RU41399U1 - COMPOUND PRODUCT FOR NEUTRALIZATION OF ELECTROMAGNETIC RADIATION - Google Patents

Abstract

The utility model relates to means for shielding various objects from electromagnetic radiation, and more particularly, to composite thin-layer products and materials, including dielectric and metal components to neutralize the harmful effects of electromagnetic radiation. The proposal may find application in the protection systems of biological objects, equipment and electronic systems for individual and collective use. The problem to be solved is the creation of an effective, functionally convenient and technologically simple protective agent in the form of a thin-layer composite product to neutralize a wide range of electromagnetic radiation when used in protection systems of biological objects, equipment, and electronic and electronic systems for individual and collective use. This problem is solved in that in a composite product to neutralize electromagnetic radiation containing a dielectric base and electrically conductive elements, according to a utility model, the dielectric base is made in the form of an elastic strip of a homogeneous or composite material, comprising at least one layer of fabric and, according to at least one layer of continuous and / or discrete conductive coating, and the ratio of the thickness of the dielectric base to the thickness of the layer of conductive coating is in the range 5-500. In addition, the components of the elastic strip of the dielectric base may contain at least one layer of organic and / or polymeric nonwoven materials. In addition, the fabric layer of the dielectric base can be made of natural and / or artificial fiber. In addition, the electrically conductive coating on the components of the dielectric base and / or fabric can be made in the form of at least one layer of metal with a thickness of 0.5-100 μm, selected from group VBB and may further include at least one metal, selected from the group 1 B, 11 B, 1 VA or V 1 B. In addition, the electrically conductive coating on the components of the dielectric base and / or fabric can be made on the basis of mainly sulfides, as well as oxides, carbides or nitrides of a metal selected from the group 1 B, 11 B, 1 VA, VShB or modifications g Afit.

In addition, the electrically conductive coating may be in the form of at least one layer of amorphous soft magnetic, magnetically hard magnets or amorphous metals. In addition, the electrically conductive coating can be made in the form of at least one layer of finely dispersed metal powder from these groups dispersed in an adhesive, mainly epoxy, varnish or other basis with similar adhesive properties. In addition, the electrically conductive coating can be made in the form of alternating continuous and / or discrete layers of these metals or metal compounds, mainly in the form of strips of one or different widths. In addition, the fabric layer of the dielectric base may include metal threads of these metals.

Description

The utility model relates to means for shielding various objects from electromagnetic radiation, and more particularly, to composite thin-layer products and materials, including dielectric and metal components to neutralize the harmful effects of electromagnetic radiation. The proposal may find application in the protection systems of biological objects, equipment and electronic systems for individual and collective use.

A shielding device for neutralizing electromagnetic radiation from computer monitors is known, which contains a filter in the form of an optically transparent plate equipped with layers of materials absorbing long-wave and short-wave EMR components and installed between the monitor and the user (see US Pat. RF No. 2046564, MKI N 05 K 9 \ 00, BI No. 29, 1995).

The disadvantage of such devices is the relatively narrow scope of their use, mainly for protecting PC monitors. In addition, the test results of such filters from various manufacturers show a significant variation in the protection efficiency over the EMP frequency range.

The closest technical solution is a layered absorber to neutralize electromagnetic radiation containing a dielectric base and conductive elements (see BIPM No. 22, part 2, 2003, RF application No. 2001129518 - prototype).

A disadvantage of the known means for neutralizing EMR is the complexity of the manufacturing technology of absorbing elements forming electrically conductive diffraction gratings, the permeability of which increases along the thickness of the product from the outer layer to the inner layers.

The problem to be solved is the creation of an effective, functionally convenient and technologically simple protective agent in the form of a thin-layer composite product to neutralize a wide range of electromagnetic radiation when used in protection systems of biological objects, equipment, and electronic and electronic systems for individual and collective use.

This problem is solved in that in a composite product to neutralize electromagnetic radiation containing a dielectric base and electrically conductive elements, according to a utility model, the dielectric base is made in the form of an elastic strip of a homogeneous or composite material, comprising at least one layer of fabric and, according to at least one layer of continuous and / or discrete conductive coating, and the ratio of the thickness of the dielectric base to the thickness of the layer of conductive coating is in the range 5-500.

In addition, the components of the elastic strip of the dielectric base may contain at least one layer of organic and / or polymeric nonwoven materials.

In addition, the fabric layer of the dielectric base can be made of natural and / or artificial fiber.

In addition, the electrically conductive coating on the components of the dielectric base and / or fabric can be made in the form of at least one layer of metal with a thickness of 0.5-100 μm, selected from group VBB and may further include at least one metal, selected from the group 1 B, 11 B, 1 VA or V 1 B.

In addition, the electrically conductive coating on the components of the dielectric base and / or fabric can be based on, mainly, sulfides, as well as metal oxides, carbides or nitrides, selected from group 1 B, 11 B, 1 VA, VBB or graphite modifications.

In addition, the electrically conductive coating may be in the form of at least one layer of amorphous soft magnetic, magnetically hard magnets or amorphous metals.

In addition, the electrically conductive coating can be made in the form of at least one layer of finely dispersed metal powder from these groups dispersed in an adhesive, mainly epoxy, varnish or other basis with similar adhesive properties.

In addition, the electrically conductive coating can be made in the form of alternating continuous and / or discrete layers of these metals or metal compounds, mainly in the form of strips of one or different widths.

In addition, the fabric layer of the dielectric base may include metal threads of these metals.

This embodiment of the composite product to neutralize the electromagnetic radiation of the product with a dielectric base containing an elastic strip including at least one layer of fabric and at least one layer of conductive coating of the specified composition and thickness allows us to solve the problem of increasing the efficiency of the shielding properties of the proposed product and simplifying the technology of its manufacture, in particular, when creating shielding means for protecting electronic systems individually and collectively on the use of the harmful effects of EMR.

For some types of electronic equipment, in particular PCs and cordless telephones, the addition to their body parts from the inside or outside of the proposed multilayer shielding product provides effective electromagnetic protection of the equipment from external emitters or maintenance personnel from internal sources of electromagnetic radiation.

The ratio of the thickness of the dielectric base to the thickness of the layer of the electrically conductive coating is impractical to reduce to less than 5, since the costs of metallizing the layers increase comparatively strongly by one of the known methods, and exceeding this ratio exceeds 500 for most types of electrically conductive coatings EMF screening coefficient.

For the same reasons, it makes sense to maintain the thickness of any layer or a number of layers of a conductive metal or semiconductor coating on the components of a dielectric base or fabric, preferably in the range of 0.5-100 μm, and the diameter of the fabric fibers or the thickness of the layers of the elastic strip, for technological reasons, you must choose not less than 10 microns and not more than 300-500 microns.

The conductive coating on the components of the dielectric base or fabric in the form of a metal layer selected from group VББ and further comprising a metal selected from group 1 B, 11 B, 1 VA or V 1 B, as well as in the form of a coating based mainly on sulfides, as well as oxides, carbides or nitrides of a metal selected from the group 1 B, 11 B, 1 VA, V ШБ or graphite modifications provides, according to known data, effective shielding of EMR up to 40 dB and higher in a wide range of radiation frequencies from units of kHz to GTZ, as well as significant ablenie magnetic and electrostatic fields (see., e.g., U.S. Patents 2,996,710, 4,439,768, 5,153,524, 5,345,243, 4,851,609, 4,710,591, Russian patent 2,046,564, 2,055,450, 2,012,004 and others.).

The implementation of the conductive coating in the form of a layer or layers of amorphous soft magnetic magnets based on 3d-metal-non-metal alloys, magnetically hard magnets based on 3d and 4f metals or amorphous metals based on transition or noble metals or alloys with amorphizing non-metal, in turn , allows, other things being equal, a sharp increase in the shielding properties of the proposed product, including due to an increase in the loss of electromagnetic radiation on the magnetization reversal of these magnets and metal glasses (see FE, Moscow , "Soviet Encyclopedia", v. 1, 1988, p. 67).

The implementation of an electrically conductive coating in the form of a layer of finely dispersed metal powder of the indicated groups dispersed in an adhesive, varnish, or other basis under other conditions can drastically simplify the manufacturing process of a composite product of this kind in comparison with galvanic, ion-plasma, and other coating methods.

In addition, the implementation of an electrically conductive coating in the form of alternating continuous or discrete layers of these metals or metal compounds, mainly in the form of strips of the same or different widths, makes it possible to use for screening effects of interference and diffraction of waves of different lengths in such gratings, which may be useful, for example, for the microwave range of radio waves. A similar effect can be achieved by using metal threads, for example, passed through a warp or weft.

The essence of the utility model is illustrated by the drawings: Fig. 1 shows a cross section of a composite product for neutralizing electromagnetic radiation, the dielectric base of which is made in the form of two elastic strips, between which a layer of metallized fabric is placed. Figure 2 shows a cross section of a composite product in which an elastic dielectric strip is provided on one side with a layer of fabric, and on the other, with a polymer film metallized each on one side. Figure 3 shows a cross section of a composite product, the dielectric base of which is reinforced with a metallized fabric and is also coated on the outside with a layer of metallized fabric. Figure 4 shows a cross section of a composite product with a dielectric base bonded to an elastic strip provided on both sides with metallized fabric layers.

A composite product for neutralizing electromagnetic radiation (Fig. 1) contains a radiolucent dielectric base of two different thickness layers of a polyamide film. An elastic fabric layer 2 in contact with one side of the first layer 1 is provided with electrically contacting or independent metal coatings 3,4 on both sides. Moreover, the layer 2 is bonded to a thinner strip 5 of the specified or other dielectric material for mechanical protection of the metallized fabric 2.

In this case, layer 1 has a thickness of 200-300 μm, layer 5 has a thickness of 100-150 μm, and layer 2 is made in the form of a structured layer of woven material based on natural silk or artificial polyamide fiber with a diameter of 40-60 μm. Conductive coatings 3, 4 on layer 2 of the woven elastic material are made on the basis of nickel with the addition of chromium, copper and silver, on the one hand, 2-4 microns thick, and 4-6 microns on the other. In this case, the fabric base of layer 2 is impregnated with conductive compounds of metal sulfides from group 1B or VShB.

The proposed composite product with the indicated types of conductive coatings allows, according to well-known literature data, to weaken the magnetic component of EMP at frequencies of up to 5 MHz by 3-32 dB, as well as provide relatively effective electrostatic and magnetostatic protection of equipment and consumers.

The specified composite product is made in layers, first elastic strips 1, 5 in rolls, then a fabric that is metallized in one of the known ways. The advantage is given to the galvanic method, as a more technological and well-developed. After a cycle of applying a metal coating 3, 4 to the roll fabric 2 and drying it, layers 1, 2, 5 are connected in a rotary machine at a temperature and pressure, ensuring their strong connection.

A composite product for neutralizing electromagnetic radiation (Fig. 2) contains an elastic dielectric strip 1 provided with a layer of fabric 2 on one side and a polymer film 3 on the other, metallized on one side with electrically conductive layers 4, 5.

Layer 1 is made of 100-140 microns thick dacron, a layer of metallized fabric 2 has a total thickness of 60-80 microns, and an elastic strip 3 with a coating of 20-30 microns. The composition of the conductive coatings 4, 5 may include metals also selected from group V ШБ, which may additionally include at least one metal selected from group 1 B, 11 B, 1 VA or V 1 B. Moreover, the thickness of the conductive coatings 4, 5 can be in the range of 1–20 μm, which is sufficient for use, for example, for shielding PC cases, electronic equipment for individual or collective use.

Such a composite product with the indicated types of conductive coatings can attenuate the electromagnetic field at frequencies up to 1 MHz by 80-90 dB, and at frequencies 30-50

MHz - up to 30-40 dB, and also provide electrostatic and magnetostatic protection of equipment.

As is known, the use of several layers with an electrically conductive coating with different current resistance in a composite product according to one of the indicated options provides an additional total protective effect, which can be indispensable, for example, when creating personal protective equipment against electromagnetic fields.

A composite product for neutralizing electromagnetic radiation (Fig. 3) contains a dielectric base 1 made of polyamide or lavsan reinforced with a metallized fabric 2 and also coated on the outside with a layer of metallized fabric 3. Accordingly, the conductive coatings of these layers are indicated by pos. 4, 5, 6, 7.

Layer 1 has a thickness of 100-200 microns, layers of metallized fabric 2, 3 have a total thickness of 40-80 microns, and coatings have a thickness mainly in the range of 2-10 microns. The composition of the conductive coatings 4, 5, 6, 7 may include both the metals indicated in FIGS. 1, 2, and selected from amorphous soft magnetic magnets based on 3d-metal-non-metal alloys, magnetically hard 3d-based magnets and 4f metals or amorphous metals based on transition or noble metals or alloys with amorphous non-metal.

This embodiment of the composite product allows to achieve an increase in the shielding properties of the proposed product due to the increased loss of electromagnetic radiation on magnetization reversal.

Such a composite product with the indicated types of conductive coatings can further weaken the effect of the electromagnetic field at frequencies of the order of several MHz, as well as at frequencies up to 2 GHz.

A composite product for neutralizing electromagnetic radiation (Fig. 4) has a dielectric base 1 of a polymer film 150-250 μm thick, bonded to a thinner elastic strip 2 of dacron, equipped on both sides with metallized fabric layers 3, 4 containing a conductive coating (pos. .5, 6, 7, 8).

A composite product for neutralizing electromagnetic radiation, made according to the specified options for execution, operates as follows.

The frame 1 of the product, which is, for example, the PC case, is closed from the outside with a protective composite product made according to FIGS. 1, 2, 3, 4, which contains metallized elastic polymer or fabric layers 1, 2, 3 with metal coatings (pos. 4, 5, 6, 7, 8), which are fastened together by one of the known methods.

Electromagnetic radiation from components of a PC or other radio equipment that are active in the radio range, including from a mobile phone that is in standby mode or in the active phase of operation, directed to a composite product, undergoes partial reflection, absorption, or refraction.

Partial absorption of radio wave energy in conductive coatings of a composite product occurs due to multiple changes in the wave path on the elements of a metallized fabric, due to magnetization reversal of magnetics, and joule losses. As a result, the protective properties of the composite product, for example, in the mode of shielding the consumer from EMP, provide practical and relatively effective protection for him or the protected equipment.

One or several continuous or discrete layers of the indicated thickness of the metal or alloy, including those based on the indicated groups of metals or their compounds, including nickel, cobalt or chromium with additives, allows taking into account other factors of the proposal to create an effective screen for EMR.

The implementation of the elastic layer in the form of a woven material based on natural or artificial fiber or in the form of a polymer film with an appropriate conductive coating greatly simplifies the technology of creating protective products of this kind using widely known and tested methods.

In some cases, to further increase the functional characteristics and expand the scope of application, the product frame can be made of material and reinforced with fibers or granules of a material of a different composition, for example, have additional elements, in particular fibers or granules of magnetically active material. In turn, a specific location in the field contact zone also allows you to achieve important results on the correction of a person’s condition by protecting him from electromagnetic radiation and improves the functional properties of the device.

It is also known that the physical effect on the consumer of mobile phones partially protected from electromagnetic radiation using the proposed composite product has a smaller effect on the vascular, cardiac and other functions of a person, therefore, the proposed composite product can serve as a means to normalize the human condition by screening them from exposure AMY.

Claims (9)

1. A composite product for neutralizing electromagnetic radiation, containing a dielectric base and conductive elements, characterized in that the dielectric base is made in the form of an elastic strip of a homogeneous or composite material, comprising at least one layer of fabric and at least one layer of solid and / or discrete conductive coating, and the ratio of the thickness of the dielectric base to the thickness of the layer of conductive coating is in the range of 5-500. 2. The composite product according to claim 1, characterized in that the components of the elastic strip of the dielectric base contain at least one layer of organic and / or polymeric nonwoven materials. 3. A composite product according to claims 1 and 2, characterized in that the layer of fabric of the dielectric base is made of natural and / or artificial fiber. 4. A composite product according to claims 1 to 3, characterized in that the electrically conductive coating on the components of the dielectric base and / or fabric is made in the form of at least one metal layer with a thickness of 0.5-100 μm, selected from group VShB, and can additionally include at least one metal selected from group 1B, 11B, 1VA or VIB. 5. A composite product according to claims 1 to 4, characterized in that the electrically conductive coating on the components of the dielectric base and / or fabric is made mainly of sulfides, as well as metal oxides, carbides or nitrides selected from groups 1B, 11B, 1VA, VShB , or graphite modifications. 6. A composite product according to claims 1-5, characterized in that the electrically conductive coating is made in the form of at least one layer of amorphous soft magnetic, magnetically hard magnets or amorphous metals. 7. A composite product according to claims 1 to 6, characterized in that the electrically conductive coating is made in the form of at least one layer of finely dispersed metal powder from these groups dispersed in an adhesive, mainly epoxy, varnish or other basis with similar adhesive properties. 8. A composite product according to claims 1 to 7, characterized in that the electrically conductive coating is made in the form of alternating continuous and / or discrete layers of these metals or metal compounds, mainly in the form of strips of one or different widths. 9. A composite product according to claims 1 to 8, characterized in that the fabric layer of the dielectric base may include metal threads of these metals.