RU70358U1 - DEVICE FOR MASKING OBJECTS (OPTIONS) - Google Patents

Abstract

The utility model relates to means of masking objects and can be used as a protective mask-overlap, hiding the object located beneath it from surveillance systems. The device consists of a protective coating 1 having the shape of a tent. The broken side surface of the tent has the form of faces directed at an angle to each other, which are not parallel to any of the surfaces of the protected object 3. The faces are formed during the installation of the tent using mounting devices 4. The width of each of the faces corresponds to or is greater than the maximum length of the electromagnetic wave of the operating range . On the surface of each of the faces of the screen 1 facing the protected object, along its width, freely falling absorbent webs 2 are installed that are not touching the surface of the protected object. Cloths 2 overlap the inner surface of the coating, further protecting the object 3 from electromagnetic and infrared radiation. For optical masking, the outer surface of the coating 1 is painted with a protective paint, while the reflective webs do not have a protective color. According to the first embodiment, the protective coating 1 and the reflective webs 2 are made of flexible materials with resistive properties, according to the second embodiment, only the material of the reflective webs has them, while the outer protective coating only works in the optical frequency range. The broken outer surface of the coating, the metallized layer of which is not parallel to any of the surfaces of the object, reduces the energy of the electromagnetic wave reflected in the opposite direction and reduces the intensity of the echo signal (EPR) by 10-15 dB. The introduction of an additional layer of absorbent panels reduces the EPR by 20-25 dB. 2 N.C., 1 C.P. f-ly, 1 ill.

Description

The utility model relates to means of masking objects and can be used as a protective mask-overlap, hiding the object located beneath it from radar recognition surveillance systems.

A device for radar masking of objects, made in the form of a frame, on which is fixed a mask screen, made in the form of a metal mesh with a mesh that makes up one sixth of the wavelength of the radar surveillance means (1). A disadvantage of the known device is the narrow operating frequency range and poor mass-dimensional performance.

Closest to both options to this utility model is an overlapping mask, made in the form of a screening fabric that completely covers the protected object, fixed with an installation tool. A screening protective sheet) made of a highly conductive perforated film has the form of a pyramid truncated parallel to the plane of the earth, the side faces of which are directed at an angle of 105 ° -125 ° relative to the earth's surface (2).

A disadvantage of the known device (2) is the low masking efficiency in the complete absence of protection against infrared radiation.

The technical result that can be achieved when using the utility model for both variants of its execution is to increase the effectiveness of camouflage.

The technical result according to the first embodiment of the utility model is achieved due to the fact that in the device for masking objects containing a protective coating made of flexible materials with resistive properties and mounting devices for fixing it over the object (2), the protective coating has the shape of a tent, the broken side surface painted in a protective color consists of faces that are directed at an angle to each other and expand towards the bottom, the edges of which are directed down from the top of the tent are formed using installation tools when installing a protective coating over the object, and the surface of the faces are not parallel to any of the surfaces of the object, and the width of each of the faces is chosen to be greater than the maximum length of the electromagnetic wave of the operating range. On the surface of each face facing the protected object

along its width, freely falling absorbent webs can be fixed, overlapping the inner surface of the protective coating without touching the surface of the object, and the absorbent webs are made of flexible materials with resistive properties.

The technical result according to the second embodiment of the utility model is achieved due to the fact that in the device for masking objects containing an external protective coating operating in the optical frequency range and mounting devices for fixing it over the object (2), the protective coating has the shape of a tent, painted in a protective color, the broken side surface of which consists of faces extending at an angle to each other and extending to the bottom, the edges of which are directed downward from the top of the tent and are formed using x devices when installing an external protective coating over an object, moreover, the surface of the faces is not parallel to any of the surfaces of the object, and the width of each of the faces is chosen to be greater than the maximum length of the electromagnetic wave of the working range, while on the surface of each of the faces facing the protected object along its width free-falling absorbent sheets are fixed that overlap the inner surface of the protective coating without touching the surface of the object, and the absorbent sheets are made of flexible their resistive properties of materials.

The drawing shows the design of a device for masking objects.

The device according to both variants of execution consists of an external protective coating 1 and absorbent webs 2. The external protective coating 1 has the shape of a tent fixed over the protected object 3 by means of mounting devices 4. The lateral surface of the coating 1 has the form of being joined at an angle to each other expanding towards the bottom faces whose surfaces are not parallel to any of the surfaces of the protected object 3. Faces and ribs are formed during installation and fixation of the tent using mounting devices 4.

The geometric dimensions of the fractures of the side surface of the tent are determined by the size of the protected object 3 and the working frequency range, in particular, the width of each of the faces should be greater than the maximum length of the electromagnetic wave of the working range.

On the surface of each facet of the coating facing the protected object along its width, freely falling absorbent webs 2 are installed, which can be fixed on one of its upper sides or simultaneously on the upper and lower sides. After assembly, the canvas should not touch the surface of the protected object.

Cloths 2 overlap the inner surface of the coating 1, further protecting the object 3 from electromagnetic and infrared radiation. For optical masking, the outer surface of the coating

painted with a protective paint, while the absorbent webs do not have a protective color. To protect the object from electromagnetic radiation, the canvases 2 (in both cases) are made of a material with resistive properties.

According to the first embodiment, the protective coating 1 painted in protective color and the absorbent webs 4 are made of flexible materials with resistive properties, for example, a highly conductive tape woven into a mesh base or a film connected to the base with a relief surface.

According to the second embodiment, the outer protective coating 1, operating in the optical frequency range, is painted with paint (for optical masking of the object), its material has no resistive properties, and the material of absorbent paintings has.

In the manufacture of coating 1 and absorbent webs from tapes woven into the base, the mesh width of the mesh base is (0.1 ÷ 1) λ, where λ is the average electromagnetic wavelength of the operating range, and the mesh width of the mesh base, the radius of the air loop and the film width relate to each other, respectively: (0.8 ÷ 1.5) :( 1 ÷ 2) :( 0.6 ÷ 2.7).

In the manufacture of the coating 1 and absorbent webs from a film connected to the base, the elements acquire a relief surface formed by uniformly alternating protrusions or depressions, the distance between which is (0.1 ÷ 1) λ, where λ is the average length of the electromagnetic wave of the operating range, and the distance between the protrusions or depressions and their height or depth are related, respectively:

(0.8 ÷ 1.5) :( 1 ÷ 2).

The film containing the impedance layer may be made of a polymeric or polyamide material such as lavsan, on which a thin metallized layer is deposited, for example, of a ferromagnetic alloy. The layer is applied by vacuum metallization. The base can be made of any synthetic or natural threads.

The choice of base material is determined by the operating conditions of the protective coating and must satisfy, in particular, the requirements for strength, flexibility, moisture resistance.

Devices for fixing the coating can be made in the form of any fixing elements, for example, racks, cords, braces, anchor supports, umbrellas, etc. (A.A. Beketov et al. “Disguise the actions of units of the ground forces” Moscow. Military Publishing House of the Ministry of Defense of the USSR, 1976, p. 35).

The metal layer deposited on the film almost completely reflects the radiant thermal energy emanating from the protected object.

Since there is an additional protective layer between the surface of the coating 1 and object 3, consisting of freely falling canvases 2, between which there are air gaps, the thermal energy does not go outside and, therefore, the protection of the object from PC radiation is significantly increased.

When performing a coating with a broken external surface, the metallized layer of which is not parallel to any of the surfaces of the object, the energy of the electromagnetic wave reflected in the opposite direction decreases, which helps to reduce the intensity of the echo signal (EPR) by 10-15 dB.

After the introduction of an additional layer of absorbing panels, the surfaces of which are not parallel to any of the surfaces of the screen and the object, a decrease in the EPR by 20–25 dB is observed.

The object 3 protected from electromagnetic effects is placed under a removable protective coating 1. Electromagnetic waves incident from free space fall on the absorbing elements of the coating, diffusely scattering in their entire volume. In addition to the processes of absorption of electromagnetic waves due to magnetic and dielectric losses in the impedance layer of the film, there are processes of multiple reflection of incident waves from the reliefs of the outer surface of the coating, accompanied by absorption of wave energy. With an arbitrary direction of the incident waves, their scattering is minimized. This is due to the fact that the amplitude of electromagnetic waves when they are reflected from the broken surface of the coating is significantly reduced, in addition, the waves are gradually absorbed in the "small" relief surface elements, for example, air loops, in which the areas of surfaces normal to the incident wave are minimized .

The device allows to reduce the reflection level of radar signals by 20-25 dB, ensuring its practical independence on the background of the earth's surface for modern radar systems

Sources of information taken into account when compiling the description:

Sharokhvostov N.G. and others. "Radio-invisible at the crossing." Information security issues. VIMI, No. 3, 1995

RU 2101658 C1, F41H 3/00, 1998

Claims (3)

1. A device for masking objects, containing a protective coating made of flexible materials with resistive properties, and mounting devices for fixing it over the object, characterized in that the protective coating has the shape of a tent, the broken side surface of which is painted in a protective color and consists of the angles of each other expanding towards the bottom of the faces, directed downwards from the top of the tent, the ribs of which are formed using mounting devices when installing a protective coating over the object, and the surfaces of the faces are not parallel to any of the surfaces of the object, and the width of each of the faces is selected to be greater than the maximum length of the electromagnetic wave of the working range. 2. The device for masking objects according to claim 1, characterized in that on the surface facing each of the faces of the protected object along its width are freely falling absorbent webs that overlap the inner surface of the protective coating without touching the surface of the object, and the absorbent webs are made of flexible materials with resistive properties. 3. A device for masking objects containing an external protective coating operating in the optical frequency range and mounting devices for fixing it over an object, characterized in that the external protective coating has the shape of a tent, the broken side surface of which is painted in a protective color and consists of the angles of each other expanding toward the bottom of the faces, directed downward from the top of the tent, the ribs of which are formed with the help of mounting devices when installing a protective coating over the object, the surfaces of the faces are not parallel to any of the surfaces of the object, and the width of each of the faces is selected to be greater than the maximum length of the electromagnetic wave of the operating range, while freely falling absorbing sheets are fixed on the surface of each face along the width facing the object to be protected, covering the inner surface of the outer protective coatings without touching the surface of the object, and the absorbent webs are made of flexible materials with resistive properties.