RU2005126340A - METHOD OF COLD DRAINAGE AND CLEANING OF WATER AND DEVICE FOR ITS IMPLEMENTATION "METHOD OF LYAPIN-KALINICHENKO" - Google Patents

Claims (23)

1. The method of cold desalination and purification of any natural water to drinking water of the highest quality or active water and / or industrial water, which consists in exposure to water by electromagnetic fields, dispersion, ozonolysis, cavitation, filtration, separation and dilution of heavily contaminated water with water distillate, characterized the fact that water is excited in the pathogen at the molecular level by the combined, simultaneous, independent and controlled action of a constant and alternating electromagnetic field with impulse microwave fields are dispersed to a finely dispersed submicron level in a stream of ozone-containing gas with the application of a pulsed electromagnetic field with the formation and further maintenance of a two-phase gas-water mixture-emulsion to ensure its disinfection, the mixture-emulsion is subsequently subjected to repeated ozonation in the course of the process, and it is subjected to hydromechanical cavitation simultaneous simultaneous application of electrohydrodynamic shock to the mixture-emulsion from a spark discharge in an aqueous medium, supporting The emulsion mixture is finely dispersed by acoustic vibrations, filtered on porous filters in the presence of an ozone-containing gas to remove salts and organic impurities from the water stream, after which the water is sprayed in a pulsed electromagnetic field, followed by separation of the sprayed water in electrostatic fields of constant and variable intensity, and the number fields is determined by the number of components released from the water, a chemotronic distiller is used to dilute heavily contaminated water, and for electric second power source used pulsed high-voltage power supply with independent voltage and current output. 2. The method according to claim 1, characterized in that the frequency of the pulses for creating electric fields during excitation and cavitation is selected from the resonance condition of intermolecular bonds of water clusters. 3. The method according to claim 1, characterized in that upon excitation, dispersion and separation create a system of radial electric fields with an inhomogeneous distribution of the intensity vector along the height of the impact. 4. The method according to claim 1, characterized in that the excitation of the source water is carried out in crossed constant and alternating electromagnetic fields with the imposition of a pulsed microwave field with independent adjustment of their electrical parameters. 5. The method according to claim 1, characterized in that the dispersion of the sprayed source water and mixing it with an ozone-containing gas is carried out in the nozzle of the ejector of the jet apparatus with the application of a pulsed electromagnetic field onto the water stream. 6. The method according to claim 1, characterized in that the maintenance of the finely dispersed state of the gas-liquid mixture is carried out by acoustic vibrations. 7. The method according to claim 1, characterized in that the supply of ozone-containing gas is produced repeatedly during the flow of water. 8. The method according to claim 1, characterized in that during hydromechanical cavitation simultaneously and together with it, an electric discharge is applied to the water in an aqueous medium, the discharge being rotated in the discharge gap of the cavitator nozzle by an external electromagnetic field in a plane perpendicular to the water flow. 9. The method according to claim 1, characterized in that to obtain the highest quality water or active water in the separator, the water is sprayed by centrifugation, while charging it in a pulsed high-voltage electromagnetic field, followed by separation of finely dispersed water, the centrifugation and separation parameters being selected from the conditions of separation from water of heavy drops with a high content of salts and insoluble sediment, from pure water, and the number of electrostatic fields during separation is chosen depending on the specified amount wa extracted fractions. 10. The method according to claim 9, characterized in that in the separator, the separation of the finely divided aqueous mixture into fractions is controlled by changing the electrical parameters on the perforated electrodes: the magnitude of the voltage pulse amplitude and / or current and / or voltage pulse shape, and changing these parameters separately to each electrode. 11. The method according to claim 1, characterized in that the removal of impurities from the water stream is carried out with an excess of ozone-containing gas and repeatedly: in the cavitator, labyrinth, porous filters and separator. 12. The method according to claim 1, characterized in that for the supply of the pathogen, inkjet apparatus, cavitator, separator and chemotron distiller, a high-voltage source of pulsed power is used with independent adjustment of the output voltage, current, frequency and shape of the pulses. 13. The method according to claim 1, characterized in that the source water, the total salinity of which exceeds 50 g / l, is diluted with distillate obtained by passing part of the source water through a chymotron distiller, after which water vapor is condensed and the distillate is sent to dilute the source water. 14. Device for cold desalination and purification of any natural water to produce water of the highest quality or active water and / or industrial water, containing connected pipelines: water pathogen, jet apparatus, cavitator, labyrinth, porous filters, separator, chymotronic distiller and ozone generator, and also a source of high-voltage pulsed power supply connected with them, characterized in that in the exciter, electrodes for joint creation of electromagnetic fields are placed on top of its cylindrical body a, in a high-voltage discharge, and the channel of this discharge is rotated using an external device to create a rotating electromagnetic field, an electrohydroshock mechanism is used to acoustically shake the flow of water in the jet apparatus, cavitator and labyrinth, the separator is made of a cylindrical grounded body with a lid of insulating material, in which the mechanism of spraying water is made in the form of a grounded rotating vertical shaft inserted into the chamber with an anode attached to it and playing the role of a disk or disks surrounding the shaft of one cylindrical and one or several conical ring perforated high-voltage electrodes with an adjustable voltage on them, a chemotron distiller generates and delivers distilled water to the main line for diluting heavily contaminated water, the power supply of the pathogen, jet device, cavitator, separator and chemotronic distiller is a source of high-voltage switching power supply with independent current regulation and the output voltage. 15. The device according to p. 14, characterized in that the electrodes in the form of narrow plates with inputs for supplying direct and alternating voltage are built-in outside the dielectric tube of the pathogen, and a winding connected to a high-voltage switching power supply is placed on top of them. 16. The device according to 14, characterized in that the grounded output nozzle of the ejector of the jet apparatus is simultaneously an electrode, and the metal bell of the mixing chamber spaced from it by a gap is the second electrode and connected to a source of high pulse voltage. 17. The device according to 14, characterized in that the grounded fairing in the cavitator is located in the center of the critical section of the cavitator nozzle, and the nozzle wall is separated from it by a gap and connected to a high voltage pulse source so that they form a strong inhomogeneous field in the gap, providing spark breakdown of the gap. 18. The device according to 14, characterized in that on top of the housing of the cavitator placed a device that creates a rotating electromagnetic field at the level of the critical section of the cavitator. 19. The device according to 14, characterized in that the cavitator and the labyrinth have perforated zones in the walls for the selection of salts and organic impurities released from the solution. 20. The device according to p. 14, characterized in that on top of the cavitator and labyrinth housings are installed electro-impact flotators connected to a high-voltage switching power supply. 21. The device according to p. 14, characterized in that inside the cylindrical and grounded casing of the separator around a grounded rotating shaft with a disk or disks mounted on it, there is one cylindrical and one or more conical perforated electrodes connected to a source of high-voltage switching power supply. 22. The device according to claim 20, characterized in that the separator disk or disks are provided with sharp teeth on the periphery, while adjacent teeth of the disk are bent from its plane through one in different directions, up and down at an acute angle with respect to the plane of the disk. 23. The device according to 14, characterized in that the electrode located in the center of the critical section of the nozzle of the chemotron distiller has an outlet for grounding, and the nozzle wall has an outlet for supplying a high voltage pulse voltage, which ensures a plasma discharge between them.