RU83167U1 - DEVICE FOR PROTECTING A HUMAN FROM ELECTROMAGNETIC RADIATION OF MOBILE PHONES - Google Patents

Abstract

1. Device for protecting a person from electromagnetic radiation of mobile phones, made in the form of a layer of conductive material of arbitrary shape and a layer of black material deposited on it with at least one hole of arbitrary shape made in it, closed by a conductive plate, while the outer surface of the layer of conductive material it contacts the radiation source, and a decorative coating made of fluorescent paint is applied over the outer surface of the black material. ! 2. The device according to claim 1, characterized in that the hole of arbitrary shape in the layer of black material is made with any of the sizes in the range of 0.3-1.5 mm ! 3. The device according to claim 1, characterized in that the decorative coating applied over a layer of black material is made non-covering the conductive plate above the hole in it or transparent. ! 4. The device according to claim 1, characterized in that an adhesive layer is applied to the surface of the layer of conductive material.

Description

The utility model relates to medicine, industrial and sanitary hygiene, is intended to be used as a means to protect a person from radiation from electrical devices, and can be used to reduce radiation levels harmful to human health in cordless telephones, computers, and other household and special purpose devices.

The relevance of providing the population with protection against electromagnetic radiation is determined by the intensive introduction of technology, which is a source of high-frequency electromagnetic fields. Currently, the problem of protecting people from electromagnetic radiation occupies one of the leading places in the world due to the fact that electromagnetic radiation is widespread in the human environment and has a great environmental hazard, since almost the entire population is exposed to it.

A device for protecting a person from artificial electromagnetic radiation, comprising a rectangular pulse generator and a transmitting antenna (see the description of the utility model of the Russian Federation No. 1805, 1996 [1]). The disadvantages of the known device are the relative complexity, the need for a power source and a limited scope.

A device for protection against electromagnetic radiation, comprising a protective screen, which is made in the form of a plate of natural shungite material, one surface of which is covered with a protective polymer layer, and the other is made with the possibility of fixing on the source of electromagnetic radiation (see the description of the utility model of the Russian Federation No. 49338 , 2005 [2]). A disadvantage of the known device is the relatively low protection efficiency.

A device for protection against electromagnetic radiation, containing a plastic case, inside which is placed a mixture of mica crystals and acrylic resin (GB 2364602 [3]). The body is equipped with a layer of glue for fixing

on a source of electromagnetic radiation - a mobile phone, a microwave oven, etc. A disadvantage of the known device is the relatively low protection efficiency.

The closest in technical essence to the claimed is a device for protection against electromagnetic radiation, (JP 2008036042 [4]), which is a layer of nylon fabric metallized with silver. The fabric is provided with a layer of glue for fixing on a person’s clothes in the region of the heart, and the adhesive layer is provided with a protective layer of paper. A disadvantage of the known device is the relatively low protection efficiency. In addition, the device is designed to protect not the whole person, but only one of its organs - the heart

Declared as an invention, a device for protecting a person from electromagnetic radiation of mobile phones is aimed at increasing the efficiency of protection from radiation of any electrical devices.

This result is achieved by the fact that the device for protecting a person from electromagnetic radiation of mobile phones is made in the form of a layer of conductive material of arbitrary shape and a layer of black material deposited on it with at least one hole of arbitrary shape made in it closed by a conductive plate, while the outer surface a layer of conductive material is in contact with a radiation source, and a fluorescently decorative coating is applied over the outer surface of the black material paint.

The indicated result is also achieved by the fact that the hole of arbitrary shape in the layer of black material is made with any of the sizes within 0.3-1.5 mm.

A decorative coating is applied over a layer of black material that does not cover the conductive plate above the hole in it or is transparent.

For ease of use, an adhesive layer is applied to the outer surface of the conductive layer.

As it was established experimentally, in the study of the device, the execution of an object worn by a person in the form of a plate of arbitrary shape from a conductive material, one of the surfaces of which is covered with a layer of black material with a hole closed by a conductive plate, reduces the effect on the human body of any radiation entering the device by about this amount times what is the surface area of the plate

more area of the hole in the layer of black material. At the same time, the universality of the device is achieved - providing protection from radiation of any electrical device. To ensure the operability of the device, as was established experimentally, its contact with the radiation source on the outer surface of the layer of conductive material is necessary.

The most optimal holes of arbitrary shape in the layers of black material to perform with any of the sizes in the range of 0.3-1.5 mm. If the hole is less than 0.3 mm, then it grows over time and the device loses its functionality. If the hole is larger than 1.5 mm, then, as experiments have shown, the efficiency decreases faster than the ratio of the area of the conductive material to the area of the hole decreases.

In particular cases of implementation, it is advisable to apply a decorative coating, for example, made with fluorescent paint, on top of the outer surface on a layer of black material. For ease of use, an adhesive layer is applied to the outer surface of the layer of conductive material facing the radiation source.

The performance of the device was checked as follows. Volunteers were subjected to acupuncture examination according to the Voll method by measuring indicators at several randomly selected biologically active points (BAP) without affecting the subject by any radiation. Then, the test subject was alternately placed near a working device — a radiotelephone, a computer, a television set, a microwave oven — and the Voll diagnostics were repeated in the same BATs. It was found that the indicators in all measured BAT decreased significantly (by 20-40 units) when the subject was near each of the devices.

Then, the subject was fixed on the shirt pocket the device described above and again checked the indicators in the same BAT when turning on the devices alternately. It was found that all indicators of BAT returned to the original, those that were before turning on the devices, despite the fact that the subject was in the field of devices. Examination of BAT with the simultaneous inclusion of all devices and the presence of the device on the clothes of the subject showed that they were equal to the originally measured. This shows that the device effectively protects against electromagnetic radiation of various electrical devices.

In another series of experiments, the subject underwent an acupuncture examination with the phone turned off (indicators were normal), while talking on a mobile phone (indicators were falling) and while talking on a mobile phone on which the proposed device was glued (indicators were normal). This shows that the device effectively protects against electromagnetic radiation of various electrical devices, if the proposed device is mounted on the device.

The essence of the device for protecting a person from electromagnetic radiation is illustrated by examples of implementation and the drawing, which shows a cross section of the device in the preferred embodiment.

Example 1. The device contains a layer of conductive material 1 of arbitrary shape (round, square, rectangular, etc.) with a thickness of several microns to 1-2 mm, made of any metal or alloy, and layer 2 of black material. As a black material, any of a number of known ones can be used, since the determining factor is not the chemical composition of the material, but the color (necessarily black). It can be a layer of black rubber, thick fabric, black paint or varnish, black thick paper, etc. The thickness of the layer of black material can be any. In layer 2 of black material, a hole 3 is made with a size in the range of 0.3-1.5 mm. The hole in the layer of black material is closed by a conductive plate 4.

In all cases of implementation, the area of the hole in the layer of black material should be much smaller than the area of the layer of conductive material.

To protect a person working in the zone of electromagnetic radiation of an electric device, the device is mounted on the housing 5 of the device, which is a source of electromagnetic radiation so that the surface of the layer of conductive material is in contact with it (see Fig.).

On top of the outer surface of the black material layer, a decorative coating 6 is made, made with fluorescent paint, not covering the conductive plate above the hole in it or transparent. For ease of fixing the device to the instrument housing, an adhesive layer 7 is applied to the outer surface of the conductive layer.

The operation of the device is not described, since it has no moving parts and is used in statics.

Claims (4)

1. Device for protecting a person from electromagnetic radiation of mobile phones, made in the form of a layer of conductive material of arbitrary shape and a layer of black material deposited on it with at least one hole of arbitrary shape made in it, closed by a conductive plate, while the outer surface of the layer of conductive material it contacts the radiation source, and a decorative coating made of fluorescent paint is applied over the outer surface of the black material. 2. The device according to claim 1, characterized in that the hole of arbitrary shape in the layer of black material is made with any of the sizes in the range of 0.3-1.5 mm 3. The device according to claim 1, characterized in that the decorative coating applied over a layer of black material is made non-covering the conductive plate above the hole in it or transparent. 4. The device according to claim 1, characterized in that an adhesive layer is applied to the surface of the layer of conductive material.