RU2139579C1 - Device for protection against radiation (modifications) - Google Patents

Abstract

FIELD: means for protection of biological objects against radiation, for example, of those located in the zone of devices generating such a radiation, namely, cathode-ray tubes and cellular telephone sets. SUBSTANCE: the device represents a rectangular frame with internal beams. The frame is made of material with electrical conductivity and crystalline structure. EFFECT: enhanced protection of biological objects against lepton radiation. 3 cl, 2 dwg

Description

 The invention relates to the field of means of protecting a biological object from radiation, mainly complex radiation of electrons, neutrinos, muons, heavy leptons, and can be used to protect biological objects located in the range of devices that generate such radiation.

 At present, it is known that biological objects located for a long time near cathode ray tubes, in particular, computer operators, as well as users of radiotelephones, are prone to fatigue and diseases of the central nervous system. The use of traditional devices used to protect against electromagnetic radiation in these cases does not provide a safe and comfortable working environment. It is also known that people who spend a long time in front of various electron-beam devices (television sets or personal computer monitors) have a slow development. It is no accident that the federal program for working with youth in the United States is largely aimed at reducing the time of television broadcasts intended for children.

 To date, no means and methods are known that directly measure lepton radiation. Known methods for detecting the constituent components of lepton radiation (electrons, neutrinos, muons) cannot provide sufficiently reliable registration of lepton radiation. The only method for diagnosing the presence of lepton radiation at present is to determine the state of a biological object located at different times near the source of lepton radiation.

 The technical problem solved by the present invention is to develop a device that protects biological objects from lepton radiation.

 The technical result obtained as a result of the implementation of the invention is to increase the security of biological objects located near sources of lepton radiation.

 To obtain the specified technical result, according to the first embodiment, it is proposed to use a device containing a frame in the form of a square with eleven beams located inside it and connected to its sides, made, like the frame, of an electrically conductive material having a crystalline structure, and on the sides of the square are sequentially arranged points of connection with the rays, while with the square in the vertical plane, point A (see Fig. 1), taken as the reference point, is located in the lower left Glu, points G, E, and Z, respectively, in the remaining angles, points B, D, G, and I are 0.5 ± 5% of the length of the side of the square from the corners of the square, and point B located between points B and G is removed from point A at a distance of 0.69 ± 5% of the length of the side of the square, the rays are located between points A and E, A and F, B and I, B and D, B and E, B and Z, D and F, D and F, D and I and F and I, the rays DI, AZ and BZ at the intersection are connected to a common point connected by a beam with point I.

 To obtain the technical result, according to the second embodiment, it is proposed to use a device containing a frame in the form of a rectangle with eleven beams located inside it and connected to its sides, made, like the frame, of an electrically conductive material having a crystalline structure, on the sides of the rectangle, the upper side which is 1.6-1.7 times smaller than the lateral side, there are points of connection with the rays, while with the rectangle in the vertical plane, the first point A (with Fig. 2), taken as the reference point, is located in the lower left corner, points D, G and L, respectively, in the remaining corners, points B, E, I, M are removed from the corners of the rectangle by a distance of 0.5 ± 5% of the length of the corresponding sides, and points C, located on the side of AD, Z and K, located on the side of the LC, at a distance of 0.25 ± 10% of the length of the corresponding side, subject to counting from the nearest corner, the rays are located between points A and G, B and M, B and E, B and F, C and K, D and I, E and M, E and I, E and Z, I and M, and the rays AJ, EM and SC at the intersection are connected to a common point connected by a beam with a point L.

 In both embodiments, the frame and beams are preferably made of copper, silver or graphite.

 In FIG. 1 shows an external view of a radiation protection device according to a first embodiment; FIG. 2 shows the appearance of the radiation protection device according to the second embodiment. The letters indicate the attachment points of the beams with a frame.

 Advantageously, for protection against radiation generated by devices equipped with cathode ray tubes, such as, for example, a computer monitor, television, oscilloscope, use the device according to the first embodiment, for protection against radiation resulting from the operation of radio and cell phones, mainly device according to the second embodiment.

 To protect against radiation generated by cathode ray tubes, the device is placed either directly in the body of the monitor or television, or near the body, but not further than 0.3 m from it. The degree of absorption of radiation is determined indirectly by examining the condition of a person who is in direct contact with a device that creates harmful radiation, for example, a personal computer operator. The studies were carried out according to the method of Dr. Richard Voll. According to the above methodology, the state of the operator was determined, namely, the state of the central nervous system and the cardiovascular system, before starting work. The state of the operator was taken as 50 conventional units. After turning on the computer in the absence of a device for absorbing radiation, the state of the central nervous and cardiovascular systems was re-measured an hour later. The condition of the central nervous system corresponded to 65 conventional units, and the cardiovascular state to 70 conventional units, which confirms the negative effect of radiation on humans. Without interruption in operation, a device was placed on the monitor case according to the first embodiment, and after 1 minute, the state of the operator was measured. The state of the central nervous system corresponded to 50 arbitrary units, and the cardiovascular state to 55 arbitrary units. Similar measurements were carried out when a person used other devices equipped with a cathode ray tube. To clarify the type of radiation from which the claimed device protects, quantitative measurements of harmful radiation, such as electromagnetic, x-ray, microwave radiation, were simultaneously performed. As a result, it was found that the indices of the above-mentioned radiations practically did not change, however, a change in the state of a person indicates that the claimed device allows protecting it from the effects of radiation, which is currently impossible to determine using existing direct control means.

 When working with a cell phone, the device corresponding to the second embodiment is inserted directly into the phone body. Studies of the condition of a person using a cell phone according to the method of Dr. Richard Voll showed that the use of the claimed device practically eliminates the effect on the person of radiation caused by leptons.

 The possibility of using the device according to the first embodiment in cell phones was confirmed experimentally, and according to the second variant for protection against the effects of radiation generated by a computer monitor, however, the human condition indicates the primary use of the device according to the first embodiment for protecting against radiation generated by a cathode ray tube, and the device according to the second embodiment from the radiation generated by the radio (cellular) telephone.

Claims (2)

 1. A device for protection against radiation, containing a frame in the form of a square with rays located inside it, made, like the frame, of an electrically conductive material having a crystalline structure, with the connection points with the rays being sequentially located on the sides of the square, while with the square in on the vertical plane, point A, taken as the reference point, is located in the lower left corner of the square, points G, E and Z, respectively, in the remaining corners, points B, D, Zh and I are removed from the corners of the square by a distance equal to 0.5 + 5% d the lengths of the side of the square, and point B, located between points B and D, is removed from point A at a distance of 0.69 + 5% of the length of the side of the square, the rays are located between points A and E, A and G, B and I, B and D , B and E, B and Z, D and F, D and F, D and I, F and I, the rays DI, AF and BZ at the intersection are connected to a common point.  2. Device for radiation protection, containing a frame in the form of a rectangle with rays located inside it, made, like the frame, of an electrically conductive material having a crystalline structure, on the sides of the rectangle, the upper side of which is 1.5 - 1.7 times smaller on the side, there are points of connection with the rays, while with the rectangle in the vertical plane, the first point A, taken as the reference point, is located in the lower left corner, points D, F and L, respectively, in the remaining corners, points B, E, I, M are distant from the corners of the rectangle by a distance of 0.5 + 5% of the length of the corresponding side of the square, and point C located on the side of the blood pressure, and points Z and K located on the side of the LC, at a distance of 0.25 + 5% of the length of the corresponding side of the square when the condition of reference from the nearest corner, the rays are located between points A and F, B and M, B and E, B and F, C and K, D and I, E and M, E and I, E and Z, I and M, moreover, the rays AJ, EM and SC at the intersection are connected to a common point connected by the beam with the point L.

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