RU2168879C1 - Electromagnetic radiation protective device - Google Patents

Abstract

FIELD: radio engineering. SUBSTANCE: device has three conductor layers with two piezoelectric insulating layers in-between; conductors are made of metal, their thickness does not exceed penetration depth of electromagnetic wave of particular frequency into this material; first and third conductor layers are electrically interconnected. Polarized, non- polarized, single-crystal, piezoelectric, or ceramic piezoelectric may be used as piezoelectric insulator. Additional insulating layer may be placed along free surface of first conductor layer, then adhesive layer along free surface of additional conductor layer. Additional metal conductor layer may be placed along free surface of third conductor; total thickness of third and additional conductor layers is greater than penetration depth of electromagnetic wave of particular frequency into this material. EFFECT: enhanced suppression of electromagnetic radiation. 8 cl, 1 dwg

Description

 The invention relates to radio engineering, in particular to means of protection against electromagnetic radiation, and can be used to reduce the level of radiation harmful to health in radiotelephones, computers and other devices for household and special purposes.

 A device for protection against electromagnetic radiation, comprising alternating layers of a conductor and a dielectric (US 4038660, H 01 Q 17 / 00.1977).

 The known device does not sufficiently reduce the intensity of electromagnetic radiation.

 The technical result from the use of the proposed device is to increase the suppression of electromagnetic radiation.

 The specified technical result is achieved by the fact that in the device for protection against electromagnetic radiation, including three layers of the conductor and two layers of dielectric placed between them, the conductors are made of metal, their thicknesses do not exceed the magnitude of the penetration depth of the electromagnetic wave of a given frequency into the metal, and dielectrics made of piezoelectric, the first and third layers of the conductor are electrically connected. The specified technical result is also achieved by the fact that a polarized piezoelectric is used as a piezoelectric.

 The specified technical result is also achieved by the fact that a non-polarized piezoelectric is used as a piezoelectric.

 The indicated technical result is also achieved by the fact that a single crystal piezoelectric is used as a piezoelectric.

 The specified technical result is also achieved by the fact that piezoelectric material is used as a piezoelectric.

 The specified technical result is also achieved by the fact that an additional dielectric layer is introduced along the free surface of the first conductor layer 1, as shown in the drawing.

 The indicated technical result is also achieved by the fact that an adhesive layer is placed along the free surface of the additional dielectric layer.

 The indicated technical result is also achieved by the fact that an additional layer of metal conductor is introduced, placed along the free surface of the third conductor layer 3, as shown in the drawing, the total thickness of the third and additional conductor layers is greater than the penetration of an electromagnetic wave of a given frequency into this metal.

 The drawing shows the proposed device. The device for protection against electromagnetic radiation contains a first metal layer of a conductor 1, a second metal layer of a conductor 2, a third metal layer of a conductor 3, a first layer of a piezoelectric 4, a second layer of a piezoelectric 5, an additional dielectric layer 6, an adhesive layer 7, a connecting element 8, an additional metal conductor layer 9.

The best embodiment of the invention
The device is glued to the body of the radiating radio equipment (not shown in the drawing), for example a radiotelephone, using an adhesive layer 7.

 The device operates as follows. An electromagnetic wave, passing through the adhesive layer 7 and the additional dielectric layer 6 and losing some of its energy in them, falls on the first metal layer 1 and simultaneously (due to the presence of the connecting element 8) induces an electric charge of the same charge on it and the third metal layer 3 sign. The thickness of the metal layers 1-3 should not exceed the value of the depth of penetration into the metal of an electromagnetic wave of a given frequency so that the radiation freely passes through them. Further, an electromagnetic wave, passing through a thin first metal layer 1, propagates in the first layer of piezoelectric 4, spending energy on the reorientation of the polarization vectors of its domains. Then, after passing through a thin metal layer 2, it enters the second layer of piezoelectric 5, the domains of which are oriented by the charge induced on the metal layer 3 in a direction opposite to the orientation direction of the domains of the first layer of piezoelectric 4. As a result, the electromagnetic wave, when passing the second layer of piezoelectric 5, spends on reorientation its domains have even greater energy than when passing through the first layer of piezoelectric 4.

Claims (8)

 1. A device for protection against electromagnetic radiation, including three layers of a conductor and two layers of dielectric placed between them, characterized in that the conductors are made of metal, their thicknesses do not exceed the magnitude of the penetration depth of an electromagnetic wave of a given frequency into the metal, and the dielectrics are made of piezoelectric, the first and third layers of the conductor are electrically connected.  2. The device for protection against electromagnetic radiation according to claim 1, characterized in that a polarized piezoelectric is used as a piezoelectric.  3. The device for protection against electromagnetic radiation according to claim 1, characterized in that a non-polarized piezoelectric is used as a piezoelectric.  4. The device for protection against electromagnetic radiation according to claim 1, characterized in that a single-crystal piezoelectric is used as a piezoelectric.  5. The device for protection against electromagnetic radiation according to claim 1, characterized in that piezoelectric material is used as a piezoelectric.  6. Device for protection against electromagnetic radiation according to any one of paragraphs. 1 to 5, characterized in that an additional dielectric layer is introduced, placed along the free surface of the first conductor layer 1, as shown in Fig. 1.  7. The device for protection against electromagnetic radiation according to claim 6, characterized in that an adhesive layer is introduced along the free surface of the additional conductor layer.  8. Device for protection against electromagnetic radiation according to any one of paragraphs. 1 to 7, characterized in that an additional layer of a metal conductor is introduced, placed along the free surface of the third conductor layer 3, as shown in Fig. 1, the total thickness of the third and additional conductor layers is greater than the penetration of an electromagnetic wave of a given frequency into this metal.