second; current density 25-100 A / m ² , total current not more than 1000 A. The pole changes at 0.01 Hz.

Flow rate between electrodes 4 plates 0.7 mm / s. Separates solids and coagulated colloids from electroflotation in the form of elastic foam by collecting the foam from the surface with a special scraper device into a sludge reservoir.

The sludge flow - relatively clean water - at the surface of the treated water passes through special filtration slits in the upper part of the tank to an adjacent collector 6, which automatically (300 mm / s) drains into the inner reservoir of the coaxial housing 7.

The annular electrodes 8, 10, provided inside the inner reservoir 7 and the outer reservoir 9 of the coaxial housing, supply an alternating voltage within 12 V at a current density of about 10 A / m ² . The pulse rate in this example was 10-25 Hz. The frequency is selected depending on the composition of the water to be treated.

The required magnetic field was maintained by a generator 13 using a voltage of about 100 V at frequency synchronous electric field pulses, provided that the magnetic field pulse duration τ did not exceed 5 ps.

The stream of purified water is discharged through the conduit 17 of the outer reservoir 9 of the coaxial housing, further exposed to a weak magnetic field in the dielectric discharge conduit 18, analogous to operation in the conduit 1.

The filtered water treated by the proposed treatment process contains less than 1 mg / l of suspended matter, no more than 3 l / l of bacterial flora and its BOD7 of about 5-10 mg / l.

The dependence of the productive capacity of the unit on some parameters of the unit is presented in Table 1.

Table: Dependence of production capacity on some device parameters

Production capacity, m ³ / h. Electrode area, m ² General electrodes current, A Water purpose Electrodes material Set power, kW 0.1 5 380 Drink Titan 1 0.1 5 380 Home Note Steel 1 1.0 15th 1100 Home Note Steel 2.7 5.0 25th 1875 Home Note Steel 4.7 10.0 37 2800 Buit. photo Steel 7.0 20.0 50 3800 Buit. photo Steel 9.5

The inner and outer reservoirs 7, 9 do not necessarily have to be cylindrical. They can be of any diameter and can be made of different materials. Likewise, the electrodes 8,10 do not necessarily have to be circular, and the electrodes 4 do not necessarily have to be flat and positioned vertically.

Claims (12)

Definition of the Invention 1. A method of treating a stream of water, comprising flotation, pulsed operation of electric and magnetic fields, and separation of impurities by filtration, characterized in that the feed stream is pre-activated by a magnetic field, followed by electroplotation and sludge removal, followed by light rays, electric field E and magnetic field H pulses, and completes the water treatment with the subsequent action of the magnetic field. 10th 2. A method for treating a water stream according to claim 1, characterized in that the electroflotation is carried out by applying a flow of water with an electric current of density up to 25-100 A / m ² and a frequency of pole change of 0.01 Hz. A method for treating a water stream according to claim 1, wherein said method is different 15 using weak current currents in the electric field E and / or the magnetic field H in the frequency range 0.01-400 Hz. 4. A method for treating a water stream according to claim 1, characterized by using high currents electric field E and / or magnetic field H 20 pulses starting from 0.01 to 400 Hz, starting in a phase. ^{5 6} 5. A method of treating a water stream according to claim 3 or 4, characterized in that the pulse amplitude, frequency, width or phase of the electric field E and / or magnetic field H are modulated by the action of the water stream. 6. A method for treating a water stream according to claim 3 or 4, characterized in that the pulsed electric field emits pulses of electric field E and / or magnetic field H in the wave mode. 7. The method of treating a water stream according to claims 1.3-6, wherein the water stream is illuminated by light having a wavelength in the range of 0.15 to 600 µLm from far infrared to vacuum ultraviolet and selects energy according to the nature of the water flow components. • 5 8. A method for treating a water stream according to claims 1.3 to 7, characterized in that the light is modulated at a frequency of 0.1 to 20 Hz. 9. A method of treating a water stream according to claims 1.3 to 7, wherein the light is monochromatic. 10. A water flow treatment device having means for treating the flow of water with electric and magnetic fields, characterized in that it has a feed tube (1) on which magnets (2) are applied. 15 pipe (1) connected to a tank (3) with electrodes (4) inside, connected every second to the same poles of the first power supply (5), a sludge discharge device in the upper part of the tank (3) and a relatively clean water collector ( 6), connected via inner reservoir (7) to outer reservoir (9), first electrode (8) mounted in inner reservoir (7), in outer reservoir 20 (9), a second electrode (10), a hermetically sealed inductance coil (12) mounted on the outer surface of the inner reservoir (7), the outer reservoir (9) being covered by a transparent plate (14), so that there is a gap between the cross-section of the inner reservoir (7) and the transparent plate (14) for the liquid to pass to the outer reservoir (9), outside the plate (14) 25 is provided with a light source (15) having a tubular outlet (17) at the opposite end of the outer reservoir (9) with an outlet tube (18) having magnets (19) and a filter (20) when the first and second electrodes (8,10) are connected. with the second power supply (11) and the inductance coil (12) connected to the third power supply (13). The water flow treatment device according to claim 10, characterized in that the inner reservoir (7) is made and mounted inside the outer reservoir (9) so that its feed sectional area is equal to the working incision area between the outer wall of the inner reservoir (7) and the inner walls of the outer reservoir (9), o - 5 also for the working area between the cross-section of the inner reservoir (7) and the transparent plate (14). Water flow treatment device according to claims 10 and 11, characterized in that both, the inner reservoir (7) and the outer reservoir (9) are manufactured. 10 of a dielectric material having a magnetic permeability and coaxially connected.