KR100959212B1 - A magnet - Google Patents

Abstract

The magnetic body includes a plurality of laminated inner layers and an insulating seal that completely seals the inner layers therein. The inner layers include a first or central metal layer, a first insulating layer, a second metal layer, a filter layer, a second insulating layer, a third metal layer, and a light absorbing material layer provided on each of the upper and lower sides thereof. Each of the metal layers is negatively charged and is formed by coating a special high temperature evaporated metal element over the entire surface of the insulator. The filter layer is woven from an insulating material and has at least 144 million mesh per square inch. The light absorbing material stores preabsorbed light energy. The magnetic body of the above-described structure produces a radial magnetic field that provides an enhanced magnetization effect.

Magnetic material, metal layer, filter layer, insulation layer, light absorbing material layer, magnetic field

Description

Ferrite {A MAGNET}

FIELD OF THE INVENTION The present invention relates to a novel magnetic material, in particular having a radial magnetic field having a plurality of laminated inner layers and comprising metal layers made of conductive metal elements, insulating layers, fine mesh-structured filter layers, and light absorbing material layers. It relates to a magnetic material that produces a.

Magnetic fields have proven their existence and are known to be widely used to magnetize various kinds of materials to change their molecular structure and physical properties. For example, when a magnetic field is used to magnetize water, the magnetic field is oriented in a direction perpendicular to the direction of the water flow such that the magnetic field lines of the magnetic field repeatedly cut through the water flowing through it to alter the molecular structure and physical properties of the water. By changing, it improves the taste of water.

At present, permanent magnets or electromagnets are used to generate a magnetic field, which is defined as two magnetic poles, namely South Pole (S) and North Pole (N), and has a fixed operating direction and a limited operating range. Thus, permanent magnets or electromagnets have only limited magnetic performance. When the magnetic fields generated by conventional permanent magnets and electromagnets magnetize different materials such as water, liquor, petroleum, etc., the magnetized materials have little change in their molecular structure and physical properties. The magnetic field shows that it has only a limited magnetization area and effect.

It is an object of the present invention to provide a magnetic body that produces a radial magnetic field, has a non-fixed magnetic field direction and range, and thus provides an enhanced magnetization effect.

In order to achieve the above and other objects, the magnetic material according to the present invention comprises a plurality of laminated inner layers including metal layers, insulating layers, filter layers, and light absorbing material layers; And an insulation seal that completely seals the laminated inner layers therein.

Each of the metal layers in the magnetic body of the present invention is formed by coating a high temperature evaporated conductive metal element on the entire surface of the insulator, thus being negatively charged. In addition, two or more different types of metal elements are used to form two or more metal layers.

Charges are similar to radial force lines and force fields, with negatively charged force fields oriented inwards, while positively charged force fields are oriented outwards, air, Since most external materials such as liquids and solids are positively charged, the magnetic body according to the invention having negatively charged metal layers and inward force field direction will have an inwardly convergent force line and force field, which is positive with an outward force field direction. It would be the case of approaching an externally charged external material, whereby an electromagnetic phenomenon is formed and a radial magnetic field is generated. As a result, the radial magnetic field produced by the magnetic body of the present invention has a non-fixed magnetic field direction and range, thereby providing an increased magnetization effect.

In a preferred embodiment of the invention, three different metal elements comprise three different metal layers: a first or central metal layer formed of indium (In), a second metal layer formed of silver (Ag), and It is used to form a third metal layer formed of aluminum (Al).

The insulating seal and the insulating layers are formed of a common insulating material such as polyurethane (PU) rubber, polyvinyl chloride (PVC) resin, or polyethylene terephthalate (PET), and isolate the negative charge of the metal layers. It functions, and the rest of the magnetic material becomes useless due to the neutralization of negative charges by external positive charges. However, the insulating sealer and the insulating layers do not interfere with the effect of the magnetic field of the magnetic body.

The filter layers are mesh structures woven from an insulating material and have at least 144,000,000 mesh per square inch. The reverse line of the electric field is converted to nanometer form as they pass through the ultrafine mesh of the filter layers.

The light absorbing layer is a light absorbing fabric capable of absorbing light energy. The absorbed light energy is stored in the light absorbing layer to increase the charge energy and thus the magnetization of the magnetic body.

The structural and technical means applied by the present invention to achieve the foregoing and other objects will be best understood by reference to the following description of the preferred embodiments and the accompanying drawings.

1 is a cross-sectional view of a magnetic body according to a preferred embodiment of the present invention.

2 is a cross-sectional view of a metal layer included in the magnetic body of the present invention.

3 is a schematic diagram of a mesh structure included in the magnetic body of the present invention.

1, a cross-sectional view of a magnetic body 100 according to the present invention is shown. As shown, the magnetic material 100 includes a plurality of laminated inner layers that are completely enclosed within the insulating enclosure 200. It is to be noted that all accompanying drawings are enlarged, and that the actual overall thickness of the illustrated embodiment of the present invention is only about 2 mm to 3 mm.

The laminated inner layers in the magnetic material (100) are located at the center of the laminated inner layers, whereby a first metal layer (1) referred to therein as a central metal layer (1); Two first insulating layers (2) separately positioned on the upper and lower sides of the central metal layer (1); Two identical second metal layers (3) separately positioned outside the two insulating layers (2); Two mesh-structured filter layers (4) separately positioned outside the two second metal layers (3); Two second insulating layers (2) separately positioned outside the two second filter layers (4); Two identical third metal layers (5) separately positioned outside the two second insulating layers (2); And two layers of light absorbing material 6 separately positioned outside the two identical third metal layers 5. All laminated inner layers are completely enclosed within the insulation enclosure 200 to form the magnetic material 100 of the present invention.

Referring to FIG. 2, the first, second, and third metal layers 1, 3, and 5 of the magnetic body 100 are made of an electrically conductive metal element 300, which is evaporated at a high temperature to insulate the body 310. ) Is covered over the entire surface to form negatively-filled metal layers (1, 3, 5).

In the preferred embodiment shown, three different types of electrically conductive metal elements, i.e., indium (In), silver (Ag), and aluminum (Al) are formed in the central, second and third metal layers (1, 3, 3). 5) to form each. Despite the use of three different metal elements of different charge numbers and charge densities, the radial magnetic fields of the first, second and third metal layers 1, 3 and 5 have a very complementary relationship.

Since the metallic elements of indium, silver and aluminum have respective charge numbers, the indium having the highest charge number is used in the present invention to form the central metal layer 1, and then the highest and lowest charge numbers are obtained. Silver and aluminum having are used to form the second and third metal layers 3, 5. Two identical second metal layers 3 and two identical third metal layers 5 are provided to be located separately in the upper and lower positions in the magnetic body 100 such that the radial magnetic field of these metal layers can produce complementary densities and effects. Will have

3 illustrates a mesh structure filter layer 4 included in the magnetic body 100 of the present invention. The filter layer 4 is a mesh structure woven from an insulating material and has at least 144,000,000 mesh per square inch. The reverse lines of charge through these high fine meshes are converted to ultra-fine nanometer forms, which have been experimentally demonstrated to work wider, farther, and longer.

The layer of light absorbing material 6 in the magnetic material 100 is a fabric capable of absorbing light energy. As light energy is previously absorbed by and stored in the layer of light absorbing material 6, the magnetic material 100 further increases charge energy.

The insulation layer 2 and the insulation seal 200 are formed of a general insulation material, for example, polyurethane (PU) rubber, polyvinyl chloride (PVC) resin, or polypropylene terephthalate (PET), It performs the function of isolating the negative charges of the material layers (1, 3, 5), the rest will be neutralized by external positive charges.

When the magnetic body 100 approaches an externally positively charged material or object, it cooperates with the N and S poles to produce a radial magnetic field and an inwardly convergent reverse line. That is, unlike conventional magnetic fields generated by magnets, the radial magnetic field generated by the magnetic body 100 is not limited to a fixed direction and range, thereby providing further enhanced magnetization effects. In other words, the magnetic body 100 generates a radial magnetic field having an excellent magnetization effect compared to a conventional magnetic field line having a limited direction and range between the N pole and the S pole.

When the magnetic body 100 of the present invention is used to magnetize water, the water molecular structure and physical properties are changed, and large molecular groups of tap water are divided into small molecular groups to improve the activity of water molecules, thereby improving the taste of water. It improves the solubility and permeability of nutrients and makes it easier to cross the cell wall, completing the human metabolism.

When the magnetic body 100 of the present invention is used to magnetize alcohol, the characteristics of alcohol are changed to improve the taste.

When the magnetic body 100 of the present invention is used in different applications of electrical energy, the magnetization and rearrangement of molecules on the surface of the metal plate, such as conductive wire, battery plate electrode, etc., so that the metal plates have lower resistance and increased conductivity. Having a lot of power increases.

When the magnetic body 100 of the present invention is used together with a fuel, the fuel molecules are magnetized, rearranged, and reduced in size to enable complete combustion of the fuel, thereby achieving the purpose of energy saving and fuel efficiency improvement.

When the magnetic body 100 of the present invention is used in clothing, shoes, etc. directly worn on the user's body, the magnetization effect provided by the charge thereof purifies the magnetic field of the user's body, activates the user's tissue cells, Improves blood circulation.

The magnetic body 100 has radial magnetic lines of force that are not limited to any limited direction and range, and thus particularly emphasize that it can be used without limitation to any particular direction or space size. In other words, when the magnetic body 100 is approached, mounted on, and disposed with a gas, a liquid, a solid or in any way having a given space, the magnetic body 100 is produced by the magnetic body 100. The radial magnetic field and the magnetic field lines are upgrade effective. Accordingly, the magnetic material 100 is very convenient and easy to use compared to a conventional magnet.

The effects of the foregoing examples using the magnetic material 100 of the present invention on water, fuel, cells of living organisms, and the like have been tested and demonstrated by various accredited organizations.

It will be appreciated that the scope and spirit of the present invention is not limited by the above-described embodiments, but is limited by the appended claims.

In conclusion, the present invention employs the principle of electromagnetism by charge to generate magnetic force, static magnetic field and the like, which has superior durability and wide application range compared to the conventionally generated magnetic force and static electricity.

Claims (9)

A plurality of laminated inner layers and an insulating seal that completely encloses the laminated inner layers therein; In the magnetic body comprising a plurality of metal layers, a plurality of insulating layers, a plurality of filter layers, and a plurality of light absorbing material layers, Each of the plurality of metal layers is formed by coating a hot evaporated conductive metal element over the entire surface of the insulator, and thus is negatively charged, and two or more different metal elements are used to form the metal layers; The insulating layers are formed of an insulating material; The filter layers are of a high fine mesh structure woven from an insulating material, and the light absorbing material layers are formed of a light absorbing material; One of the plurality of metal layers is a central or first metal layer positioned in the center of the magnetic material, and each of the upper and lower sides of the central metal layer includes a first insulating layer, a second metal layer, one of the filter layers, a second insulating layer, A third metal layer and one light absorbing material layer are sequentially stacked such that the plurality of metal layers are electrically isolated from each other by the insulating layers to prevent neutralization of the negative charges of the metal layers by external positive charges. Magnetic material made with. delete delete The method of claim 1, And the third metal layers are formed of aluminum, the second metal layers are formed of silver, and the central metal layer is formed of indium. The method of claim 1, And the insulating sealant and the insulating layers are made of an insulating material selected from the group consisting of polyurethane (PU) rubber, polyvinyl chloride (PVC) resin, or polyethylene terephthalate (PET). delete The method of claim 1, And said filter layers are of a mesh structure having at least 144,000,000 mesh per square inch. delete The method of claim 1, And wherein the light absorbing material forming the light absorbing material layers has pre-absorbed light energy stored therein.

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