RU2192078C2 - Laminated shield - Google Patents

Abstract

FIELD: protection of electronic devices and personnel from radio-frequency electromagnetic radiation in various industries. SUBSTANCE: proposed laminated shield transparent in visible spectrum of light has at least one additional layer of transparent insulating material placed either on shield surface free from electricity conducting layer, or on electricity conducting layer surface, or at least one additional layer of transparent insulating material is placed on each side of shield. Permittivity of transparent insulating layers reduces with increase in their distance from electricity-conducting layer and surface resistance of electricity conducting layer is 30-60 Ohms per square. EFFECT: reduced fraction of radio-frequency radiation reflected from shield. 5 cl, 1 dwg

Description

 The invention relates to the field of radio engineering, in particular to the field of protection of devices and maintenance personnel from exposure to electromagnetic radiation (EMP) of the radio frequency range, and can be used in mechanical engineering, microelectronics, aviation and other industries to attenuate the electromagnetic field of the radio frequency range both from external and from internal radiation sources.

 A device is known comprising a layer of optically transparent material, on the outside of which there is a thin layer of electrically conductive material. The device is intended to protect electronic devices from external electromagnetic radiation [1].

 The disadvantage of this device is the large proportion of reflected from the screen of radio frequency radiation.

 The closest analogue taken as a prototype is a protective screen of a video display terminal for attenuating electromagnetic radiation, containing a layer of transparent dielectric material, one surface of which is coated with a thin layer of electrically conductive material that has contact with the ground element [2].

 The disadvantage of this protective screen is the large proportion of radio frequency radiation reflected from the screen.

 An object of the invention is to reduce the proportion of radio-frequency radiation reflected from the laminated protective shield while maintaining its transparency in visible light.

 The stated technical problem is achieved by the fact that the proposed laminated protective screen contains at least one additional layer of transparent dielectric material, and at least one additional layer of transparent dielectric material is located either on the surface of the screen free from the electrically conductive layer or on the surface of the electrically conductive layer or on both sides of the protective screen is located at least one additional layer of transparent dielectric material. The value of the dielectric constant of transparent dielectric layers decreases with distance from the conductive layer, and the surface resistance of the conductive layer is 30 ... 60 Ohm / square. The thickness of the transparent dielectric layers of the protective screen is selected depending on the magnitude of their dielectric constant.

 In FIG. 1 (a, b, c, d) shows examples of the implementation of the proposed device layered protective screen.

 The device contains a transparent dielectric layer 1, on one side of which an electrically conductive layer 2 is applied, having electrical contact with the grounding element 3, and at least one additional layer of transparent dielectric material 4 (5, 6).

 FIG. 1a, an additional layer 4 of transparent dielectric material is located on the surface of the electrically conductive layer.

 FIG. 1b - an additional layer 4 of transparent dielectric material is located on the surface of the screen free from the electrically conductive layer.

 FIG. 1c - on each side of the screen there is one additional layer 4 and 5 of transparent dielectric material.

 FIG. 1d - an additional layer 4 of transparent dielectric material is located on the surface of the screen free from an electrically conductive layer and additional layers 5 and 6 of transparent dielectric materials are located on the side of the electrically conductive layer. The number of additional layers of transparent dielectric materials can be increased.

 The device operates as follows (see Fig. 1a). The electromagnetic radiation 7 of the radio frequency range incident on the protective shield partially passes through it 9, partially reflected 8 from the interface: air - the extreme layers of the screen and the interface between the layers inside the screen, and is also partially absorbed in the electrically conductive coating. At the same time, a significant fraction of the incident radiation 7 that has passed into the screen structure undergoes re-reflection from the above layer boundaries of the protective screen, remaining inside the structure and repeatedly passing through an absorbing electrically conductive coating. As a result, the proportion of absorbed radiation increases.

 The table shows the comparative characteristics of the options for implementing a layered protective shield in comparison with the prototype for three values of the surface resistance of the electrically conductive layer.

Tweed - integrated transmission of visible light;
Temi - transmittance of the protective shield in the frequency range of electromagnetic radiation 10-20 GHz;
R1 and R2 are the reflection coefficients from two sides of the protective shield in the frequency range of electromagnetic radiation 10-20 GHz, see Fig.

 Samples 1.1-1.6 were made according to the scheme shown in Fig.la.

 Sample 1.1 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 30 ohms / square. The value of the dielectric constant of the dielectric layer 4 is equal to 7.8.

 Sample 1.2 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 30 ohms / square. The value of the dielectric constant of the dielectric layer 4 is equal to 2.8.

 Sample 1.3 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 40 ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 7.8.

 Sample 1.4 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 40 ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 2.8.

 Sample 1.5 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 60 Ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 7.8.

 Sample 1.6 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 60 Ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 2.8.

 Samples 2.1-2.3 were performed according to the scheme shown in figb.

 Sample 2.1 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 30 ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 2.8.

 Sample 2.2 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 40 ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 2.8.

 Sample 2.3 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 60 Ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 2.8.

 Samples 3.1-3.3 were performed according to the scheme shown in figv.

 Sample 3.1 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 30 ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 2.8. The dielectric constant of the additional dielectric layer 5 is equal to 7.8.

 Sample 3.2 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 40 ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 2.8. The dielectric constant of the additional dielectric layer 5 is equal to 7.8.

 Sample 3.3 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 60 Ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 2.8. The dielectric constant of the additional dielectric layer 5 is equal to 7.8.

 Samples 4.1-4.3 were made according to the scheme shown in Fig.1g.

 Sample 4.1 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 30 ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 2.8. The dielectric constant of the additional dielectric layer 5 is equal to 7.8. The dielectric constant of the additional dielectric layer 6 is equal to 2.8.

 Sample 4.2 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 40 ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 2.8. The dielectric constant of the additional dielectric layer 5 is equal to 7.8. The dielectric constant of the additional dielectric layer 6 is equal to 2.8.

 Sample 4.3 - The dielectric constant of the dielectric layer 1 is equal to 7.8; surface resistance of the electrically conductive layer is 60 Ohms / square. The dielectric constant of the additional dielectric layer 4 is equal to 2.8. The dielectric constant of the additional dielectric layer 5 is equal to 7.8. The dielectric constant of the additional dielectric layer 6 is equal to 2.8.

 As can be seen from the table, the use of the proposed layered protective shield can reduce the level of reflected electromagnetic radiation of the radio frequency range by increasing its absorption, while the proportion of radiation transmitted through the device does not increase. As a result, a decrease in the level of electromagnetic radiation, which has a detrimental effect on the operating personnel and devices sensitive to electromagnetic radiation, is achieved on both sides of the transparent laminated protective shield.

Literature
1. US patent 5373102.

 2. US patent 5122619.

Claims (5)

 1. A layered protective screen, transparent in visible light, containing a layer of transparent dielectric material, on one surface of which is applied an electrically conductive layer having contact with the ground element, characterized in that at least one additional layer of transparent dielectric material is introduced, wherein the surface the resistance of the conductive layer is 30 to 60 ohms / square.  2. The layered protective screen according to claim 1, characterized in that at least one additional layer of transparent dielectric material is located on the surface of the screen free from the electrically conductive layer.  3. The laminated protective shield according to claim 1, characterized in that at least one additional layer of transparent dielectric material is located on the surface of the electrically conductive layer.  4. A layered protective shield according to claim 1, characterized in that at least one additional layer of transparent dielectric material is located on both sides of the screen.  5. A laminated protective shield according to any one of claims 1 to 4, characterized in that the dielectric constant of the layers of transparent dielectric materials decreases with distance from the electrically conductive layer.

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