RU2231137C1 - Electromagnetic radiation protective device - Google Patents

Abstract

FIELD: electronics; protection of persons against electromagnetic radiation.

SUBSTANCE: device has first substrate that carries square matrix. The latter has set of similar squares each being, essentially, central part of fractal structure symmetrical relative to center, its fractal level M being minimum three. Second substrate is placed under first one and carries structure that has eight similar circles crossing center-of-matrix location with centers of every two adjacent circles equally spaced apart, four of them being disposed at points of intersection of matrix sides. Formed on substrate is group of squares; sides of first square coincide with matrix sides, those of second one cross corners of first square, and sides of third square cross corners of second one, and also set of equal squares with same center, each being turned relative to its equal square through 45 deg. Structures are formed on substrates by lines of crystalline lattice material and electrically insulated from one another.

EFFECT: enlarged functional capabilities.

13 cl, 9 dwg

Description

The invention relates to medicine, industrial and sanitary hygiene and is intended to be used as a means for protection against electromagnetic radiation from a person using various electromagnetic emitters - cordless telephones, computers, televisions, microwave ovens, etc.

Usually, shielding of electronic equipment is used to protect the operator from exposure to electromagnetic radiation. But this type of protection cannot be applied to the operator of the transmitting radio device, in particular the person using the radiotelephone, since the transmitting antenna cannot be placed on the protective shield, but it is in close proximity to the person.

It is known (1) to use as a protective device any human-carried object that acts as a generator of a protective field. For this, the attenuated wave characteristic of the emitter is previously transferred to it. It can be a watch, keychain, keys, etc. Studies by the method of electropuncture diagnostics according to R. Voll showed the effectiveness of such protection.

But such protection is effective against electromagnetic radiation of one type of emitters. When changing the radiation parameters (replacing one type of emitter with another), such a protective device is ineffective.

It is known (2) a device for protecting against the energy impact of a radiotelephone. By design, it is closest to the offer. It contains a substrate on which geometrical figures in the form of stars are placed one above the other, made of magnetic and non-magnetic materials, and an electromagnet is located under the substrate. The known device solves the problem of generating a spin-torsion field quenching the spin-torsion field of a radiotelephone.

But the design of the radiotelephone is a powerful local source of the electromagnetic field as well, from the negative influence of which the known device does not protect.

The problem solved by the invention is the development of a device for protection against electromagnetic radiation from a wide range of electrical devices.

The invention is based on the use of the phenomenon of fractality. A fractal structure is a structure in which all internal components are similar to the general form, and the general form is a derivative analogue of its basic foundation. The mathematical concept of a fractal combines structural forms of various scales, reflecting the hierarchical principle of their organization (3). The concept of fractality in physics appeared relatively recently, but its use provided additional information on the properties of many phenomena, and established links between seemingly completely different physical phenomena and objects. But the theory of the effect of fractal structures on objects is under development, experimental material is accumulating.

The problem is solved due to the fact that, like the well-known, the proposed device contains a first substrate, but in contrast to it, a square matrix is formed on the first substrate, consisting of a set of identical squares. Each square is a central, symmetrical relative to the center, part of the fractal structure with a fractalization level M of at least three, which is formed as follows. The module of the first fractalization level consists of 1 + N circles of radius R ₀ , where N is more than two, and the centers of N circles are located on the first circle at equal distances along it, and a circle with a radius of 2R ₀ , the center of which coincides with the center of the first circle, and the circle with radius 2R ₀ is the first modulus circle of the second fractalization level. At the points of its conjugation with the circles of the first level, the centers of the modules of the first level are located, and the resulting structure is covered by a circle of radius 4R ₀ , which is the first for the module of the third level of fractalization. At the points of its conjugation with the circles of the second-level module, the centers of the second-level modules are located, and the resulting structure is covered by a circle with a radius of 8R ₀ , and then the structure is formed in the same way. Under the first substrate there is a second one on which a structure is formed containing eight identical circles passing through the location of the center of the matrix, with equal distances between the centers of each two adjacent circles, four of which are located at the points of intersection of the sides of the matrix, and a set of squares, the sides of the first of which coincide with the sides of the matrix, the sides of the second pass through the corners of the first, and the sides of the third pass through the corners of the second, as well as the set of squares equal to them, respectively, with the same ntrom, each of which is rotated relative to an equal square at 45 °. The structures on both substrates are formed by lines whose material has a crystal lattice, and the lines on the first substrate are electrically isolated from the lines on the second substrate.

The set of features set forth in paragraph 2 of the claims characterizes a device for protecting a person from electromagnetic radiation, in the fractal structure of which at least one additional circle passes through the intersection points of N circles of the same radius in each module.

The set of features set forth in paragraph 3 of the claims characterizes a device for protecting a person from electromagnetic radiation, in the fractal structure of which at least one additional circle passes through the intersection points of N circles of the first module and the centers of circles with a radius equal to the radius of the additional circles, which covers a circle with a radius equal to two radii of the additional circle, and then additional modules of the second, ... n level are formed i, where n does not exceed M.

Additional circles introduced in paragraphs 2 and 3 of the claims have radii whose values differ from the radii of the remaining circles by a fractional number of times, and this allows to increase the protective effect of the device. The construction of an additional fractal structure introduced by claim 3 of the formula greatly increases the density of lines and enhances the protective properties of the device, but the technology of its manufacture is complicated.

The set of features set forth in paragraph 4 of the claims characterizes a device for protecting a person from electromagnetic radiation, in the fractal structure of which at least one additional circle with radius Rd passes through the points of intersection of N circles of the last-level module, which covers N circles with radii Rd / 2 , mating with them at the same points, and their centers are located on a circle with a radius Rd / 2, the center of which coincides with the center of the additional circle, and each circle of this module is is Busy final module with the same structure with the circles of radii Rd / 4, and further structure fractalized same manner fractalization to a level no greater than M.

This method of “reverse” fractalization of the additional circle is used when the size of the external contour of the module is predefined and it is necessary to obtain a high saturation density with lines, which increases the protective properties of the device.

The set of features set forth in paragraph 5 of the claims characterizes a device for protecting a person from electromagnetic radiation, in the fractal structure of which the number of circles N is 4.

The set of features set forth in paragraph 6 of the claims characterizes a device for protecting a person from electromagnetic radiation, in the fractal structure of which the number of circles N is 8.

A fractal structure with the number of circles N equal to 8 has a very high density of lines, which increases the protective properties of the device compared to N equal to 4, but it is more difficult to manufacture.

The set of features set forth in paragraph 7 of the claims characterizes a device for protecting a person from electromagnetic radiation, in which lines are formed on the second substrate, which are an extension of the sides of the least squares and ending at the points of their intersection with each other.

The set of features set forth in paragraph 8 of the claims characterizes a device for protecting a person from electromagnetic radiation, in which a circle describing the least squares is additionally formed on the second substrate.

The set of features set forth in paragraph 9 of the claims characterizes a device for protecting a person from electromagnetic radiation, in which a circle describing the largest squares is additionally formed on the second substrate.

The experiment shows that all additional lines and circles formed on the second substrate in accordance with paragraphs 7-9 of the claims extend the frequency range to which the protective properties of the device extend.

The set of features set forth in paragraph 10 of the claims characterizes a device for protecting a person from electromagnetic radiation, in which the material of the first substrate is silicon, the material of the second substrate is paper, and the lines of structures formed on both substrates are made of metal.

The set of features set forth in paragraph 11 of the claims characterizes a device for protecting a person from electromagnetic radiation, in which the second substrate is made of polyvinyl and the lines on it are made of graphite.

The implementation of the second substrate of materials such as paper or polyvinyl can reduce the cost of the device.

The set of features set forth in paragraph 12 of the claims characterizes a device for protecting a person from electromagnetic radiation, in which the height of the lines forming the structures on both substrates is equal to or a multiple of their width.

This is the optimal ratio for the effective operation of the device.

The set of features set forth in paragraph 13 of the claims characterizes a device for protecting a person from electromagnetic radiation, in which a sealing coating, for example a compound, is applied to its surface.

Coating is recommended for long life.

One of the hypotheses explaining the effect of the fractal structure on the radiation of a radiotelephone is as follows. When the device for protecting a person from electromagnetic radiation interacts with a radiotelephone located directly next to a person’s head, the distance between the phone’s radiator, the protection device and the brain-receiving areas of the radiation is significantly less than the radiation wavelength. Therefore, in this zone, the field can be considered as quasistatic, the structure of which does not depend on the wavelength, but only on the distances indicated above. This resulting quasistatic field will be modulated by the formed spatial structure of the protection device to a greater extent, the closer the observation point (brain point) to the radiator-protection device system.

The invention is illustrated by drawings, where:

FIG. 1 - general view of the device;

FIG. 2-5 are diagrams of the formation of a fractal structure;

FIG. 6-7 are diagrams of unit squares of a matrix;

FIG. 8 - the first substrate;

FIG. 9 - the second substrate with additional lines.

The device for protecting a person from electromagnetic radiation (Fig. 1) consists of a first substrate 1 on which a square matrix is formed. The matrix consists of a set of identical squares (Fig. 6, 7), each of which is a central, symmetrical relative to the center part of the fractal structure with a fractalization level M of at least three. It is formed as follows: the module of the first fractalization level (Fig. 2) consists of 1 + N circles of radius R ₀ , where N is more than two (in Fig. 2 the module with N = 4 is shown), and the centers (1-4) are N circles are located on the first circle centered at point O at equal distances along it, and circles with a radius of 2R ₀ , the center of which coincides with the center of the first circle at point O. The construction of the first module is complete, but the circle with a radius of 2R ₀ is the first circle of the second-level module (Fig. 3). On this circle at the points of its conjugation with circles of radius R ₀ are the centers of the first-level modules. The construction of the second level module is completed by drawing a circle with a radius of 4R ₀ centered at point O, which, in turn, is the first circle of the third level module (Fig. 6). Further construction proceeds in a similar way, i.e. at the points of conjugation of a circle with a radius of 4R ₀ with circles with a radius of 2R _{0, the} centers of second-level modules are placed and then a circle is drawn with a center at a point O of radius 8R ₀ , etc. In FIG. Figure 4 shows the implementation of the first level module with the fractalization of an additional circle that passes through the intersection points of N circles with each other (1 ₁ , 2 ₁ , 3 ₁ , 4 ₁ ), and its fractalization centers are located at these points. At N = 4, each circle intersects with two neighboring ones and 1 additional circle passes through the points of their intersection. At N = 8, each circle intersects with six neighboring ones, and three additional circles can be drawn through the points of their intersection.

In the case when the size of the outer contour of the last-level module is predefined, the additional fractal structure has a slightly different form: at least one additional circle with radius Rd passes through the intersection points of N circles of the last-level module, which covers N circles with radius Rd / 2 mating with them at the same points, and their centers are located on a circle with a radius Rd / 2, the center of which coincides with the center of the additional circle, and each circle of this module is final for the module with the same structure with circles with a radius of Rd / 4, and then the structure is fractalized in the same way to a level of fractalization not exceeding M. In this case, the minimum additional circle can be located inside a circle with a radius of R ₀ . Such a method of fractalizing an additional circle is illustrated in FIG. 5. For clarity, the modulus of the first fractalization level is shown, where N is 8. An additional circle with a radius Rd passes through the points of intersection of circles with radius R ₀ , and at the same points it is mated with circles with radius Rd / 2.

In the manufacture of the device, a matrix is formed on the first substrate (Fig. 8), consisting of a set of identical squares. Each square represents the central part of one of the fractal structures described above (Figs. 6 and 7). The optimal value of the L side of the square is 2R ₀ (M + 1), with the center of the circle with a radius R ₀ in the center of the square. In FIG. Figure 6 shows the formation of a square at N equal to 4, and at a fractalization level M equal to 3. Using a fractal structure with additional circles (Fig. 7), the line density in the square can be very high. When L = 2R ₀ (M + 1), lines of modules of all levels are used and the density of lines in the square is quite uniform. When located in the center of the square of the center of the circle with radius R _0, we obtain a symmetric, and therefore, stable structure. Under the first substrate is placed a second substrate 2 (Fig. 1). A structure is formed on it containing eight identical circles. The circles pass through the location of the center of the matrix with equal distances between the centers of each two adjacent circles, four of which are located at the points of intersection of the sides of the matrix. A set of squares is also formed on the substrate, the sides of the first of which coincide with the contours of the matrix, the sides of the second pass through the corners of the first, and the sides of the third pass through the corners of the second, as well as the set of squares equal to them, respectively, with the same center, each of which is rotated relative to itself square at 45 °. The structures on both substrates are formed by lines whose material has a crystal lattice, and the lines on the first substrate are electrically isolated from the lines on the second substrate.

To expand the frequency range of electromagnetic radiation, which extends the protective properties of the device, the structure on the second substrate additionally contains lines that are an extension of the sides of the least squares and ending at the points of their intersection with each other (Fig. 9). For the same purpose, a circle describing the matrix, as well as a circle describing the largest squares, is additionally formed on the second substrate. In FIG. 9, these additional lines and circles are shown by thicker lines.

It has been established that fractal structures of a spherical shape have the greatest impact. But their manufacture is practically impracticable at the present time. The proposed device uses a flat cut of the ball. But due to the fact that the lines are made of a material having a crystal lattice, we can assume that the fractal structure is not flat, but has a volume character. The height of the lines and the substrate material with a crystal lattice, for example, silicon, contribute to the increase in the bulk of the fractal structure. Each of these factors increases the protective properties of the device.

There are several ways to formulate the proposed fractal structures on a substrate, for example, by silk-screen printing or photolithography. By screen printing, for example, on a polyvinyl substrate, a fractal structure is obtained with graphite lines 80-100 microns wide and 40-50 microns high. Fractal structures made by photolithography, for example on a silicon substrate, have a line width and height of aluminum of 1 micron.

The maximum effect is exerted by the device, the substrates of which are made of materials having a pronounced crystalline structure, for example silicon, aluminum. But when performing, for example, a tungsten-molybdenum lattice on a silicon substrate with 0.15 micron thick lines, a complex, expensive technology is used, and therefore protection devices made on this basis are quite expensive. The protection device can be cheapened by at least one substrate made of cheap material on which the fractal structure is formed of graphite. But such devices have less impact compared to the above. An important factor in the functional properties of fractal structures formed on a substrate is the barrier effect of a change in the density of a substance, which changes at the interface between the lines forming the fractal structure and the “free field”. The more pronounced this difference, the higher the effect of exposure.

A device for protecting a person from electromagnetic radiation, having dimensions (35 × 35) mm (the size of the matrix being 7.5 mm), is conveniently fixed on the edges of a computer, microwave oven, on the handset of a radiotelephone.

It was experimentally established that the effect of a radiotelephone transmitter has the most negative impact on a person in comparison with other household electronic devices.

The main method for studying the protective properties of the device was electroencephalographic (EEG), which was dictated by the special ratio of EEG to the studied sides of holistic brain activity. The possibility of restoring bioelectric activity (BEA), which was disturbed as a result of exposure to technogenic factors when using a device to protect a person from electromagnetic radiation, was considered.

During the operation of a radiotelephone, changes in the brain of a person are so pronounced that they can be called an electromagnetic storm in a local volume. The results of clinical trials show that the use of a protective device almost completely eliminates these changes. Studies have shown that the use of a radiotelephone clearly changes the structure of BEA, causing the disintegration of the initial activation-deactivation balance, not only the rhythmic pattern is disturbed, but also the pattern of the distribution of rhythms on the surface of the head. In the area of a radiotelephone, asymmetry in delta activity increases on average by 37%. However, in the presence of a protective device, the asymmetry is leveled. During statistical processing of EEG, changed under the influence of a radiotelephone, the most significant changes were detected in the alpha range. The alpha rhythm can be considered as the “coding system” necessary for the brain so that the perception of the outside world and reactions to irritating factors are not distorted and erased by a constant influx of sensory stimuli. In the presence of a protective device, the total rhythmic activity is rearranged and the brain forms an “alpha defense”.

Changing the EEG under the influence of radiation from a computer, television, microwave oven are not so pronounced. But it is known that daily and constant use of a PC monitor for 6-8 years can lead to pathological impairments of vision, central nervous system, cardiovascular and immune systems. But when one or more of the proposed protection devices are located on the electronic device, as the EEG shows, “alpha protection” is formed.

LITERATURE

1. Patent No. 02117497, RU, IPC A 61 N 1/16.

2. Patent No. 2167678, RU, IPC A 61 N 1/16.

3. Paytgen H.O., Richter P.H. "The beauty of fractals," M.: WORLD. 1993.

Claims (13)

1. A device for protecting a person from electromagnetic radiation, comprising a first substrate, characterized in that a square matrix is formed on the first substrate, consisting of a set of identical squares, each of which is a central, symmetrical relative to the center part of the fractal structure with a fractalization level M of at least three which is formed as follows: first level fractalization module consists of 1 + N circle radius R _0, wherein N greater than two, and the centers N circles located on a first circle ti at regular intervals along it, and a circle with a radius of 2R _0, the center of which coincides with the first circle center of a circle with a radius of 2R ₀ is the first circle of the module of the second level fractalization, and the points of its conjugation with the circles first level fractalization module arranged modules venues fractalization first level, and the resultant structure covers a circle with a radius of ₀ 4R, being the first to the third level module fractalization, and the points of its conjugation with the circles of the second level module fractalization p found on the rear center modules of the second level fractalization, and the resultant structure covers a circle with a radius 8R _0, and then the fractal pattern is formed in the same manner under the first substrate is placed a second substrate on which is formed a fractal structure comprising eight identical circles passing through the location of the center of a square matrix , with equal distances between the centers of each two adjacent circles, four of which are located at the intersection points of the sides of the square matrix, and квад squares, the sides of the first of which coincide with the sides of the square matrix, the sides of the second square pass through the corners of the first square, and the sides of the third square through the corners of the second square, as well as the set of squares equal to them, respectively, with the same center, each of which is rotated relatively equal to itself a square of 45 °, the fractal structure being formed by lines of material having a crystal lattice, and the lines on the first substrate are electrically isolated from the lines on the second substrate. 2. The device for protecting a person from electromagnetic radiation according to claim 1, characterized in that at least one additional circle passes through the intersection points of N circles of the same radius in each fractalization level module. 3. The device for protecting a person from electromagnetic radiation according to claim 1, characterized in that at least one additional circle passes through the points of intersection of the N circles of the first module of the fractalization level in the fractal structure and the centers of circles with a radius equal to the radius of the additional circles covered by a circle with a radius equal to two radii of the additional circle, and then additional modules of the second, ... n fractalization level are formed, where n does not exceed M. 4. The device for protecting a person from electromagnetic radiation according to claim 1, characterized in that at least one additional circle with a radius R _d that spans N circles with a radius R _d / passes through the intersection points of N circles of the module of the last fractalization level 2, mating with them at the same points, while their centers are located on a circle with a radius R _d / 2, the center of which coincides with the center of the additional circle, and each circle fractalization this module is the final level for Odulov fractalization level with the same structure with the circles with the radius R _d / 4, and more fractalized structure in the same manner to fractalization module level, not exceeding M. 5. The device for protecting a person from electromagnetic radiation according to any one of claims 1 to 4, characterized in that in the fractal structure the number of circles N is 4. 6. The device for protecting a person from electromagnetic radiation according to any one of claims 1 to 4, characterized in that in the fractal structure the number of circles N is 8. 7. The device for protecting a person from electromagnetic radiation according to any one of claims 1 to 6, characterized in that the structure on the second substrate further comprises lines that are an extension of the sides of the least squares and ending at the points of their intersection with each other. 8. The device for protecting a person from electromagnetic radiation according to any one of claims 1 to 7, characterized in that a circle describing the square matrix is additionally formed on the second substrate. 9. The device for protecting a person from electromagnetic radiation according to any one of claims 1 to 8, characterized in that a circle describing the largest squares is additionally formed on the second substrate. 10. The device for protecting a person from electromagnetic radiation according to any one of claims 1 to 9, characterized in that the material of the first substrate is silicon, the material of the second substrate is paper, and the lines of fractal structures formed on both substrates are made of metal. 11. The device for protecting a person from electromagnetic radiation according to any one of claims 1 to 9, characterized in that the second substrate is made of polyvinyl, and the lines of the fractal structure formed on it are made of graphite. 12. The device for protecting a person from electromagnetic radiation according to any one of claims 1 to 11, characterized in that the height of the lines forming fractal structures on both substrates is equal to or a multiple of their width. 13. The device for protecting a person from electromagnetic radiation according to any one of claims 1 to 12, characterized in that a sealing coating, for example a compound, is applied to its surface.

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