RU159329U1 - PROTECTIVE CAMERA COVERING - Google Patents

Abstract

1. A protective camouflage coating containing a flexible mesh base, in the cells of which are mounted elastic flexible cylindrical absorbing elements with radially diverging electrically conductive flexible microdipoles made of a material with magnetic properties, characterized in that on the outer side of the incident electromagnetic wave there are bulk boss-shaped elements that are connected to one end of the flexible legs, the other ends of which are fixed on a mesh basis, with volumetric elements are made of a material with magnetic properties. 2. A protective camouflage coating according to claim 1, characterized in that the volumetric elements are made of elastic flexible cylindrical absorbing elements twisted together with radially diverging electrically conductive flexible microdipoles. 3. The protective camouflage coating according to claim 1, characterized in that the microdipoles are made of nanostructured ferromagnetic microwires.

Description

The utility model relates to radio electronics and can be used as a protective tool designed to hide a moving or stationary object located under it from surveillance systems of radar and optical recognition.

Known protective device containing a mesh base on which are mounted hanging absorbing flexible cylindrical elements with electrically conductive microdipoles radially diverging from the axis (RU 2037931 H01Q 17/00, 1992).

A disadvantage of the known device is the impossibility of its use for objects on the march (only at the position). This is due to the fact that when using this design in the form of a cover, dipoles that are on its inner side are deformed and do not provide the necessary absorption of electromagnetic waves, which negatively affects the effectiveness of protection.

Closest to the utility model is a protective camouflage coating (RU 2322735 H01Q 17/00 2006) containing a flexible mesh base, in the cells of which elastic flexible cylindrical absorbing elements with radially diverging electrically conductive flexible microdipoles made of a material with magnetic properties are strengthened. The cylindrical elements form on the outer side of the base facing the incident electromagnetic wave a bulk radio-absorbing structure.

A disadvantage of the known technical solution is the relatively low efficiency of protection against detection of surveillance systems of radar and optical detection. This drawback is due to the fact that when the air moves, the reflected signal from the protected object, the signal differs from the reflected signal of the vibrating vegetation of the earth, which increases the likelihood of radar detection. In addition, the accuracy of the simulation of the underlying surface is reduced during wind, which increases the likelihood of optical detection.

The technical result that can be achieved in the implementation of the utility model is to increase the effectiveness of protection against detection by radar and optical surveillance systems.

The technical result is achieved due to the fact that in a protective camouflage coating containing a flexible mesh base, in the cells of which are mounted elastic flexible cylindrical absorbing elements with radially diverging electrically conductive flexible microdipoles made of a material having magnetic properties on the outer side facing the incident electromagnetic wave bases are placed volumetric elements in the form of bosses, which are connected to one of the ends of the flexible legs, the other ends of which are fixed Rowan based on the mesh, wherein the three-dimensional elements are formed of a material having magnetic properties. Volumetric elements can be made of twisted together elastic flexible cylindrical absorbing elements with radially diverging electrically conductive flexible microdipoles. In this case, microdipoles can be made of nanostructured ferromagnetic microwires.

The drawing shows the design of the device.

The device is made in the form of a mesh base 1, in which are fixed (for example, by weaving) flexible radar absorbing cylindrical elements 2 with electrically conductive microdipoles (type of tinsel) radially diverging from their axis. On the outside of the base 1, facing the incident electromagnetic wave, volume elements 3 (having the shape of bosses) are placed, connected to one of the ends of flexible legs, the other ends of which are fixed on a mesh basis. All radar absorbing elements are made of a material with magnetic properties.

Microdipoles can be made of nanostructured ferromagnetic microwires.

Volumetric elements 3 can be made of the same elastic flexible cylindrical absorbing elements twisted together with radially diverging electrically conductive flexible microdipoles.

The legs with which the volumetric elements 3 are attached to the outer side of the warp can be made of any flexible inelastic material, for example, viscose-lavsan yarns, which are used to weave the net warp.

Elements 2 and 3 form on the outer side of the coating a three-dimensional radar absorbing structure facing the incident wave.

Due to the fact that the inner side of the cover is flat, it is convenient to put it on and remove it from the protected object without engaging the absorbing elements with its rough surface.

The specified working frequency range and the degree of necessary attenuation of the energy of the reflected electromagnetic wave depend on the amount of absorbing coating material, determined by the weaving step and the mesh size of the mesh, the distance between the microdipoles and their size, as well as the number and size of volumetric elements per unit area of the coating.

The device operates as follows.

A camouflage cover is put on the protected object. Electromagnetic waves incident from free space fall on the external absorbing structure of the coating, diffusely scattering in its volume. Along with the processes of absorption of electromagnetic waves due to magnetic losses in microdipoles, there are processes of multiple reflection and re-reflection of incident waves from microdipoles, accompanied by absorption of energy of electromagnetic waves. Against the background of the underlying surface during the movement of air, the volumetric elements 3 located on the outside of the coating oscillate freely, changing the reflected signal from the object and, therefore, increasing the efficiency of its protection against radar detection. With an arbitrary direction of the incident waves, their back reflection is minimized. This is due to the fact that the waves are gradually absorbed in the voluminous fleecy structure formed by the microdipoles randomly located in it. Due to the presence of magnetic properties, dipoles absorb electromagnetic waves of radar detection systems, practically not reflecting them.

When air moves, the chaotic movement of volumetric elements distorts the optical contour of an object located under the coating, which increases the effectiveness of its protection from visual observation.

By changing the shape of the bulk elements and, consequently, the shape of the entire absorbing structure, the conductivity of the absorbing elements and their quantity per unit area of the coating, it is possible to provide the required radio technical characteristics of the protective equipment, for example, the effective value of the working frequency range of electromagnetic radiation, in which there is sufficient efficiency protection.

The fleecy surface of the cover can be painted in the color of the underlying surface, and its configuration changing with the movement of air can more accurately simulate the underlying surface, making the protected object hardly noticeable in the optical range.

Due to the high camouflage properties, a utility model may be most preferable when choosing means of protection for moving and stationary objects from radar and optical detection systems.

Claims (3)

1. A protective camouflage coating containing a flexible mesh base, in the cells of which are mounted elastic flexible cylindrical absorbing elements with radially diverging electrically conductive flexible microdipoles made of a material with magnetic properties, characterized in that on the outer side of the incident electromagnetic wave there are bulk boss-shaped elements that are connected to one end of the flexible legs, the other ends of which are fixed on a mesh basis, with this volumetric elements are made of a material having magnetic properties. 2. The protective camouflage coating according to claim 1, characterized in that the volumetric elements are made of elastic flexible cylindrical absorbing elements twisted together with radially diverging electrically conductive flexible microdipoles. 3. The protective camouflage coating according to claim 1, characterized in that the microdipoles are made of nanostructured ferromagnetic microwires.

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