RU59892U1 - RADIATION NEUTRALIZER - Google Patents

Abstract

The utility model relates to the field of instrumentation and can find application as a means of protecting biological objects from exposure to radiation and fields of various origins. The essence of the utility model is a radiation converter, which includes layers of a dielectric, between which an electrically conductive grid is located, moreover, layers of a dielectric are enclosed in an insulating shell, and the electrically conductive grid between them is formed by concentric circles and / or circuits located horizontally relative to each other and located one in other triangles and made of a dielectric paint containing 50-85 wt.% electrically conductive filler. 2 of FIG.

Description

The utility model relates to the field of instrumentation and may find application as a means of protecting biological objects from exposure to radiation and fields of various origins.

Known protective devices and materials that absorb and neutralize electromagnetic radiation in the form of multilayer structures of layers of a dielectric and an electric current conductor, made in the form of an electrically conductive grid. The size and shape of the cells, in particular, the interweaving of threads, electrically conductive grids and their relative position in different layers, determine the frequency of the absorbed or transformed electromagnetic radiation.

(EA (RU) 001272 B1, H 01 Q 17/00, F 41 H 3/02, 1999.02.19; DE 2601062 C1, H 01 Q 17/00, H 01 Q 15/00, 1976.11.25; US 3599210 C1, H 01 Q 17/00, 1971.08.10)

These materials are part of interference-absorbing devices in which the incident and reflected electromagnetic waves mutually cancel each other out.

According to the proposed mechanism of action of the radiation converter according to a utility model, the closest analogue is the protective structure in the form of electrically conductive networks placed one above the other and separated by insulating (made of dielectric) layers.

(US 5003311 C1, H 01 Q 17/00, 1991.03.26).

By a similar protective mechanism, a system of small human blood vessels operates, absorbing and neutralizing external fields and radiation of various origins. A disadvantage of the known technical solution is its performance in a fairly narrow range of high and ultra-high frequencies, low efficiency in a wide range of frequencies, as well as manufacturing complexity and high

value, which prevents its distribution as a consumer goods.

The objective of the utility model is to create a mass demand device that can effectively neutralize the uncontrolled exposure of a person to electromagnetic radiation and fields of various origins (from household microwave devices, televisions, monitors, television and radio antennas, etc.).

The technical result of the utility model is to reduce the influence of external factors in the form of uncontrolled electromagnetic radiation and fields on the parameters of human biological fluids (solutions of blood, lymph, cerebrospinal fluid, urine, etc.).

The essence of the utility model is a radiation converter, which includes layers of a dielectric, between which an electrically conductive grid is located, moreover, layers of a dielectric are enclosed in an insulating shell, and the electrically conductive grid between them is formed by concentric circles and / or contours located horizontally relative to each other, other triangles and made of a dielectric paint containing 50-85 wt.% electrically conductive filler.

In addition, the Converter further includes a substrate of a dielectric with a thickness of 400-800 microns; the number of dielectric layers is 2-50; the thickness of the paint is 20-300 microns; the width of the paint is 20-300 microns; the displacement of adjacent circles and / or contours of triangles is 35-700 microns; the diameter of the circle and / or the diameter of the circle describing the triangle is 1-25 mm; the thickness of the dielectric layer is 100-300 microns; powder of graphite and / or metal with a particle size of 1-50 microns was used as an electrically conductive filler; the metal used is aluminum or zinc; electrically conductive mesh formed

concentric circles and contours of triangles located in one another, made with the ratio of the total number of circles to the total number of triangles of 0.5-1.5; the dielectric for the manufacture of layers and substrates is selected from the group: mica, glass, thermoplastic and thermoset; the insulating shell is made of polyethylene, polypropylene, polyvinyl chloride.

The constructive solution of the matrix modulator according to the utility model is presented in Figs. 1 and 2, where:

1 - substrate;

2 - insulating shell;

3 - layers of dielectric;

4 - electrically conductive mesh of various kinds.

The operation of the radiation converter according to a utility model of the invention can be illustrated by the following examples.

Example 1. The ability of a radiation neutralizer according to a utility model to reduce the effect of external radiation on a person was evaluated by reducing the induced optical activity of a human biological fluid, in particular, a blood solution (5% solution of blood serum in standard saline), the value of which is determined by the parameters of the acting radiation or field .

An indicator of the optical activity of a human biological fluid was the angle of rotation of the plane of polarization φ, which was determined by a circular SM-3 polarimeter with a sodium lamp (wavelength of the sodium D-line is 589 nm, a cell with a capacity of 10 ml at an ambient temperature of 22 ± 2 ° C). In the optical system of the SM-3 polarimeter, an optically active quartz plate 0.2 mm thick was used. The measurements were carried out when changing the location of the polarimeter at distances from 500 m to 3.5 km from the place of radiation: the transmitting antenna of the television tower.

Conducted standard measurements with a change in the location of the cuvette of the polarimeter showed that the angle of rotation of the plane of polarization φ was -8.4 ± 0.35 °. A sufficiently large scatter of the results indicates the presence of induced optical activity in the biological fluid due to exposure to external radiation or fields.

To shield the polarimeter cell with a biological object, a neutralizer was used according to the utility model (Fig. 1), which included 6 layers 3 of a dielectric made of 20 × 20 mm paper with a thickness of 120-150 μm. On the side of each dielectric layer with oil-based paint containing 84 wt.% Of an electrically conductive filler in the form of graphite powder with particle sizes of 3-20 μm, an electrically conductive grid 4 was applied in the form of concentric circles displaced relative to each other with a diameter of 1-7 mm , the thickness of the contour line of the paint 25-50 microns, the width of the contour line of the paint 30-50 microns with horizontal displacement of adjacent circles 70-90 microns (dimensions are shown conditionally figure 2). The total thickness of the package of dielectric layers and grids was 1.2-1.4 mm. The bag was sealed in a 0.3 mm thick polypropylene film sheath.

After placing the neutralizer under and on the sides of the cell with the blood solution, the angle of rotation of the plane of polarization φ, ceteris paribus, was -8.4 ± 0.05 °, which indicates a significant decrease in the scatter of the results caused by the induced optical activity, i.e. indicates a decrease in the influence of external factors in the form of uncontrolled radiation and fields on the parameters of human biological fluids.

Example 2. A similar result was achieved when using a neutralizer according to a utility model containing 12 layers of a dielectric made of mica 20 × 20 mm with a thickness of 120-150 microns. To the side of each layer of dielectric 3 is oil-based paint,

containing 60 wt.% an electrically conductive filler in the form of zinc powder with a particle size of 20-40 microns, an electrically conductive grid 4 was applied (Fig.2) in the form of concentric circles displaced relative to each other with a diameter of 5-10 mm, the thickness of the contour line of the paint 25- 50 microns, the width of the contour line of the paint 30-50 microns with horizontal displacement of adjacent circles of 70-90 microns and the contours of the isosceles triangles located in one another, the diameter of the circumscribed circle of which was 5-10 mm, the thickness of the contour line of the paint 25-50 microns, width to nturnoy paint line 30-50 microns at a horizontal displacement of adjacent triangles 70-90 microns. The ratio of the total number of circles to the total number of contours of triangles was 1.3. The thickness of the package was 2.7-3.0 mm. The bag was hermetically sealed in the shell of their 0.4 mm thick polyethylene film.

Thus, the signs of the radiation converter according to the utility model are in a causal relationship with the stated technical result, and the converter itself can reduce the influence of external factors in the form of uncontrolled electromagnetic radiation and fields on the parameters of human biological fluids.

The implementation of the utility model is not limited to the package in the form of a rectangular parallelepiped, presented in the description and illustrated by the drawings. A utility model is capable of other forms of implementation and can be performed in different ways. In addition, technical terms used in the formula and description should not be construed as limiting the scope of protection.

Claims (13)

1. A radiation converter comprising layers of a dielectric between which an electrically conductive grid is located, characterized in that the layers of a dielectric are enclosed in an insulating sheath, and the electrically conductive grid between them is formed by concentric circles and / or circuits arranged horizontally offset relative to each other and arranged in a single other triangles and made of a dielectric paint containing 50-85 wt.% electrically conductive filler. 2. The radiation Converter according to claim 1, characterized in that it further includes a substrate of a dielectric with a thickness of 400-800 microns. 3. The radiation Converter according to claim 1, characterized in that the number of layers of the dielectric is 2-50. 4. The radiation Converter according to claim 1, characterized in that the thickness of the paint is 20-300 microns. 5. The radiation Converter according to claim 1, characterized in that the width of the ink is 20-300 microns. 6. The radiation neutralizer according to claim 1, characterized in that the displacement of adjacent circles and / or triangles is 35-700 microns. 7. The radiation neutralizer according to claim 1, characterized in that the diameter of the circle and / or the diameter of the circle describing the triangle is 1-25 mm. 8. The radiation Converter according to claim 1, characterized in that the thickness of the dielectric layer is 100-300 microns. 9. The radiation neutralizer according to claim 1, characterized in that the graphite and / or metal powder with a particle size of 1-50 microns is used as an electrically conductive filler. 10. The radiation neutralizer according to claim 8, characterized in that aluminum or zinc is used as the metal. 11. The radiation neutralizer according to claim 1, characterized in that the electrically conductive grid formed by concentric circles and the contours of the triangles located in one another is made with a ratio of the total number of circles to the total number of triangles of 0.5-1.5. 12. The radiation neutralizer according to claims 1 and 2, characterized in that the layers and the substrate are made of a dielectric selected from the group: mica, glass, paper, thermoplastic and thermoset. 13. The radiation Converter according to claim 1, characterized in that the insulating shell is made of polyethylene, polypropylene, polyvinyl chloride.