RU2630790C2 - Method of magnetizing drinking water - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: method consists in magnetizing drinking water with a magnetic flux passing through water, which is a sum of the magnetic fluxes formed by, at least, two radiating transformers with load inductances. The components of the magnetic fluxes of each transformer are formed due to the magnetic circuit, which is a winding of an insulated wire made of electrical steel with the formation of coils of large and small diameter followed by applying a rectified voltage to the resistance of this wire. The primary and secondary coils are wound on the turns of the large diameter of the magnetic circuit with the connection to the secondary load coil of inductance, which with the current passage therethrough generates a magnetic field. The directions of the magnetic strain vectors formed by one transformer together with the load inductance coincide. The direction of the summed vectors of each transformer by switching the polarity of the supply voltage can be one-sided, counter or opposite.

EFFECT: increasing the efficiency of magnetic processing, increasing the productivity.

2 cl, 2 dwg

Description

The present invention relates to devices for magnetic treatment of water. It can be used in the field of medicine, as well as in various industries, for example, in the power industry to prevent scale formation, in the building materials industry in the production of mortars and concrete in order to increase their strength, ductility, frost resistance, as well as in agriculture.

Closest to the claimed device is a device for magnetic water treatment (see Russian patent No. 2278826), including electromagnetic coils with cores installed in pairs against each other with the formation of pairs of poles, between which there is a tube for water passage, and an AC source connected through a rectifier with coils with the formation of a constant magnetic field between the poles, while the device contains 12 coils with 6 pairs of poles forming a field of one direction, each coil is equipped with It is connected with a U-shaped yoke, each yoke of 6 adjacent coils on one side of the tube is connected to each other with the formation of a hexagon, while the second coils of each pair are arranged with the formation of a six-pointed star, and the tube for water passage is made in the form of 5 turns of a rubber hose.

A disadvantage of the known device is the low productivity and low efficiency of water treatment by a magnetic field.

The technical result, which is provided in the claimed invention, is that instead of electromagnetic coils with cores, radiating transformers are used, one of the components of the magnetic flux of which is formed by winding an insulated wire made of electrical steel. As a result of this there is an increase in the energy density of the magnetic field passing through the water, as well as an increase in the productivity achieved by magnetizing a significant amount of water per unit time with the goal, for example, of accelerating the filling of pools of significant volumes of magnetized water of the required quality.

In FIG. 2 shows a diagram of the electrical connections of the elements of the device, FIG. 1 shows a device that implements these goals, which contains a housing 12, representing a cylindrical tube of significant volume, containing a working chamber 5, coaxially located perforated holes 6 of the plastic pipe 1 of smaller diameter. In the upper part, the housing is hermetically sealed by a cover 20 with an outlet 21. The pipe 1 contains at least two water magnetizing devices (emitting transphomarors), each of which is a transformer, the magnetic circuit of which is formed by a winding of an insulated wire made of electrical steel. The winding of the magnetic circuit is made with a wire around the plastic pipe 1 and is a small coil 4 and a large coil 3 of diameter. Between the coils 3 of large diameter pass coils of the input coil 7, the output coil 9 and the feedback coil 8. The load of the output coil 9 is the radiating inductance 11. The winding of the magnetic circuit, the winding of the output coil 9 and the winding of the radiating inductance 11 are connected in series or in parallel and, based on the principle of superposition, form a total magnetic field of one-sided direction. When connecting the feedback coil 8, which has the same direction of the turns with the input coil 7, in parallel or sequentially of the secondary coil 9, we obtain an increase in the current of the elements radiating the magnetic field and, as a result, an increase in the total magnetic flux vector. Thus, the connection of the rectified voltage to the magnetic circuit and the primary coil in the presence of a feedback coil can significantly increase the magnetization efficiency of a significant amount of water in a short time, which means it can increase the flow rate of magnetized water. When applying to the winding of the magnetic circuit and the input coil 7 of the rectified voltage, the current through the coil flows in a predetermined direction through the normally closed contacts of the intermediate relay. When the relay is turned on, the polarity of the input voltage changes and, as a result, the polarity of the total vector of the magnetic flux emitting the transformer changes. The polarity of the input value of the transformer determines the direction of the total magnetic flux emitted by the transformer and its inductor. When the polarity of the input voltage changes, the total magnetic flux changes direction by 180 degrees. The vectors of magnetic tensions generated by two transformers can have a consonant opposite and opposite directions. The magnetic fluxes of transformers passing through water have a mixed compressive tensile effect on water dipoles. Therefore, magnetized water is called in the first case of mixed magnetization, in the second - northern, in the third - southern. Therefore, to obtain water of a given quality, it is necessary to configure with the help of a relay such a direction of the magnetic intensity vectors that would correspond to the desired value of the quality of the obtained magnetized water. The entire transformer device is flooded with compound 2, followed by coating with a thin layer of food grade plastic.

The operation of the device is that, including the valve 19, water under pressure enters the cavity 16, moves the piston 17 (bellows), which through the rod 13 includes the contact 15, providing voltage to the emitting transformers. The water from the cavity 16 through the opening hole 18 and the hole 6 enters the working chambers 5 and 10, is magnetized and through the hole 21 comes out for its intended purpose. When closing the valve 19 and opening the valve 23 under the action of the spring 14, the contact 15 switches off the input voltage to the device. The function of the valves 19, 23 can be performed by a device having one actuator, for example a flywheel, according to Russian patent No. 2503504.

The device can be used both in static and in dynamic mode. To use the device in static mode, pour water into the working chambers, turn on the device and, after a specified time, select magnetized water through valve 22.

The device can be used, according to Russian patent No. 2469798 for a thermal shower, where magnetized water is used as hot and cold water.

Claims (2)

1. The method of magnetizing drinking water with a magnetic flux passing through water, which is the sum of the magnetic flux formed by at least two radiating transformers with load inductors, while the components of the magnetic flux of each transformer are formed by a magnetic circuit representing winding of an insulated wire of electrical steel with the formation of turns of large and small diameter with subsequent supply of a rectified voltage to the resistance of this wire and with subsequent by winding the coils of the primary and secondary coils onto large turns of a large diameter and connected to a secondary load inductor, which also emits a magnetic field when a current passes through it, and the directions of the magnetic stress vectors formed by one transformer together with the load inductance coincide, and the direction The total vectors of each transformer due to switching the polarity of the supply voltage can be one-sided, oncoming or opposite. 2. The method according to p. 1, characterized in that the feedback coil is additionally wound on the magnetic circuit, connected in parallel or in series to the secondary output coil, while the coils and inductance must form a current circuit.

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