RU39055U1 - MAGNETIC WARE LEPILOVA FOR WATER-CONTAINING MEDIA - Google Patents

Abstract

Usage: dishes for the magnetic treatment of aqueous media in order to improve their biomedical properties. The essence of the utility model: a water-containing medium is placed in a container 1 made of a dielectric or a conductor (diamagnetic or paramagnetic). The permanent magnet 2, located on the outer surface of the tank 1, is equipped with a pole tip 3, which concentrates the magnetic flux in a water-containing medium and creates a magnetic field that is variable in space. When stirring aqueous media, the magnetic field acts on the molecular structures of water at biotropic frequencies (for example, at a frequency of the alpha rhythm of the brain, about 10 Hz) and improves the biomedical properties of the aqueous media. Due to the concentration of the magnetic field in the tank 1, effective shielding of the environment from it is also provided. The biomedical properties of water are also improved due to the use of reflectors 4 and resonators 5 of electromagnetic waves in magnetic dishes generated by the molecular medium of water in millimeter and other wavelength ranges.

Description

The utility model relates to dishes for the magnetic treatment of aqueous media and is intended to improve their biomedical properties. A water-containing medium is ordinary water, tea, coffee, stewed fruit, kissel, milk, juice, broth, soup, alcoholic beverage, water infusion of herbs, medicines containing water, etc. The dishes can be made in the form of a cup, mug, bowls, plates, decanter, bottles, buckets, flasks, etc.

The water-containing medium magnetized in dishes is used by people for food, rinsing the mouth, washing, etc., for feeding animals, increasing the germination of seeds and watering plants, improving the properties of water-containing infusions of herbs and medicines, etc.

As shown in basic research, in a molecular ice-like component of water (crystalline structures such as snowflakes, patterns on winter glass, etc.), electromagnetic waves in millimeter and other wavelength ranges arise at strictly defined frequencies. The energy and spectrum of these oscillations determine all the vital processes (Petrosyan V.I., Gulyaev Yu.V., Zhiteneva E.A., Elkin V.A., Sinitsyn N.I. Interaction of physical and biological objects with electromagnetic radiation of the EHF range Radio engineering and electronics., 1995, v. 40, issue 1; Sinitsyn N.I., Petrosyan V.I., Elkin V.A., Devyatkov N.D., Gulyaev Yu.V., Betsky O.V. The special role of the system "millimeter waves - water medium" in nature. Biomedical Radio Electronics, 1998, No. 1; Petrosyan VI, Sinitsyn NI, Elkin VA Luminescent interpretation of the "SPE-effect", Biomedits nskaya electronics 2002, №1; Betsky OV Pioneering work on millimeter electromagnetic biology, made in IRE RAS Biomedical technology and electronics 2003, №8, etc.)...

Deficiency of energy in the body at the frequencies of its own molecular vibrations of water and defects in the spectra of these vibrations worsen all life processes. One of the ways to fill the energy deficit of these vibrations and improve their spectrum is to use the body of aqueous media treated in a magnetic field.

As a result of research, it was shown that the magnetic field promotes the crystallization of liquid water at the molecular level. In this case, the intensity of intrinsic molecular vibrations of water along the magnetic field vectors and perpendicular to them increases, and accordingly all life processes in organisms using magnetized water improve (Petrosyan V.I., Sinitsyn N.I., Elkin V.A., Bashkatov O .V. Interaction of water-containing media with magnetic fields. Biomedical Radio Electronics, 2000, No. 2.).

Five analogues are known in which magnetic dishes for water-containing media are described, including a container made of a dielectric or a diamagnetic conductor (stainless steel) and a permanent magnet placed on the side of the external surface of the container.

1st analogue. In the "Magnetic Bowl" (Patent of Ukraine No. 32849 IPC A 61 N 2/06, publ. 02/15/2001. Bull. Inventory of Ukraine No. 1, 2001.) "an inductor is located on the outer surface of the vessel, the magnetic field of which covers all or part of the working volume of the vessel ... " This product has two drawbacks compared with the claimed utility model, which are, to one degree or another, repeated in other analogues.

Disadvantage No. 1: large scattering fields of the magnet; more than half of the magnetic flux penetrates the volume outside the useful volume of the bowl. This leads to an additional environmental burden on the environment (on people, including heart stimulants, computers, watches, etc.). In addition, with large scattering fields of the magnet to provide the required magnetic field strength

it is necessary to increase the mass of the magnet, which leads to an increase in the cost of the magnet and the product as a whole. The disadvantage is due to the absence in the bowl of the device for transporting the magnetic flux, including the scattering flux, only to the volume of the bowl where the aqueous medium is located.

Disadvantage No. 2: low efficiency of magnetic treatment of an aqueous medium, that is, low efficiency of its therapeutic effect on all living things. This is due, firstly, to the low intensity of intrinsic molecular vibrations of water at certain frequencies, and secondly, to the poor quality of their spectra — the lack of modulation of these vibrations at biotropic frequencies (for example, at a frequency of the alpha rhythm of the brain, about 10 Hz) (Application of artificial magnetic fields in experimental and clinical medicine - Part 11: Therapeutic use of magnetic fields - Reviews on electronic technology - Ser. 1: Microwave electronics / Yu.M. Raigorodsky et al. - M. Central Research Institute "Electronics", 1987, no. 5 (1253), p. 56). The reason for this disadvantage is the lack of analogue of the corresponding devices that increase the intensity of these vibrations and improve the quality of their spectra (for example, reflectors and resonators for intrinsic electromagnetic vibrations of water, a special distribution of the magnetic field in an aqueous medium).

2nd analogue. In Bulgarian patent No. 623Y, IPC A 61 N 2/06; A 47 G 19/22; C 02 F 1/48, publ. 07/31/2003 a magnetic cup is a ceramic container with a double bottom and a cavity in which a permanent magnet is located. On the outer side of the vessel wall there is a side providing positioning of the lid with the second cavity in which the second magnet is located. This analogue is characterized by both disadvantages of the previous one. Moreover, the presence of a magnet in the lid increases the adverse effect of the magnetic field on a person, since the lid is necessarily taken in hand.

3rd analogue. In the device for the magnetic processing of liquids (RF patent No. 2097336, IPC C 02 F 1/48, publ. 11/27/1997), the magnetic system is deposited on the outer surface of the vessel made of diamagnetic material. A large number of magnets in the analogue creates the prerequisite for the partial elimination of deficiency No. 2, but the nature of the placement of the magnets in space is not indicated, which ensures, for example, during normal mixing of the aqueous medium, the magnetic field modulates the natural molecular vibrations of water at biotropic frequencies, the 4th analogue. Japanese Patent No. 11178692, IPC A 47 G 19/22; A 61 N 2/08, publ. 07/06/1999, a stainless steel cup is proposed, consisting of two containers entering one another. Magnets are located on the outer surface of the inner container. The presence of several magnets and the manufacture of an internal capacitance from a conductor (stainless steel) partially eliminates the deficiency No. 2, but the deficiency No. 1 remains unresolved completely.

5th analog. Closest to the claimed utility model, an analogue of the set of essential features (prototype) is a magnetic cup described in Japanese patent No. 9098873, IPC A 47 G 19/22, publ. 04/15/1997. In the central part of the bottom of the cup body there is a chamber protruding into the container with a magnet located in it. The hole in the chamber closes the plug. The advantage of this cup is that, due to the placement of the magnet inside the vessel, its external scattering fields are reduced. This partially eliminates flaw # 1, but another flaw remains unresolved.

Tasks the utility model aims to solve:

1) the concentration of magnetic flux in the working volume of the dishes with simultaneous screening of the environment from magnetic fields;

2) increasing the efficiency of magnetic treatment of water and an aqueous medium by increasing the intensity of its own

molecular vibrations of a water-containing medium and improving the quality of the spectra of these vibrations.

The tasks are solved in Lepilov’s magnetic cookware for aqueous media, including a container and a permanent magnet located on the side of its external surface, in that the magnet is equipped with at least one pole tip, at least on the side of the external surface and / or on the internal surface of the container single reflector and resonators of electromagnetic waves tuned to the frequencies of natural molecular vibrations of water.

The capacitance can be made of a dielectric, diamagnetic or paramagnetic conductors. Moreover, if the capacitance is made of a conductor, then it forms a single part with a reflector.

To protect magnets, pole pieces, reflectors and resonators from mechanical damage, exposure to water and detergents, etc., the container capacity is completely or partially covered by the container with the formation of a chamber between them.

To improve the quality of the spectra of intrinsic molecular vibrations of a water-containing medium, the manufacture of a pole tip of a magnet located on the side of the bottom of the dish is made in the form of a hexagon equipped with at least six beam-shaped strips covering the container, as well as equipping the dishes with more than one magnet.

To further increase the efficiency of magnetic treatment of water, the dishes are equipped with a lid with a part facing the container in the form of a test tube made of a dielectric with magnets, pole tips, reflectors and resonators inside it, or a lid with a component facing the container in the form of a tube from a diamagnetic or paramagnetic conductor, inside of which magnets with pole tips are placed, and on the outside of the part at least one reflector and resonator are placed.

The specified set of essential features provides a solution to the tasks.

The magnetic pole piece provides transportation and the creation of an alternating (pulsating) in the space distribution of magnetic field strength in a container with a water-containing medium, protecting the environment from the magnetic fields of dishes, and also reduces the mass of the magnet while maintaining the required magnetic field strength. An alternating (pulsating) in space distribution of the magnetic field strength in a tank with an aqueous medium is also ensured by the use of several magnets.

When mixing a water-containing medium with a frequency of about 2 Hz in a magnetic field with 8-10 maxima and minima of the magnetic field along the trajectories of the movement of water molecules, the magnetic field is affected by the magnetic field at the biotropic frequency of about 10 Hz (alpha-rhythm of the brain).

Reflectors reflect electromagnetic waves generated by a water-containing medium from the walls of the dishes inside it and increase the intensity of oscillations, just like a reflector in a car headlight increases the illumination in front of a car.

Resonators of electromagnetic waves accumulate the energy of their own vibrations in the aquatic environment and increase their intensity, just as ordinary swings in resonance significantly increase the energy stored in them and the amplitude of the vibrations.

The utility model is illustrated by drawings, where figures 1-5 show embodiments of magnetic dishes and its elements, in which is indicated:

1 - capacity for an aqueous medium,

2 - permanent magnet

3 - magnetic pole piece,

4 - reflector of electromagnetic waves,

5 - resonator of electromagnetic waves,

6 - pen

7 - container

8 - sealed chamber;

9 - spring,

10 - cover

11 - part in the form of a test tube.

Figure 1 shows a magnetic circle containing a container 1 of a dielectric (for example, ceramic or plastic) and a permanent magnet 2, mounted on the bottom of its outer surface. Magnet 2 is equipped with a pole piece 3 of soft magnetic material and a reflector 4 of diamagnetic or paramagnetic conductor. On the outer side surface of the tank are placed resonators 5 of conductors in the form of disks and stripes of a rectangular shape. Resonators have resonant frequencies corresponding to the frequencies of natural vibrations of the aqueous molecular environment in the millimeter and other wavelength ranges.

The mug is equipped with a handle.

Figure 2 shows a magnetic circle containing a container 1 of a dielectric, which is partially externally covered by the container 7.

The container 1 and the container 7 form a sealed chamber 8. The chamber 8 has a glass-shaped reflector 4 made of a conductor, for example, aluminum foil, covering the container, as well as a permanent magnet 2 with a pole tip 3. On the outer side surface of the container 1 are placed 5 resonators from conductors in the form of disks. The functions of the resonators 5 also perform holes of a special shape made in the reflector 4.

To compensate for thermal expansion and prevent mechanical deformation of the container 1 and the container 7, a spring 9 is placed between the pole piece 3 and the inner wall of the container. The container is equipped with a handle 6.

Figure 3 shows a magnetic cup containing a container 1 of a diamagnetic (e.g., stainless steel) or paramagnetic (e.g., aluminum) conductor. The permanent magnet 2, mounted on the bottom of its outer surface, is equipped with a pole tip 3. The reflector function is performed by the inner surface of the capacitor 1. On the inner surface of the capacitor 1 there are resonators 5 in the form of quarter-wave pins. The tank is equipped with a handle 6.

Figure 4 shows the lid 10, equipped with a part in the form of a tube 11 made of a diamagnetic or paramagnetic conductor, which has a length less than the depth of the container. One or several magnets 2 with pole pieces 3 are placed inside the part 11. The outer surface of the part 11 performs the function of a reflector. The resonators 5 are made in the form of quarter-wave pins on the part 11.

Figure 5 shows the shape of the pole piece 3 in the form of a hexagon with radiant strips covering the container, which is equipped with a magnet 2, located on the side of the bottom of the dishes.

Lepilov magnetic dishes for aqueous media, as a rule, are made in the following way.

Utensils manufactured by the industry are used, which are equipped with magnets, pole pieces, reflectors and resonators. For example, double plastic thermomugs are used (inner mug-container, outer mug-container), which are equipped with everything necessary in a sealed chamber between the tank and the container.

Pole lugs can be made in the form of a flat hexagon, a truncated hexagonal cone, a truncated hexagonal prism, and other shapes.

Examination of the proposed magnetic dishes using a magnet in the form of a disk with a diameter of 13.5 mm and a thickness of 2 mm and a pole tip in the form of a flat hexagon with a maximum size

40 mm of soft magnetic sheet 0.35 mm thick showed the following. In the working volume of the dishes, the magnetic field is approximately 1.6-1.7 times greater than without a pole piece. That is, to obtain the desired field, you can use magnets of lower mass.

But the pole piece in the utility model also performs the function of a highly efficient magnetic screen. Thus, the magnetic field strength on the surface of the tip facing the environment in the studied design was 40-60 times less than on the surface of a magnet without a tip.

Reflectors 4 for containers 1 of a dielectric can be made of aluminum or copper foil in the form of disks (figure 1) or glasses (figure 2). Reflectors can also be made by spraying non-toxic diamagnetic or paramagnetic metal films onto a dielectric surface. For example, a silver film deposited on the inner surface of a container provides an additional healing effect.

Resonators for containers made of dielectric can also be made of aluminum or copper foil in the form of disks, rectangles (Fig. 1).

Resonators can also be made in the form of half-wave slots and round holes on the surface of the reflectors (figure 2).

The magnet can be made in the form of a disk, ring, regular hexagon (for example, from magnetoplast or magnetoelast).

Magnetic dishes are used as usual. A water-containing medium is poured into it and mixed for 10-15 seconds. For magnetization, 2-3 minutes are enough. A water-containing medium should be used at a temperature not exceeding 60-70 ° С, since at a temperature above 70 ° С degrees the ice-like structures of water are destroyed, and the use of such water to improve vital processes is not effective. There are no contraindications for using magnetic dishes.

Claims (8)

1. Magnetic dishes for aqueous media, including a container and a permanent magnet placed on the side of its outer surface, characterized in that the magnet is equipped with at least one pole tip, at least one reflector is located on the side of the outer surface and / or on the inner surface of the container and electromagnetic resonators tuned to the frequencies of natural molecular vibrations of water. 2. The dishes according to claim 1, characterized in that the container is made of a dielectric. 3. The dishes according to claim 1, characterized in that the container is made of a diamagnetic or paramagnetic conductor and forms a single part with a reflector. 4. The dishes according to claim 1, characterized in that the container is completely or partially covered by the container with the formation of a chamber between them. 5. The dishes according to claim 1, characterized in that the pole tip of the magnet located on the bottom side of the dishes is made in the form of a hexagon having at least six beam-shaped strips covering the container. 6. The dishes according to claim 1, characterized in that it has more than one permanent magnet. 7. The dishes according to claim 1, characterized in that it is provided with a lid with a part facing the container in the form of a test tube made of a dielectric with permanent magnets, pole pieces, reflectors and resonators inside. 8. The cookware according to claim 1, characterized in that it is provided with a lid with a part facing the container in the form of a test tube of a diamagnetic or paramagnetic conductor with permanent magnets and pole pieces placed inside it, and at least one reflector is placed on the outside of the part and resonator.