EA037875B1 - Device for magnetic activation of liquids - Google Patents

Abstract

The invention relates to the field of technique of the magnetic activation of liquids. The magnetic activation of liquids to change their structure and physical properties can be used in chemical industry, oil production and oil refining industries, in the production of concrete and construction materials, in heat supply systems, in agriculture, medicine, cosmetology, etc. The objective of the proposed invention is to improve the efficiency and reduce the size and weight of the device for the magnetic activation of liquids. The substance of the invention is that the system of permanent magnets is made in the form of three-dimensional matrix of magnetic balls to increase the efficiency and reduce the size and weight of the device for the magnetic activation of liquids. The said balls are assembled in a matrix with as close packing as possible. In the cross-section, the three-dimensional magnetic matrix forms a hexagonal structure inscribed in the cross-section perimeter of the chamber for the magnetic activation of liquid with at least three layers forming the matrix. Each subsequent layer after the first layer in the matrix of magnetic balls is rotated coaxially relative to the previous layer over the circle connecting the centers of corner balls with hexagonal cross-section by an amount equal to the radius of the magnetic ball, and all layers are rotated in the same direction, due to which the magnetic matrix has a spiral shape that swirls the liquid. The hexagonal packing of the balls is considered to be the most dense of all known packing options.

Description

The invention relates to the field of technology for magnetic activation of liquids.

Magnetic activation of liquids to change their structure and physical properties can be used in the chemical, oil-extracting and oil-refining industries, in the production of concrete and building materials, in heat supply systems, in agriculture, medicine, cosmetology, etc.

Magnetic activation of a liquid is carried out using devices in which a powerful constant or variable magnetic field is created through the use of permanent magnets or electromagnets. Water is passed through a magnetic field, due to which the water is structured, i.e. ordering of water molecules and destruction of clusters in them. The magnetic properties of various substances are due to the rotation of electrons in their orbits and the internal moment of their motion (spin). It is this movement of electrons that characterizes the magnetic moment by its magnitude.

The impact of a powerful magnetic pulse on a substance causes nuclear magnetic resonance (NMR) in it. NMR - resonant absorption or emission of electromagnetic energy by a substance containing nuclei with non-zero spin in an external magnetic field, at a frequency v (called the NMR frequency), due to the reorientation of the magnetic moments of the nuclei. In the absence of an external magnetic field, the spins and magnetic moments of protons are oriented randomly. If you place a proton in an external magnetic field, then its magnetic moment will be either codirectional or oppositely directed to the magnetic field, and in the second case its energy will be higher (1).

Thus, when a liquid passes through a powerful magnetic field, the phenomenon of nuclear magnetic resonance arises in the atoms of the liquid and substances, which leads to the orientation of chaotically oriented protons into a strictly oriented state.

Molecules of ordinary natural water are combined into groups - clusters, the sizes of which can be different and depend on many external conditions - temperature, pressure, magnetic field strength, etc. The presence of clusters affects the physicochemical properties of water, in particular, its surface tension and a decrease in fluidity (2).

When water is exposed to a powerful magnetic field, the clusters are destroyed, due to which the water becomes homogeneous, its fluidity increases, and the surface tension decreases. As a result, the structuring of water occurs from the level of atomic nuclei to the level of macromolecules and microparticles of various chemical compounds present in water. Crystallization centers formed in water lead to adhesion of microparticles of a number of compounds and salts in water, which precipitate. Thus, there is a significant softening of water and a decrease in its surface tension, and its biological and chemical activity increases (3-5).

In addition, it is known that the creation of a vortex flow of water also very effectively destroys water clusters and increases its energy and biological activity. This property of mechanical action on water is used in vortex magnetic water activators (6-7).

At the same time, it is known that the acoustic impact on water at the infrasound frequency promotes the destruction of water clusters and its structuring (8).

A device for activating liquids is known, including a housing, inlet and outlet pipes, a spiral placed in the housing for a liquid flow (6). The liquid enters the body through the inlet pipe and moves in a spiral, while a vortex flow of the liquid arises, which leads to the destruction of the clusters and the structuring of the liquid.

The disadvantage of this device is its low efficiency, since the liquid is subjected only to mechanical action, while only very large water clusters can be destroyed, while for more efficient structuring of water, action is necessary at the level of atomic nuclei and molecular structures of water, which is achieved by the action of a powerful magnetic fields.

A device for magnetic activation of liquids is known, including a housing, inlet and outlet pipes, a chamber for magnetic activation of liquids located inside the housing, in which a system of permanent magnets is located. The magnetic system consists of two subsystems located in a cylindrical case with the same poles to each other, while each of the subsystems is identical to the other and each consists of two or more ring-shaped permanent magnets facing each other with opposite poles, while the case is transverse with respect to to its longitudinal axis a groove in which a pipeline (9) is located between the poles of the same name of two magnetic subsystems.

The disadvantage of this device is that individual parts of the liquid passing through the pipeline are exposed to the magnetic field unevenly. That is, the part of the liquid in direct contact with the magnetic assemblies is exposed to the maximum effect of the magnetic field, and the parts of the liquid that are remote from the surface and located in the middle between the permanent magnets are exposed to the minimum intensity of the effect of the magnetic field. Considering that the magnetic field decreases in inverse proportion to the cube of the distance to the magnet's surface, the decrease in the effect of the magnetic field even at a small distance will be significant. In addition, the liquid in the device moves in a parallel flow, which prevents different hours of liquid from mixing in the flow and being simultaneously subjected to magnetic and vibroacoustic effects. Other disadvantages of the device are its large size, high weight and low efficiency, which is associated with the need to use large permanent magnets in order to provide a sufficiently high intensity of the magnetic field in the entire volume of the body through which the liquid flows.

A device for magnetic activation of liquids is known, including a housing, inlet and outlet pipes, a chamber for magnetic activation of liquids located inside the housing, in which a system of permanent magnets is located. The cylindrical body of the device contains a magnetic system of parallel assemblies made in the form of a series of permanent magnets installed with gaps. The system assemblies are installed parallel to the housing axis along one or more concentric circles around the central assembly and are separated in the radial direction of the system by coaxial ferromagnetic baffles. Thus, ferromagnetic attachments are placed in the gaps of the assembly, and the magnets in each assembly are oriented with respect to each other by the same poles with the provision of alternating the orientation of the first magnet in each assembly of the annular row (10).

The disadvantage of this device is that individual parts of the liquid passing through the magnetic assemblies are exposed to the magnetic field unevenly. That is, the part of the liquid in direct contact with the magnetic assemblies is exposed to the maximum effect of the magnetic field, and the parts of the liquid that are remote from the surface and located in the middle between the permanent magnets are exposed to the minimum intensity of the effect of the magnetic field. Considering that the magnetic field decreases in inverse proportion to the cube of the distance to the magnet's surface, the decrease in the effect of the magnetic field, even at a small distance, will be significant. In addition, in the device, the liquid moves in a parallel flow, which prevents different parts of the liquid from mixing in the flow and being simultaneously subjected to magnetic and vibroacoustic effects. Another disadvantage of the device is its large size and high weight and low efficiency, which is associated with its design features, in particular with a large number of metal structural elements and the need for multiple gaps between magnetic assemblies, magnets and partitions.

The closest technical solution is a device for magnetic activation of a liquid, which includes a housing, inlet and outlet pipes, a chamber for the formation of a vortex flow of a liquid and a chamber for magnetic activation of liquids connected in series with it, in which a system of permanent magnets is located. The liquid enters the device through the inlet and enters the vortex chamber, where it swirls, after which the liquid enters the magnetic activation chamber of water, where it is exposed to the magnetic field of permanent magnets, as a result of which the efficiency of magnetic activation of the liquid increases. Thus, the fluid is subjected to successively two physical factors: vortex and magnetic activation (7).

The disadvantage of this device is that the liquid sequentially passes through two different devices, each of which acts on it independently. This, on the one hand, increases the size and weight of the device, and, on the other hand, reduces the efficiency of water activation, since the magnetic and vortex activation of water does not occur simultaneously.

The objective of the proposed invention is to improve the efficiency and reduce the size and weight of the device for magnetic activation of liquids.

The problem is solved by the fact that in a device for magnetic activation of a liquid, including a housing, inlet and outlet pipes, a chamber for magnetic activation of liquids located inside the housing, in which a system of permanent magnets is located, where according to the invention the system of permanent magnets is made in the form of a three-dimensional matrix of magnetic balls , which in section forms a hexagonal structure inscribed in the perimeter of the section of the magnetic activation chamber of the liquid, while the number of layers forming the matrix is at least three; where, according to the invention, each subsequent layer after the first in the matrix of magnetic balls is coaxially rotated relative to the previous layer in a circle connecting the centers of the corner balls of the hexagonal section by an amount equal to the radius of the magnetic ball, and all layers are rotated in the same direction, while at the input and output limit grids are installed in the branch pipes, the cell sizes of which are less than the diameter of the balls.

The essence of the invention lies in the fact that in order to increase the efficiency and reduce the size and weight of the device for magnetic activation of liquids, the system of permanent magnets is made in the form of a three-dimensional matrix of magnetic balls. The balls are collected in a matrix with the closest possible packing. In cross-section, the three-dimensional magnetic matrix forms a hexagonal structure inscribed in the perimeter of the cross-section of the magnetic activation chamber of the liquid, while the number of layers forming the matrix is at least three. The hexagonal packing of balls is considered to be the densest of all known packing (11).

Thus, the most dense packing of magnetic balls ensures the passage of liquid through the gaps between balls in a three-dimensional matrix at a minimum distance from the surface

- 2,037875 magnetic balls. This provides the most intense effect on the liquid of the magnetic field.

Each subsequent layer after the first magnetic balls in the three-dimensional matrix is rotated coaxially relative to the previous layer in a circle connecting the centers of the corner balls in the hexagonal section of the matrix by an amount equal to the radius of the magnetic ball, and all layers are rotated in the same direction. This assembly of the magnetic balls allows the three-dimensional matrix to be spiraled, while the system of gaps between the balls also forms a spiral along which the fluid moves. The spiral motion of the liquid contributes to its best structuring (6, 7), while the Schauberger effect appears (12), when the hydraulic resistance decreases during the rotation of the liquid, which contributes to the faster passage of the liquid through the cross section of the three-dimensional matrix.

During the passage of the liquid through the gaps between the balls, there is a periodic increase and decrease in the cross section and volume of the gap from layer to layer on the path of the fluid flow. This leads to a variable change in the fluid pressure at the infrasound frequency, which ensures the best structuring of the fluid and the destruction of clusters (8). On the other hand, a variable change in the cross section of the gaps between the balls on the path of the fluid flow leads to the greatest turbulence, which ensures better mixing of various parts of the fluid and increases the efficiency of its structuring and magnetic treatment.

When a liquid passes through a three-dimensional magnetic matrix, it is subjected to alternating harmonic oscillations of the magnetic field, which makes it possible to increase the efficiency of the excitation of nuclear magnetic resonance in the nuclei of atoms of the liquid. This, in turn, increases the efficiency of the magnetic activation of the fluid.

To prevent deformation of the three-dimensional matrix or balls falling out of it under pressure and as a result of fluid turbulence, restricting grids are installed at the inlet and outlet nozzles, the cell sizes of which are smaller than the size of the balls.

The dimensions of the layers and the fluid flow rate determine the frequency of the effect of alternating oscillations of the matrix magnetic field on the fluid. Thus, by varying the size of the balls and the velocity of the fluid flow, it is possible to achieve optimal values of the frequency of oscillations of the magnetic field.

For example, if with a length of a three-dimensional matrix of 10 cm, there will be 20 layers in the assembly, they will create 10 sign-alternating full-period cycles of magnetic field oscillations. Thus, at a flow rate of 1 m per second, the liquid will undergo harmonic alternating oscillations of the magnetic field with a frequency of 10 Hz.

If it is necessary to increase the productivity of the device, the dimensions of the body are increased accordingly: the cross-sectional area and the length of the magnetic activation chamber of the liquid. In this case, the diameters of the magnetic balls are proportionally increased so that the packing of the magnetic balls in the cross section forms a hexagonal structure. With a decrease in the productivity of the device, the dimensions of the magnetic activation chamber of the liquid are correspondingly reduced and the diameters of the magnetic balls in the matrix are proportionally reduced.

FIG. 1 shows a sectional diagram of a device for magnetic activation of a liquid. The housing 1, made of non-magnetic material, has inlet 2 and outlet 3 nozzles. A three-dimensional magnetic matrix 5 is placed in the magnetic activation chamber of a liquid 4, which consists of a dense packing of magnetic balls, while the cross-section of the magnetic matrix has a hexagonal structure, and restrictive grids 6 are installed at the inlet and outlet nozzles 6. As a result of the fact that each subsequent layer after the first in the matrix of magnetic balls are coaxially rotated relative to the previous layer in a circle connecting the centers of the corner balls of the hexagonal section by an amount equal to the radius of the magnetic ball, and all layers are rotated in the same direction, the packing of balls acquires a spiral shape along the axis of the matrix.

This is clearly seen due to the straight line D drawn through the centers of the balls along the diagonal of the cut of the matrix.

FIG. 2a) and b) show the hexagonal arrangement of magnetic balls in the cross section of a three-dimensional magnetic matrix. FIG. 2a) shows the rotation of the second layer of the three-dimensional magnetic matrix L relative to the first layer K. As can be seen from FIG. 2a), the second layer L is rotated coaxially relative to the first layer K along a circle connecting the centers of the corner balls of the hexagonal section by an amount equal to the radius of the magnetic ball r, the corner ball centered at point A has taken a position centered at point B. In Fig. 2b) shows a general view of a three-dimensional magnetic matrix from the end, consisting of three layers - the first layer K, the second layer L, and the third layer M.

The device works as follows. The liquid is supplied to the inlet nozzle 2 of the housing 1 and passes through the restrictive grid 6, entering the magnetic water treatment chamber 4. Then the liquid passes through the spiral system of gaps of the three-dimensional magnetic matrix 5, where it is exposed to a powerful alternating magnetic field combined with a vortex flow and high turbulence ... In the process of passing through the gaps of the three-dimensional magnetic matrix, the liquid passes through the gaps periodically changing in the section and volume, which causes fluctuations in the liquid pressure with the infrasound frequency, which enhances the effect of liquid structuring and destruction of clusters. After passing through the three-dimensional magnetic matrix, the liquid passes through the restriction mesh 6 and exits through the outlet 3.

Thus, in this device, the liquid is simultaneously subjected to four types of impact, contributing to its maximum effective magnetic activation and structuring: alternating magnetic field; vortex flow (Schauberger effect); high turbulence, which ensures good miscibility of all layers of the liquid; infrasound impact that destroys clusters.

Information sources

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http://www.o8ode.ru/article/leam/klaster.htm

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Chemistry, 1982, p. 265-282.

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8. Kovalenko VF, Glazkova V.B. Influence of acoustic waves on the structural properties of water. Biomedical Engineering and Electronics. No. 1 (3), 2013, p. 2-14.

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RF No. 2 333 895, 2006.

Yu A device for magnetic treatment of liquids. RF patent 2133710, 1999.

11.N.DJ. A. Sloene. Ball packing. Scientific American. Edition in Russian .. No. 3 · MARCH 1984 · P. 72-82.

12. Schauberger Victor.

https://ru.wikipedia.org/wiki/%D0%A8%D0%B0%D 1% 83% D0% B 1% D0% B5% D l% 80% D0% B3% D0% B5% Dl% 80, _% D0% 92% D0% B8% D0% BA% Dl% 82% D0% B

E% Dl% 80

Claims (2)

CLAIM 1. A device for magnetic activation of a liquid, including a housing, inlet and outlet pipes, a chamber for magnetic activation of liquids located inside the housing, in which a system of permanent magnets is located, characterized in that the system of permanent magnets is made in the form of a three-dimensional matrix of magnetic balls, which in cross section forms a hexagonal structure inscribed in the cross-sectional perimeter of the magnetic activation chamber of the liquid, while the number of layers forming the matrix is at least three. 2. The device according to claim 1, characterized in that each subsequent layer after the first in the matrix of magnetic balls is rotated coaxially relative to the previous layer in a circle connecting the centers of the corner balls of the hexagonal section by an amount equal to the radius of the magnetic ball, and all layers are rotated in the same direction, while at the inlet and outlet nozzles are installed restrictive grids, the size of the cells of which are less than the diameter of the balls.