RU108697U1 - PROTECTIVE COVERING FROM ELECTROMAGNETIC RADIATION OF CELLULAR DEVICES - Google Patents

Abstract

The objective of the solution is to create a cover that protects against electromagnetic radiation from a cell phone / communicator / smartphone or other cellular communication device, providing ease of use with the ability to view the screen / display and dial from the keyboard.

The technical result is to reduce the radiation flux density of the radiation power of a cell phone / communicator / smartphone or other cellular communication device to a minimum, to provide more effective protection without a significant deterioration in communication quality or distortion of the audio signal, as well as to improve the usability of a cell phone / communicator / smartphone or other cellular device in a protective coating.

The problem is solved in that in the protective coating from electromagnetic radiation of cellular communication devices in the form of a device containing a base, according to the solution, the base consists of one or more layers of material, with part of the coating in the area of the antenna and / or screen, and / or keyboard and / or end surfaces and / or the back surface is made in the form of a layer of metallized material, metallized fabric shielding electromagnetic radiation, or a metal mesh, the distance between the rods of which is beyond the radiation wavelength of a cell phone / communicator / smartphone or other cellular communication device, as well as, according to the decision, part of the coverage in the area of the screen and / or keyboard and / or camera lens and / or camera for video calling and / or speaker, and / or a connector for connecting a charger, and / or antenna, and / or light sensor, and / or ON / OFF (power) button, and / or microphone, and / or in the area of any other keys of a cell phone / communicator / smartphone or other cellular device made of transparent or translucent material, such as PVC film or thin flexible glass.

The protective coating may have a part, at least one layer of which the area of the screen and / or keyboard is made of a transparent or translucent electromagnetic radiation shielding metallized material, for example, a transparent or translucent metallized fabric, and / or a PVC layer with an embedded, embedded or applied to another by a method, for example, by spraying, with a metal mesh, the distance between the rods of which is less than the radiation wavelength of a cellular telephone / communicator / smartphone or other cellular device communication, or PVC layers with embedded, embedded or coated in another way inner layer of shielding material is metallized, metallized shielding cloth for protection against electromagnetic radiation and fields.

The protective coating may have an opening in the area of the screen and / or keyboard, and / or end surfaces, and / or the rear surface, and / or the camera lens, and / or camera for video calling, and / or speaker, and / or connector for connection charger, and / or antenna, light sensor, and / or ON / OFF (power) button, and / or microphone, and / or in the area of any other keys of a cell phone / communicator / smartphone or other cellular device.

The protective coating may have an aperture with overall characteristics not exceeding the radiation wavelength of a cell phone / communicator / smartphone and / or other cellular communication device in the area of the antenna and / or screen, and / or keyboard, and / or end surfaces, and / or back the surface and / or lens of the camera and / or camera for a video call, and / or speaker, and / or connector for connecting a charger, and / or antenna, and / or light sensor, and / or ON / OFF (power) button , and / or microphone, and / or in the area of any other cellular keys phone / communicator / smartphone or other cellular device in order to increase the efficiency and usability of the cell phone / communicator / smartphone and / or other cellular device.

The protective coating may be part of a cell phone / communicator / smartphone or other cellular device.

The utility model is illustrated by the drawings: FIG. 1 is a cross-sectional view of the base of a protective coating, which may include several layers, including a layer of metallized material, metallized fabric shielding electromagnetic radiation, or a metal mesh, the distance between the rods of which is less than the radiation wavelength of a cell phone / communicator / smartphone or other cellular device, or be made in the form of a single layer of a transparent or translucent metallized material, for example, transparent or a translucent metallized fabric, or in the form of a PVC layer with a fused, embedded or applied in another way, for example, by spraying, with a metal mesh, the distance between the rods of which is less than the radiation wavelength of a cellphone / communicator / smartphone or other cellular communication device, or in the form of a layer PVC, with an inner layer of shielded metallized material, shielded metallized fabric, fused, integrated, or applied in another way to shield against electromagnetic radiation and fields , Fig.2 is a General view of the protective coatings, Fig.3 is a General view of the installation of the meter of the energy flux density P3-33 during the experiment, where

1 - shielding metallized material or shielding metallized fabric for protection against electromagnetic radiation and fields or metal mesh,

2 - layers of the base material.

A protective coating is a structure with a layer in the form of a metallized material, a metallized fabric that shields electromagnetic radiation, or a metal mesh 1 (Figure 1), which can be made of iron, copper, cobalt, magnesium, silver, chromium, zinc, aluminum or another metal. The distance between the rods of the metal mesh should be less than the radiation wavelength of a cell phone / communicator / smartphone or other cellular communication device to ensure the conditions of the physical effect of the Faraday cages. Metallized material, metallized fabric, shielding electromagnetic radiation, or a metal mesh can be located between the layers of the base material 2 (Figure 1), while the coating can have a part of at least one layer of which is in the area of the screen and / or keyboard, and / or end surfaces, and / or rear surface, and / or camera lens, and / or camera for video calling, and / or speaker, and / or connector for connecting a charger, and / or antenna, and / or light sensor, and / or the ON / OFF (power), and / or microphone buttons a, and / or in the area of any other keys of a cell phone / communicator / smartphone or other cellular communication device, it may be made of a transparent or translucent electromagnetic radiation shielding metallic material, for example, a transparent or translucent metallized fabric, and / or a layer of PVC with fused, built-in or applied in another way, for example, by spraying, with a metal mesh, the distance between the rods of which is less than the radiation wavelength of a cell phone / communicator / smartphone or another cellular communication device, and / or a PVC layer, with an inner layer of a shielding metallized material, shielded metallized fabric, embedded, embedded or applied in another way to protect against electromagnetic radiation and fields.

Layers of the base 2 (Figure 1), covering a metal mesh, shielding electromagnetic radiation, metallized material and / or metallized fabric can be made of leather, artificial leather, plastic, fabric, PVC film, thin flexible glass, etc.

The opening part of the protective coating in the area of the screen and / or keyboard, and / or end surfaces, and / or the rear surface, and / or the camera lens, and / or camera for a video call, and / or speaker, and / or charger connector , and / or antenna, and / or light sensor, and / or ON / OFF (power) button, and / or microphone, and / or in the area of any other keys of a cellular telephone / communicator / smartphone or other cellular communication device may be implemented in the form of one or more leaves and provide the possibility of being open I need to set at the keyboard or monitoring screen. Mounting options for opening parts are also possible using zippers, Velcro, magnets, buttons, magnetic buttons, any other types of mounts, etc. An embodiment of the coating without flaps opening from above and / or below and / or from the front and / or from the rear and / or from the side end surfaces is possible. A possible embodiment of the coating only for the area of the antenna.

Description

The utility model relates to the field of protecting users from electromagnetic radiation in the HF and radio frequencies and can mainly be used in the field of mobile radio communications to protect the user from electromagnetic radiation from wearable radiotelephones and radio stations, cell phones / communicators / smartphones or other cellular devices.

At the moment, a lot of research on the harmful effects of electromagnetic fields (EMF) from cell phones on human health and other biological objects has been made public.

It is proved that already in the first 20 seconds of talking on a cell phone in a person’s electroencephalogram (EEG), changes similar to those in EEG in patients with epilepsy are recorded.

Power Flow Density (MRF) is a kind of “telephone hazard”, a measure of the biological impact of cell phones / communicators / smartphones or other cellular devices. The challenge is to reduce this indicator.

A protective cover for cordless telephones is known from the prior art, comprising a housing with a removable lower end wall, a keyboard window, a telephone microphone on the front wall, a retractable panel, and an antenna hole in the upper end wall, characterized in that the housing is supplemented by a screen installed with the possibility of vertical movement and made in the form of a rectangular parallelepiped with open lower end and rear walls, and its side walls are bent and held ball locks placed in the grooves made on the rear wall of the housing, a sliding panel mounted on the front wall of the housing is made with holes for sound and a protrusion at the removable lower end wall, while the housing and the screen are made of a mixture of material that absorbs electromagnetic radiation and a binder in relation to, %:

A material that absorbs electromagnetic radiation 20-95, a binder of 5-80, and as the mentioned material that absorbs electromagnetic radiation, a material is used that has anisotropy of electrophysical properties and includes natural shungite in an amount of 40-70% by weight of this material (see RF patent No. 2234200 IPC Н04М 1/725).

The disadvantage of the invention is that distortion of the audio signal and deterioration in the quality of reception and communication are allowed, due to the fact that the principle of operation of the protective cover for radiotelephones is based on the absorption effect. In addition, the device does not protect against radiation from the antenna.

A device for protecting a user of a portable wearable cell phone is known, including an element of a dielectric material coated with a metal layer placed in a protective plastic layer. The element is made in the form of fabric in the shape of the back side of the phone, while the metal layer is made on the basis of nickel, and its maximum thickness on the side to be placed on the back of the phone is greater than the thickness of the metal layer of the other side of the fabric (see patent for ПМ No. 8837 MPK Н01М 2 / 02).

This device does not protect the user from radiation from the receiving and emitting element - the antenna, since an element of a dielectric material coated with a metal layer placed in a protective plastic layer shields the "far field", which is responsible for the quality of communication, and not the "near field", which affects Thus, the use of this device can, on the contrary, lead to an increase in the radiation absorbed by the user's head and hand.

A device for protecting against electromagnetic radiation a cell phone tube, characterized in that the screen protecting the person from radiation is the surface of the cell phone facing the person, in the manufacture of which ferromagnetic powder was introduced (see RF patent No. 2237376 IPC Н04М 1 / 03).

The disadvantage of the invention is that the principle of operation of the device is based on the absorption effect, and therefore distortion of the audio signal and deterioration in the quality of reception and communication are allowed.

A device for protecting against electromagnetic radiation from cellular mobile phones, comprising a screen - an absorber of electromagnetic waves containing ferromagnetic powder, characterized in that it further comprises a metal base (reflective substrate) connected on one side to the layer (sheet) of the electromagnetic wave absorber in this way so that when fastened to clothing or equipment, the metal base (reflective substrate) of the screen is always facing the human body, and the absorber layer is facing the telephone onu, while the layer (sheet) of the electromagnetic wave absorber is made of a rubber mixture filled with carbonyl iron powder pretreated in attritors, with an iron content of up to 80 wt.% with an average particle size of 0.5 ÷ 3.0 μm, and the layer thickness the absorber is selected so that the reflection of the radiation of the cell phone from the screen surface is less than 0.05 in the frequency range 1.8 ÷ 1.9 GHz and less than 0.35 in the frequency range 850 ÷ 950 MHz and has a protective and decorative coating at least one of the outer surfaces (see patent for PM No. 76505 IPC H01Q 17/00).

The principle of operation of this device is also based on the absorption effect due to the presence of a ferromagnetic powder in the "electromagnetic wave absorber", in connection with which distortion of the sound signal and deterioration in the quality of reception and communication are also allowed.

Closest to the claimed invention is a device for protecting a biological object from electromagnetic radiation of a cell phone. A device for protecting a biological object from electromagnetic radiation of a cell phone in the form of a cover containing a base, characterized in that the base consists of at least two layers of material, while part of the cover contains a layer in the form of a metal mesh located between the layers of material, and the distance between the rods of the grid is less than the wavelength (see patent for PM No. 68186 IPC Н01М 2/02).

The disadvantage of this device is the inconvenience of operation due to the fact that in order to ensure the effect of the "Faraday Cages" effect, which is the basis for the operating principle and protective effect of this device, it is necessary to have a layer in the form of a metal mesh located between the layers of material in the area of the screen / display keyboard, which complicates the operation of the cellular device, the user does not have the ability to watch the screen and use the keyboard, because a metal mesh layer located between the material layers is not a transparent flexible coating.

The objective of the solution is to create a cover that protects against electromagnetic radiation (EMP) a cellular telephone / communicator / smartphone or other cellular communication device, providing ease of use with the ability to view the screen / display and dial from the keyboard.

The technical result is to reduce the radiation flux density of the radiation power of a cell phone / communicator / smartphone or other cellular communication device to a minimum, to provide more effective protection without a significant deterioration in communication quality or distortion of the audio signal, as well as to improve the usability of a cell phone / communicator / smartphone or other cellular device in a protective coating.

The problem is solved in that in the protective coating from electromagnetic radiation of cellular communication devices in the form of a device containing a base, according to the solution, the base consists of one or more layers of material, with part of the coating in the area of the antenna and / or screen, and / or keyboard and / or end surfaces and / or the back surface is made in the form of a layer of metallized material, metallized fabric shielding electromagnetic radiation, or a metal mesh, the distance between the rods of which is beyond the radiation wavelength of a cell phone / communicator / smartphone or other cellular communication device, as well as, according to the decision, part of the coverage in the area of the screen and / or keyboard and / or camera lens and / or camera for video calling and / or speaker, and / or a connector for connecting a charger, and / or antenna, and / or light sensor, and / or ON / OFF (power) button, and / or microphone, and / or in the area of any other keys of a cell phone / communicator / smartphone or other cellular device made of transparent or translucent material, such as PVC film or thin flexible glass.

The protective coating may have a part, at least one layer of which the area of the screen and / or keyboard is made of a transparent or translucent electromagnetic radiation shielding metallized material, for example, a transparent or translucent metallized fabric, and / or a PVC layer with an embedded, embedded or applied to another by a method, for example, by spraying, with a metal mesh, the distance between the rods of which is less than the radiation wavelength of a cell phone / communicator / smartphone or other cellular device connection, or from a PVC layer, with an inner layer of shielding metallized material, shielded metallized fabric, shielded, metallized fabric, to be protected from electromagnetic radiation and fields, embedded, embedded or applied in another way.

The protective coating may have an opening in the area of the screen and / or keyboard, and / or end surfaces, and / or the rear surface, and / or the camera lens, and / or camera for video calling, and / or speaker, and / or connector for connecting charger, and / or antenna, light sensor, and / or ON / OFF (power) button, and / or microphone, and / or in the area of any other keys of a cell phone / communicator / smartphone or other cellular device.

The protective coating may have an aperture with overall characteristics not exceeding the radiation wavelength of a cell phone / communicator / smartphone and / or other cellular communication device in the area of the antenna and / or screen, and / or keyboard, and / or end surfaces, and / or back the surface and / or lens of the camera and / or camera for a video call, and / or speaker, and / or connector for connecting a charger, and / or antenna, and / or light sensor, and / or ON / OFF (power) button , and / or microphone, and / or in the area of any other cellular keys phone / communicator / smartphone or other cellular device in order to increase the efficiency and usability of the cell phone / communicator / smartphone and / or other cellular device.

The protective coating may be part of a cell phone / communicator / smartphone or other cellular device.

The utility model is illustrated by the drawings: FIG. 1 is a cross-sectional view of the base of a protective coating, which may include several layers, including a layer of metallized material, metallized fabric shielding electromagnetic radiation, or a metal mesh, the distance between the rods of which is less than the radiation wavelength of a cell phone / communicator / smartphone or other cellular device, or be made in the form of a single layer of a transparent or translucent metallized material, for example, transparent or a translucent metallized fabric, or in the form of a PVC layer with a fused, embedded or applied in another way, for example, by spraying, with a metal mesh, the distance between the rods of which is less than the radiation wavelength of a cellphone / communicator / smartphone or other cellular communication device, or in the form of a layer PVC, with an inner layer of shielded metallized material, shielded metallized fabric, fused, integrated, or applied in another way to shield against electromagnetic radiation and fields , Fig.2 is a General view of the protective coatings, Fig.3 is a General view of the installation of the meter of the energy flux density P3-33 during the experiment, where

1 - shielding metallized material or shielding metallized fabric for protection against electromagnetic radiation and fields or metal mesh,

2 - layers of the base material.

A protective coating is a structure with a layer in the form of a metallized material, a metallized fabric that shields electromagnetic radiation, or a metal mesh 1 (Figure 1), which can be made of iron, copper, cobalt, magnesium, silver, chromium, zinc, aluminum or another metal. The distance between the rods of the metal mesh should be less than the radiation wavelength of a cell phone / communicator / smartphone or other cellular communication device to ensure the conditions of the physical effect of the Faraday cages. Metallized material, metallized fabric, shielding electromagnetic radiation, or a metal mesh can be located between the layers of the base material 2 (Figure 1), while the coating can have a part of at least one layer of which is in the area of the screen and / or keyboard, and / or end surfaces, and / or rear surface, and / or camera lens, and / or camera for video calling, and / or speaker, and / or connector for connecting a charger, and / or antenna, and / or light sensor, and / or the ON / OFF (power), and / or microphone buttons a, and / or in the area of any other keys of a cell phone / communicator / smartphone or other cellular communication device, it may be made of a transparent or translucent electromagnetic radiation shielding metallic material, for example, a transparent or translucent metallized fabric, and / or a layer of PVC with fused, built-in or applied in another way, for example, by spraying, with a metal mesh, the distance between the rods of which is less than the radiation wavelength of a cell phone / communicator / smartphone or another cellular communication device, and / or a PVC layer, with an inner layer of a shielding metallized material, shielded metallized fabric, embedded, embedded or applied in another way to protect against electromagnetic radiation and fields.

Layers of the base 2 (Figure 1), covering a metal mesh, shielding electromagnetic radiation, metallized material and / or metallized fabric can be made of leather, artificial leather, plastic, fabric, PVC film, thin flexible glass, etc.

The opening part of the protective coating in the area of the screen and / or keyboard, and / or end surfaces, and / or the rear surface, and / or the camera lens, and / or camera for a video call, and / or speaker, and / or charger connector , and / or antenna, and / or light sensor, and / or ON / OFF (power) button, and / or microphone, and / or in the area of any other keys of a cellular telephone / communicator / smartphone or other cellular communication device may be implemented in the form of one or more leaves and provide the possibility of being open I need to set at the keyboard or monitoring screen. Mounting options for opening parts are also possible using zippers, Velcro, magnets, buttons, magnetic buttons, any other types of mounts, etc. An embodiment of the coating without flaps opening from above and / or below and / or from the front and / or from the rear and / or from the side end surfaces is possible. A possible embodiment of the coating only for the area of the antenna.

The operation of the device is based on the “Faraday Cages” effect, which consists mainly in the fact that electromagnetic radiation does not pass through a metal chamber or mesh, provided that the distance between the grid rods does not exceed the value of the radiation wavelength.

The effectiveness of devices manufactured according to the proposed solution (Figure 2) has been proven in a number of installations, including: energy / power flux density meters P3-18 and P3-33; ThermaCAM SC3000 thermal imaging system, DK-V point diode (11); using installations for biometric monitoring of human physiological parameters to record the effect of the effects of cell phone radiation on cardiovascular system parameters, brain activity, respiration, blood flow velocity, amplitude and frequency of respiratory movements and heart contractions, human pulse wave velocity and other parameters (electroencephallograph "SPEG-NSFT", "Polyspectrum" electrocardiograph, apparatus for recording respiratory movements and heart contractions; I monitor the speed of propagation of a pulse wave, the installation for monitoring the blood flow velocity "Reograph", etc.).

According to the standards adopted in Russia, the level of maximum permissible PPM is set at 10 μW / cm ² ,. It is interesting to note that a much stricter norm has been adopted for Ukraine, namely 2.5 μW / cm ² .

However, in the course of measurements on the energy flux density sensors P3-18 and P3-33 (Figure 3), we found that the PPM value for all the studied phone brands was more than 23 μW / cm ² , which is more than two times higher than that accepted in Russian norm. T.O. Most phones sold in Russia are designed for people who use cellular services rarely and little by little. After placing the phone in a protective device, the PPM value was reduced to normal or even lower, which indicates the high efficiency of these devices.

During the EEG studies using the SPEG-NSFT device, significant changes in the bioelectric activity of the human brain were detected when exposed to radiation from an open telephone, which was not observed when the telephone was exposed to a protective coating.

When studying the thermal effect of a cell phone using the ThermaCAM SC3000 thermal imaging system, it was found that the phone in the protective coating causes less heating of the test fluid, which is also important, because, as you know, with a certain heating of the brain cells they begin to degenerate and irreversibly collapse.

During experimental studies of the influence of the EMF of cell phones on the propagation speed of a pulse wave (SRPV), an increase in SRV was recorded in the event of exposure to radiation from the phone without a protective coating, while it was found that there are no changes when the EMF of the phone is in active mode, placed in protective mode coating.

The same effect was revealed during biometric monitoring of human physiological parameters: periodic chest displacements that characterize respiratory movements and heart contractions, using a microwave autodyne on the Gunn diode when exposed to EMF phones in a protective coating and in its absence, during which it was established that exposure to EMF from the telephone in the absence of a protective coating causes rapid breathing.

So the frequency of respiratory movements when exposed to EMR from a cell phone in the active mode in a protective case was: 12.82 bpm / min and 3.28 mm, when exposed to EMR from a cell phone: 21.06 bpm / min, the amplitude of the respiratory movements - 3 mm.

At the moment, a number of studies have been carried out on the effects of mobile phone radiation on biological objects. During an experiment on a test object, 4 groups of Daphnia were studied, 10 in each group. Freshwater Daphnia crustaceans (Daphnia magna Straus) were cultivated under standard laboratory conditions.

In the experiments, individuals of 0.7–1.5 mm in size were used. A single daphnia from an aquarium culture was moved to a chamber restricting its movement.

The experiment used the three most common brands of GSM standard cell phones with GPRS support. The daphnia heart rate was measured using a special recording processing software made by a video camera under a microscope before being exposed to a cell phone. The heart rate was 6.41 Hz. Then Daphnia was placed next to a working telephone. The phone worked for about an hour. During this time, a conversation was played on the handset with which the call was made to simulate the conditions for the actual use of a cell phone, including the frequency vibrations of the voice. Further, the heart rate was re-measured, heart rate was recorded at an average of 0.2 Hz. Since the heart of daphnia is sensitive to alternating magnetic fields, as the second part of the experiment, it was decided to place daphnia in an alternating magnetic field with a frequency of 5-6 Hz and an amplitude of 25 mT for 1 hour in order to “bring it out of rest”, and then act on it by radiation from a cell phone. After irradiation with an alternating magnetic field, an average shift in heart rate of 1.2 was recorded. Hz

During the study, each daphnia was exposed to a magnetic field for 1 hour. Thus, the measurement of the heartbeat frequency of Daphnia was carried out both before and after exposure to a magnetic field. As follows from the results obtained, an increase in the heart rate as a result of exposure to a magnetic field is observed, with a maximum frequency shift observed at an external magnetic field frequency close to the heart rate of daphnia.

Daphnia was then re-exposed to EMF from a cell phone, and the control group was exposed to the phone in a designed absorbent coating. After irradiation with a cell phone for about an hour, the heart rate shift for the case of using an open telephone was 0.5 Hz. Thus, in experimental studies of the effect of electromagnetic fields from mobile phones on daphnia as a test object, an increase in heart rate was revealed, which indicates the presence of a certain effect of electromagnetic fields from a cell phone.

After irradiation with a cell phone in a protective coating for about an hour, the heart rate shift averaged less than 0.1 Hz, which fits into the installation error, and, therefore, we can conclude that the shift was either extremely insignificant or absent altogether.

The proposed cover allows you to reduce the MRP to normal, while distortion of the audio signal is allowed no more than 5%.

Claims (5)

1. A protective coating against electromagnetic radiation of cellular communication devices in the form of a device containing a base, characterized in that the base consists of one or more layers of material, with part of the coating in the area of the antenna and / or screen, and / or keyboard, and / or the end surfaces and / or the back surface contains a layer in the form of a metallized material, metallized fabric, shielding electromagnetic radiation, or a metal mesh, the distance between the rods of which is less than the radiation wavelength of a cellular telephone she / a communicator / smartphone or other cellular device, characterized in that a part of the coverage is in the area of the screen and / or keyboard, and / or the camera’s lens, and / or the camera for the video call, and / or the speaker, and / or the charger connector device, and / or antenna, and / or light sensor, and / or ON / OFF (power) button, and / or microphone, and / or in the area of any other keys of a cell phone / communicator / smartphone or other cellular communication device transparent or translucent material, e.g. PVC film or t flexible flexible glass. 2. The protective coating according to claim 1, characterized in that at least one layer of part of the coating area of the screen and / or keyboard, and / or end surfaces, and / or the rear surface and / or camera lens, and / or cameras for video calling, and / or speaker, and / or connector for connecting a charger, and / or antenna, and / or light sensor, and / or ON / OFF (power) button, and / or microphone, and / or in the area any other keys of a cell phone / communicator / smartphone or other cellular device made of transparent or translucent e that shields electromagnetic radiation from a metallized material, for example, a transparent or translucent metallized fabric, and / or a layer of PVC with an embedded, embedded or applied in another way, for example by spraying, a metal mesh, the distance between the rods of which is less than the radiation wavelength of a cell phone / communicator / smartphone or other device cellular communication, and / or PVC layer, with an inner layer of shielding metallized material embedded, embedded or otherwise applied, the screen metallizing fabric for protection against electromagnetic radiation and fields. 3. The protective coating according to claim 1, characterized in that it has an opening part in the area of the screen and / or keyboard, and / or end surfaces, and / or the rear surface, and / or the camera lens, and / or camera for video calling, and / or speaker and / or connector for connecting a charger, and / or antenna, and / or light sensor, and / or ON / OFF (power) button, and / or microphone, and / or in the area of any other cellular keys a phone / communicator / smartphone or other cellular device. 4. The protective coating according to claim 1, characterized in that it has an opening with overall characteristics not exceeding the radiation wavelength of a cell phone / communicator / smartphone and / or other cellular communication device in the area of the antenna and / or screen and / or keyboard and / or end surfaces and / or rear surface and / or camera lens and / or camera for video calling and / or speaker and / or connector for connecting a charger and / or antenna and / or light sensor , and / or the ON / OFF (power) button, and / or microphone, and / or in the any other keys of a cell phone / communicator / smartphone or other cellular device in order to increase the efficiency and usability of a cell phone / communicator / smartphone and / or other cellular device. 5. The protective coating according to claim 1, characterized in that it can be part of a cell phone / communicator / smartphone or other cellular communication device.