SU990681A1 - Apparatus for complex activation of liquid - Google Patents

Description

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The invention relates to a technique for treating liquids, including its mechanical to magnetic activation, gas saturation, and can be used in industry, agriculture, medicine, and veterinary medicine. Known apparatus with an external arrangement of coils of electromagnets. Inside (the body of such an apparatus, representing; a steel pipe, there is a magnetic core jjl.

However, such electromagnets have a small radius of action. So, at a distance of 12 cm from the surface, the magnetic field strength decreases by a factor of 1 O.

. Closest to the invention is a device for treating a fluid with a magnetic field. It is a fluid reservoir and a magnetic system, made in the form of two disks with poles of opposite polarity, equipped with shafts, installed at a distance from each other with a fugue with the possibility of G2D rotation.

A disadvantage of the known device is the low efficiency of fluid activation.

The purpose of the invention is to increase the efficiency of the treatment of the liquid by obtaining a more stable modified its internal structure.

The goal is achieved by the fact that the disks are made in the form of alternating sectors from the ferromagnetic and dnamagne material legs, equipped with rods mounted on the diamagnetic sectors, and placed in the tank, and the shafts are hollow and connected to the tanks, equipped with electric windings mounted to their external side and separate drives.

FIG. 1 shows the device together with the drive, a section; in fig. 2 and 3 disks of the device, front view (arrows indicate the directions of rotation).

The device comprises a housing 1, parallel disks 2, made up of ferromagnetic 3 and diamagnetic 4 sectors, perpendicular rods 5 for mechanically activating a fluid, 5 left shafts 6 with windings 7 electromagne-i s, discharge pipe 8, belt pedochi 9, rotational actuators 10 with a friction clutch coupling 11 and an electric motor 12.

The device works as follows.

The processed fluid is directed into the housing 1 through the hollow shafts 6 and out through the nozzle 8. Air can be supplied through one 5 shaft, thereby saturating the liquid with gas.

Activated oxygenated water can be used to fish.

When the disks 2 are rotated, first of all, the mechanical activation of the fluid occurs by means of rods 5 protruding from the diamagnetic sectors 4. When the rods move in the fluid behind them 25, vortices form and cavitation processes occur, which affect the internal structure. The intensity of mechanical activation is controlled by the speed of rotation of the disks.

When the electromagnet windings 7 are connected to the current source, the fluid is first exposed to a constant magnetic field inside the shafts 6 and then inside the case 1 between the rotating j disks 2 - actions of the alternating magnetic field. With the connection indicated in FIG. 1, the north pole vl appears on the right disc, and the south pole on the left-hand side. If necessary, you can create homonymous poles. As the discs 2 rotate in opposite directions (this is achieved, then), by means of an overlap; belt on one side), the ferromagnetic 3 and diamagnetic 4 sectors of the opposite discs periodically change places. Thus, in the gap between the disks 2, a variable pulsing magnetic pope occurs. The magnitude of the magnetic field H is controlled by the strength of the current passing through the windings 7 of the electromagnets.

The frequency depends on the speed of rotation of the disks 2.

I Thus, in the case of 1 particle | liquids additionally undergo a boa-t effect of an alternating magnetic field. Studies have shown that structural changes in molecular bonds are more persistent and exist much longer than when processing liquid in known devices.

The application of the invention significantly increases the processing efficiency - the activation of a liquid.

Claims (2)

1. Klassen VI. The magnetization of water systems. M., Himi, 1978, p. 120-121, is 456. 2. USSR author's certificate s 321457, cl. C O2 F 1/48, 22.O7.7O.