RU2214026C2 - Process winning coat diminishing backward radar reflection and flexible belt used to make it - Google Patents

Abstract

FIELD: coats reducing visibility of aircraft. SUBSTANCE: salient feature of invention consists in deposition of electric insulation film on which current-conducting layer in the form of slit plate or grid is formed on sections of radio opaque surface of object contributing noticeably to backward radar reflection. Spacing of grid is chosen from interval equal to 1.05 and not more than 2 working lengths of wave of radar radiation. Formula of invention describes specific cases of slit plate or grid. EFFECT: reduced weight of coat with provision for diminished backward radar reflection. 6 cl, 16 dwg

Description

 The invention relates to radio engineering, and specifically to the formation of coatings that reduce the visibility of objects when they are detected by the radar, and can be used to reduce the visibility of aircraft by applying anti-radar coatings to surface areas that make a significant contribution to reverse radar reflection.

 When creating stealth aircraft for radar detection of aircraft, technologies based on the use of absorbing materials and coatings dispersing the radiation energy in a direction different from the direction of the radar radiation were widely used [1]. At the same time, one of the most important problems hindering the use of radar absorbing coatings is their high weight and size characteristics [2].

 A known method of radar masking, including applying to the surface of the object an adhesive layer and a layer containing electrically conductive particles, and forming a coating [3]. In the known method, the adhesive layer is a primer and serves to increase adhesion to the surface of the object of the main layer containing dispersed filler and electrically conductive particles that scatter the radar radiation into the binder and filler, which contributes to the absorption of radiation, and therefore, to reduce reverse radar reflection. However, a decrease in the back reflection is achieved by the large thickness of the applied coating, which increases the weight and size characteristics of the object and limits the use of the coating and the method of its production mainly by the internal components of the aircraft, and not by its skin.

 A known method of obtaining an absorbing coating that reduces reverse radar reflection, including the deposition and formation of a radio-transparent electrical insulating and conductive layers [4]. In the known method, a coating is obtained in which the electrically conductive layer is located between the layers of the dielectric radiolucent material and contains, in addition to the electrically conductive particles, particles providing high dielectric constant and high radiation absorption, the thickness of the electrically conductive layer reaches 0.5 mm, which is associated with the need to maintain the outer surface of the electrically conductive layer at a distance equal to a quarter of the radar wavelength, because of this, the coating formed in a known manner has significantly low weight, which increases the weight of the aircraft. For the longer wavelength part of the radar range, the weight of the coating increases significantly, which limits the possibility of applying the known method to the frequency range 30-100 GHz. In addition, when applying paint layers on surfaces with a high and variable curvature, especially in the presence of structural inhomogeneities, the known method does not provide sufficient accuracy to maintain the location of the interference cancellation plane, whereby the level of reverse radar reflection on these surfaces can be undesirably increased. Due to the unpredictability of the directions of reflection in the presence of technological and structural inhomogeneities, the scattering of radiation by them can enhance the reverse radar reflection from the object.

 Closest to the claimed is a method for coating to reduce reverse radar reflection, which consists in the fact that on the portion of the metal surface of the object, which makes a significant contribution to the reverse radar reflection, a conductive layer and a layer for fixing the conductive layer on a metal substrate are applied [5]. In the known method of countering radars, counteraction is provided by reducing reverse radar reflection from the edges of aircraft wings, various irregularities of aircraft, that is, from surface portions that make a significant contribution to reverse radar reflection. Such areas are called "shiny dots." The method provides for the formation on these areas of the surface of the coating, which reduces reverse radar reflection. The coating is formed by applying to a metal substrate (object surface) a mixture containing electrically conductive magnetized particles in a binder, and the formation of an electrically conductive absorbing layer due to hardening of the binder. The closest option is when the electrically conductive layer is formed using a flexible tape containing a flexible base (layer for fixing). However, the formed coating has an increased weight, which is due to both the thickness of the continuous coating (the electrically conductive layer) at the “brilliant point” (s) and the magnetized particles, since the most common materials of this kind — ferrites — have a high specific gravity. Additional scattering from the coating at one or more “brilliant points” is uncontrollable and can increase back radar reflection by increasing the size and changing the location of “brilliant points”.

 Known flexible tape to obtain a coating that reduces reverse radar reflection, containing a flexible layer and a conductive layer deposited on it [6]. As already noted, the increased thickness of the continuous conductive layer, the need to use magnetized particles with a high specific gravity increase the weight of the coating, and with it the weight of the object, which is not always acceptable for an aircraft. The conductive layer formed by magnetizing particles in a dielectric binder does not reduce the likelihood of “shiny points” due to uncontrolled scattering of radar radiation.

 Closest to the claimed is a flexible tape to obtain a coating that reduces reverse radar reflection, containing a flexible film of electrically insulating material and an electrically conductive layer having the structure of a linear lattice or grid formed by two intersecting linear gratings [7]. In the known flexible tape, the electrically conductive layer is made in the form of bundles formed by polymer filaments and arranged among the filaments with steel or carbon fibers, the bundle layers forming linear lattices, in the aggregate, a grid with a given angle between the bundles. Due to this, on the one hand, high flexibility of the tape is ensured, and on the other, resonant interaction with a radar wave having circular polarization. Known tape is able to reduce reverse radar reflection, provided that the working wavelength of the radar does not exceed the step between the bundles of the tape. In this case, the tape acts as a flexible reflective screen with high radiation scattering. However, the level of reverse radar reflection in this case is high, and the placement of the tape at the “shiny points” is likely to “provoke” the emergence of new “shiny points”. The thickness of the flexible tape due to the thickness of the bundles cannot be reduced, which limits the dimensions of the tape and its use on aircraft.

 According to the invention, a method for producing a coating that reduces reverse radar reflection from surface areas of objects, mainly of the type of aircraft, making a significant contribution to reverse radar reflection, is proposed. The main technical result achieved by this invention is to reduce the weight of the coating while providing a high level of reduction in reverse radar reflection. An additional technical result is the possibility of obtaining a given reflection from the surface of the object.

 The achievement of the main technical result is ensured by the fact that in the method of producing a coating that reduces reverse radar reflection, which consists in the fact that a conductive layer and a layer for fixing the latter on the surface are applied to a portion of the electrically conductive radar opaque surface of the object, which makes a significant contribution to the inverse radar reflection, different the fact that the layer for fixing on the surface is applied in the form of an electrical insulation film, on an electrical insulation film or on an electric a reflection of a rectilinear flat lattice or a rectilinear flat grid is formed in the water layer, the step of which is selected from an interval equal to at least one point five hundredths and no more than two whole working wavelengths of radar radiation, and the conductive layer is applied in accordance with the image in the form of sections of an electrically conductive radio-opaque film separated by slots. In addition, obtaining the display of a lattice or grid on an electrical insulating film and applying sections of an electrically conductive radio-opaque film separated by slots is carried out by applying a flexible tape. In addition, the step or steps of a rectilinear flat lattice or a rectilinear flat grid is selected in accordance with the given directions of radar reflection (which ensures the achievement of an additional technical result).

 The achievement of the main and additional technical results is provided by a flexible tape, which serves to implement the method. In a flexible tape for producing a coating that reduces backward radar reflection, containing a flexible electrically insulating film and a conductive layer having a structure of a rectilinear lattice or a rectilinear grid, the structure of the conductive layer corresponds to a rectilinear slit lattice or rectilinear slit grid, which is made in the form of sections of an electrically conductive radio-opaque film separated slots from each other, and the step or steps of the lattice or mesh selected from an interval equal to at least one whole fifth and hundredths and not more than two entire working length of the radar radiation.

 The invention is as follows.

 For flat electrically conductive surfaces, it has been experimentally established that the formation of coatings in accordance with the invention reduces the reverse radar reflection (hereinafter - ORO). The coating obtained in accordance with the invention consists (see FIGS. 1, 2, 3) of an electrically conductive substrate 1, on which an electrically insulating film 2 and an electrically conductive film are applied in the form of sections of an electrically conductive non-opaque film 3, separated by slots 4. When reproducing the structure of the electrically conductive layer in in accordance with the foregoing, in the form of films (with a total thickness of the electrically conductive and insulating films of not more than 150-200 μm), the periodic slot structure reproduced according to the invention is resonantly excited from the radar system as a radiation slot radiators which forms a distal radio wave reradiation zone with directions defined increments (steps) slot array (grid).

 Non-radio transparency of sections of the conductive film and the conductive substrate provides the conditions for the formation of a slotted system of emitters. In this case, the minimum thicknesses of the deposited films and the substrate are limited only by the requirements of electrical insulation for the conductive film and the thickness of the skin layer of the sections of the conductive film and the substrate. These requirements allow you to choose materials that meet not only operational requirements, but also the requirements of reducing the weight of the coating. The application of films is easily carried out by known methods.

 In view of the foregoing, a reduction in the weight of the coating according to the invention is achieved mainly by reducing the thickness of the layers to the level of the films, as well as by reducing the continuity of the electrically conductive film.

 In addition, it was experimentally established that the properties of the coatings obtained according to the invention on flat surfaces are preserved for coatings formed on curved surfaces of objects. This is ensured by the correct formation of a slotted lattice or mesh on the surface. To do this, make a stencil (template), having the form of a flat rectilinear lattice (or mesh) with a specific step or steps. The stencil is placed on the surface or in contact with it perpendicular to the surface normal to the center of the “brilliant point” region and the grating (grid) is projected onto the image surface in the direction of irradiation. Other reproduction methods are possible. A stencil, a template provides obtaining on the surface (in the general case of a curvilinear) image (display) of a rectilinear lattice or a rectilinear grid formed on the plane, preserving the similarity of its configuration and proximity of dimensions.

 When playing slots on the surface of an object or on a flexible tape, their width is selected from the operating conditions of slot emitters. The width of the steps of the projected grating or grid is determined in relation to the working wavelength of the expected radar exposure. At wavelengths from 1.05 of the operating wavelength to two wavelengths, a significant reduction in back radar reflection is provided. At wavelengths shorter than 1.05 of the operating wavelength or large two wavelengths, the grating (grid) on a flat surface works primarily as a mirror-reflecting screen with reflection, respectively, from the electrically conductive layer with a slotted grating (grid) or from the electrically conductive substrate. The level of reverse radar reflection is high.

 The directions of the given re-reflection angles for both flat and curved surfaces are determined by one or several individual steps of the lattice (grid), polarization of radar radiation. In this case, to reduce the reverse radar reflection with elliptical (circular) polarization of radiation, a picture is used, obtained, as a rule, by projecting a grid, and for radiation with linear polarization, a lattice or grid. Therefore, using the lattice or grid to display with a given step (s), the required angles of re-reflection of the future coating are set. To obtain a coating with desired properties, the following examples for a flat surface can be used, or additional results for a flat surface can be obtained with their subsequent transfer to curvilinear ones.

 Coatings in accordance with the invention are obtained on an electrically conductive, predominantly metallic, surface of an object. The invention can also be used when performing the surface of an object of non-conductive material. In this case, to implement the invention on the surface of the object must first apply an electrically conductive layer-substrate. It is easy to see that the thickness of the substrate can be chosen close to the skin layer, which in some cases also provides a reduction in the weight of the anti-radar coating.

 It has been experimentally established that the formation of a coating according to the invention on areas of the object’s surface that make a significant contribution to the reverse radar reflection (hereinafter referred to as “brilliant points”) provides a reduction in ODP from both “brilliant points” and the object. Knowing the directions of rereflections from the areas of "brilliant points" for each individual coating formed on the object, allows you to consciously and consistently form coatings that reduce the visibility of the object, thereby preventing the emergence of new "brilliant points".

 The use of a flexible tape according to the invention allows to accelerate the formation of coatings with desired properties in the serial production of objects, when upgrading or repairing their anti-radar systems.

The figure 1 presents the image of the coating obtained by the present method, with the structure of the conductive film in the form of a slit grid on the surface of a metal plane of finite dimensions in an axanometric projection, and figure 2 shows an image of the specified coating in cross section with a plane perpendicular to the metal plane. The figure 3 shows the coating of a metal plane of finite dimensions in an axanometric projection with the structure of the conductive film in the form of a slit lattice. Figure 4 shows a backscatter diagram of a metal plane of final dimensions without coating, curve 1, and with the coating according to the invention depicted in Figure 3, with a grid step close to the average value of the claimed grid spacing, curve 2. Figure 5 shows a diagram effective scattering surface of the metal plane without coating, curve 1 (interval of angles in figure 5 from 0 to minus 180 ^o ) and with a coating in the form of a slit lattice shown in figure 3, curve 2 (interval of angles from 0 to 180 ^o ). Figure 6 shows diagrams of the effective scattering surface (hereinafter referred to as EPR) of the uncoated metal plane, curve 1, and with the coating, according to figure 1, curve 2, when the grid spacing is optimal. The figure 7 shows a diagram of the effective scattering surface of the metal plane without coating, curve 1, and with the claimed coating with the structure of the electrically conductive film in the form of a square slit mesh with a grid pitch equal to the extreme upper, curve 2, and the lowest, curve 3, the values of the step interval the grid. Figure 8 shows diagrams of the effective scattering surface of a metal plane without coating, curve 1, and the same plane with a coating with the structure of an electrically conductive film in the form of a square slit grid with a grid step equal to the transcendental values: greater than the upper, curve 2, and less than the lower, curve 3, the values of the optimal interval. The diagrams are recorded in a plane perpendicular to the surface of the object.

Figure 9 shows an image of a dihedral corner reflector with an opening angle of 90 ^° , on the inner surface of which is coated according to the invention with the structure of an electrically conductive layer in the form of a linear grid, obtained by projecting a rectangular grid from a plane perpendicular to the direction of radar radiation corresponding to the axis of symmetry of the reflector, with several steps of the projected mesh selected from the claimed mesh step interval. Figure 10 shows a diagram of the effective scattering surface depicted in figure 9 of an angular reflector, with and without coating (curve 1) (curve 2). The figure 11 shows a diagram of the effective scattering surface of a dihedral corner reflector with an opening angle of 90 ^o , on the inner surface of which is coated according to the invention with the structure of an electrically conductive film in the form of a linear square grid with the projected grid step selected at the lowermost (curve 1) and extreme upper (curve 2) the values of the steps of the optimal interval. The diagrams are recorded in a plane perpendicular to the generatrix of the dihedral angle.

 Figure 12 shows a scan of the slit lattice used to display and apply the coating obtained according to the invention on the outer surface of a metal cylinder. The figure 13 shows a diagram of the back radar scattering from the coated cylinder, the structure of the slit lattice of the electrically conductive film of which corresponds to the scan shown in figure 12, recorded in a plane perpendicular to the axis of the cylinder.

 Figure 14 shows a model in the form of a metal cylinder with an airplane profile, a top view, and Figure 15 shows diagrams of the effective scattering surface of the model, recorded in a plane perpendicular to the cylinder generatrix: without coating, curve 1, and with a coating with the structure of an electrically conductive film in the form square slit grid, curve 2, deposited on its entire surface, formed by the generatrix of the cylinder, and formed using a flexible tape. The figure 16 shows a flexible tape according to the invention in cross section with a plane perpendicular to the surface.

 The inventive method is as follows. An electrically insulating film is applied to the conductive surface of the “shiny dot”. The film is applied by spraying, painting, dipping electrical insulation material, for example, electrical insulating varnish. An electrically conductive film is sprayed, painted, sprayed, etc., onto a formed electrical insulating film through a stencil that displays a rectilinear slit grid or a rectilinear grid with a step (s) selected in accordance with the interval of optimal values. For application, suspensions with a filler of electrically conductive material, metals, carbon, are used. If necessary, a radiolucent film is applied to the formed coating to protect it from atmospheric influences. The thickness of the films is determined by the methods of their application and the materials used for this.

 The coating can also be obtained using a flexible tape with the structure of an electrically conductive film in accordance with the invention. The flexible tape contains (see FIG. 16) a flexible electrical insulating film 2, on the surface of which a rectilinear slit grating or a rectilinear slit grid is applied in the form of sections 3 of an electrically conductive radio-opaque film separated from each other by slots 4, the step or steps of the lattice or grid being selected from the interval equal to not less than one point five hundredths and not more than two point whole working wavelength of radar radiation. A radiolucent film of glue is applied to the surface of the object, and then a flexible tape is applied.

 The resulting coating reflects radar radiation in accordance with the directions specified by the pitch of the grating (grid). Due to which ORO decreases. In this case, the radar radiation corresponding to the working wavelength excites the gap, forms a traveling wave along the surface, exciting the gap. In the far zone, slot emitters form in accordance with a given step the direction of the re-radiation field. Flexible tape can also be used to obtain selectively reflective surfaces, such as screens.

 Below are the results of experimental studies, selected as examples of the implementation of the proposed method, as well as confirming the correct choice of its parameters. Moreover, in the following examples for the production of coatings on a metal plane of finite dimensions, mock-ups were made in the form of plane-parallel plates with a one-sided coating and both sides of the plate were used for EPR measurements.

Example 1. A layer of electrical insulation material of polyethylene terephthalate was deposited on a metal plane of finite dimensions, and after it was dried, a film of a suspension containing an electrically conductive finely dispersed copper powder in the same polymer binder with the following suspension composition, in mass parts: 80 copper powder and 20 polymer, was dried through a stencil. The stencil had the form of a flat rectilinear grid with square cells with a size (pitch) of 1.41λ, where λ is the expected working wavelength of the radar radiation. The thicknesses of the deposited electrical insulating and conductive films after their formation (hardening) were respectively 52-60 and 68-76 microns. The resulting coating had the form shown in figure 1. Figure 6 presents the results of measuring the effective scattering surface diagram of the uncoated metal plane, curve 1, and from the coated metal plane, curve 2. As follows from figure 6, the value of the effective scattering surface for the direction radar radiation incidence normal to the metal surface (in figure 6 the direction 180 ^o) decreased after coating is 100 times, in the radiation was pereotrazheno spatial cone with carbon m at the top in a 85-95 ^o, i.e. with deviation from the direction of fall. The coating was formed for λ = 3.2 cm. Radar irradiation and measurements were carried out in an anechoic chamber by an electromagnetic wave with circular polarization at λ = 3.2 cm.

Example 2. The example was carried out analogously to example 1. The difference was that the structure of the electrically conductive film was formed in the form of a slit lattice shown in figure 3, with a step of 1.32λ. The figure 4 shows the measurement results of the backscattering diagram of a metal plate without coating, curve 1, and with a coating, curve 2. It follows that the use of a coating on a metal plate with a structure of an electrically conductive film in the form of a slotted grating with the indicated step reduces the normal reflection of radio waves to the plane of the plate for 6-7 dB, and wherein the energy of the incident wave normal to the plate is pumped into the space sector to turn away from the normal minimum of ± (30-45) ^o, apart from the maxima in these reflections directions. The backscatter pattern is measured at a fixed angle of irradiation of the object (we are normal to the plane of the plate) and the reflected signal is measured in the required sectors to the left and right of the normal to the plane of the plate. The figure 5 shows the EPR diagram of this metal plate without coating, curve 1 (sector of angles from 0 to minus 180 ^o ), and with a coating in the form of the specified slotted lattice, curve 2, (sector of angles from 0 to 180 ^o ). The directions of 45 ^o , 90 ^o and 135 ^o , figure 5, curve 2, have a noticeable decrease in EPR by 6.5-7 dB compared with the directions -45 ^o , -90 ^o and -135 ^o , figure 5, curve 1. This It also confirms the fact that when irradiated at an angle of 45 ^o or 135 ^o this structure in the form of a slit lattice deposited on a metal surface by a signal from a radar, the energy of the reflected signals will be pumped in the direction normal to the screen and an angle of 135 ^o or 45 ^o , respectively. The coating was formed for λ = 3.2 cm. Irradiation was carried out by an electromagnetic signal with linear polarization at a wavelength of 3.2 centimeters.

 Example 3. The example was carried out analogously to example 1. The difference was that the structure of the conductive film was formed by sputtering an aluminum film with a thickness of 10 μm. The EPR diagram had a form similar to that shown in figure 6 (the diagram is not shown). In this case, the angles and nature of rereflection did not change, and the value of the EPR after coating decreased by 168 times. The observed decrease in EPR compared to Example 1 indicates a more snug fit of the deposited metal film to the insulating substrate.

 Example 4. A square grid was displayed on the flat surface of the mylar film and a thin copper film was applied by electrochemical methods and the copper film structure was formed in the form of a square slit grid with a step equal to 1.41λ. The total thickness of the obtained flexible tape was 128 μm. An insulating film with parameters similar to Example 1 was applied to the surface of a metal plane of finite dimensions. A flexible tape was applied to the liquid film of the varnish, and after hardening of the varnish, the ESR of the resulting coating was measured. The measurement results almost coincided with the results obtained in example 1. The coating was formed, and the measurements were carried out for λ = 3.2 cm with circular polarization.

 Examples 5-6. Coatings were formed and radar measurements were carried out analogously to Example 1. The differences were that flat square grids with steps of 1.05λ (Example 5) and 2.0λ (Example 6) were used to display and apply the structure of the slit mesh. The EPR measurement results are shown in FIG. 7, where curve 1 corresponds to the EPR of the uncoated metal plane, curve 2 corresponds to the EPR of the coated metal plane at a pitch of a slit grid of an electrically conductive film of 2.0λ, and curve 3 - at a step of 1.05λ. According to measurements, the EPR value at step 1.05λ for the direction of incidence of radar radiation normal to the surface of the coated metal plane, the EPR value is 28% of the maximum EPR, and at 2.0λ, the EPR value is 48% of the maximum value for a metal surface in normal fall.

 Examples 7-8 (justification for the choice of interval). Coatings were formed and measurements were carried out analogously to example 1. The differences were that for the display and deposition of the structure of the electrically conductive film, we used a step of 0.8λ (example 7) and 2.8λ (example 8). The EPR measurement results are shown in Figure 8. As the measurements indicate, the EPR value at 0.8λ for the direction of incidence of radar radiation normal to the metal surface after coating decreased only by 30%, the direction of reflection of radiation in the indicated irradiation sector remained practically unchanged. At a step of 2.8λ, an EPR reduction of 15% was obtained. The results indicate the inappropriateness of using coatings with such a pitch of the slit mesh to reduce ORO.

Example 9. The coating was applied to the inner surface of a dihedral 90 ^o metal corner reflector of finite dimensions. For display, we used a flat rectangular grid with a constant step of 1.41λ and a variable step, which averaged 1.05λ at the edges and in the middle of the grid, and 1.87λ between the central and end sections. The mapping was performed by a rectilinear geometric projection parallel to the plane passing through the axis of symmetry and the dihedral angle generator. In this case, the flat grid was previously oriented so that the lines of the variable pitch were parallel to the generatrix of the angle. A film of electrical insulating varnish AC-1115 was applied to the surface of the reflector, on which strips of aluminum foil were applied in accordance with the image of the grid, thereby forming a coating with a slotted grid of variable pitch. The coating thickness was 188 μm. The angled reflector with a coating is depicted in figure 9, which also shows the orientation of the reflector relative to the coordinate system. The measurement results of the EPR of the reflector with and without coating are shown in Figure 10. From the measurement results it follows that the EPR of the reflector along the axis of symmetry in the sector ± 30 ^o from the bisector of the corner reflector decreased by 17.2 times when applying the coating. The coating was formed and measurements were carried out for λ = 3.2 cm with circular polarization.

 Examples 10-11. Coatings were formed and measurements were carried out analogously to example 9. The differences were that square grids with a step of 1.05λ (example 10) and 2.0λ (example 11) were used to display and apply a slit mesh on an electrically conductive film. The EPR measurement results are shown in FIG. 11, where curve 1 corresponds to a flat grid pitch of 1.05λ, curve 2 to 2.0λ, and curve 3 to the EPR of an uncoated reflector. As evidenced by measurements formed in compliance with the optimal coverage interval, they can be used to reduce the ORO (EPR) of the corner reflector and systems similar to it.

Example 12. The coating was applied to the outer surface of a metal cylinder of finite dimensions with a radius of 25λ transversely forming through a flexible stencil, depicted in figure 12 in the form of a scan. The sweep step on a flat surface was 1.27λ. Otherwise, the coating was obtained analogously to Example 1. The results of measuring the backscatter pattern are shown in Figure 13. The amount of backscatter in the 20-degree sector when the object is irradiated strictly along the normal to the tangent plane at the point of incidence electromagnetic signal on a cylindrical surface, when coating was reduced (figure 13, curve 2) to a value of 0.32 of the maximum signal (figure 13, curve 1). Radiation incident normally on a cylindrical surface is reflected with maxima mainly in the directions of 90 and 150 ^o (figure 13, curve 2). For measurements, linearly polarized radiation with λ = 3.2 cm was used.

 Example 13. Reduced the EPR model of the aircraft shown in figure 14, and made in the form of a metal cylinder with an airplane profile. The dimensions of the cylinder along the axis of the aircraft were 5.7λ, in the wingspan - 5λ. Bends of the surface simulated inhomogeneities smaller than λ, and the edges of the wings and nose - the region of "shiny points". The ESR of the surface of the model formed by the cylinder generatrix, without coating, is shown in Figure 15, curve 1. On the entire surface of the model formed by the cylinder generatrix, a flexible tape with an lavsan substrate and a copper film with a square grid structure with a step of 1.41λ was glued with an insulating varnish ( see example 4). Before gluing, a group of parallel slots were oriented parallel to the cylinder generatrix. The results of measurements of EPG with the coating are shown in figure 15, curve 2. Coatings were formed and measurements were performed for λ = 3.2 cm with circular polarization of the electromagnetic field. As evidenced by the measurement results, the EPR of the "brilliant points" decreased at least twice and a maximum of 20 times. The results indicate the possibility of using the proposed method to reduce ORO from "brilliant points".

 The estimates of the reduction in coating weight for a wavelength of 3.2 cm on aircraft models show that the weight of the coating can be reduced by 3-4 times compared with traditional absorbing materials.

 Similar results were obtained on other models for various methods of displaying, applying and forming a coating at “brilliant points” at other wavelengths of the microwave range. In this case, there was a significant decrease in the EPR of objects and a slight increase in their weight due to coating. The results indicate the promise of using the invention to reduce the radio visibility of objects such as aircraft, especially in the low-frequency region of the microwave range.

Sources of information
1. Foreign Military Review, 1988, 6, p. 45-46.

 2. Foreign Military Review, 1999, 4, p.30.

 3. The patent of Germany 2136000, IPC H 01 Q 17/00, C 09 D 5/30, publ. 1979

 4. Copyright certificate of the USSR 1786567, IPC H 01 Q 17/00, publ. 1993 year

 5. US patent 4173018, IPC H 01 Q, n.cl. 343/18 A, publ. 1979 - a prototype.

 6. US patent 4173018, IPC H 01 Q, n.cl. 343/18 A, publ. 1979

 7. German patent 2601062, IPC H 01 Q 17/00, H 01 Q 15/00, publ. 1979 - a prototype.

Claims (6)

 1. The method of obtaining a coating that reduces reverse radar reflection, which consists in the fact that on the portion of the electrically conductive non-transparent surface of the object, making a significant contribution to the reverse radar reflection, a layer is applied for fixing on the surface and an electrically conductive layer, characterized in that the layer for fixing on the surface They are made in the form of an electrical insulating film, and an electrically conductive layer is formed on it in the form of a slit lattice or a grid consisting of sections of a radio-opaque electric wire one film, separated by slots, the location of which displays a flat rectilinear lattice or grid, the step or steps of which are selected from an interval equal to at least one point five hundredths and not more than two point whole working wavelength of radar radiation.  2. The method for producing a coating according to claim 1, characterized in that the electrically conductive layer is preliminarily formed on the flexible electrical insulating film in the form of a slotted grating or mesh, and then the electrical insulating film is fixed on the surface of the object.  3. The method of producing a coating according to claim 1 or 2, characterized in that the formation of a slit lattice or grid on an insulating film is carried out by applying an electrically conductive material through a stencil or template made in the form of or indicated by this flat rectilinear lattice or grid.  4. The method for producing a coating according to claim 1, characterized in that the formation of a slit lattice or grid on an electrical insulating film is carried out by displaying said flat rectilinear lattice or grid on it and sequentially applying sections of a radially opaque conductive film in accordance with the display.  5. The method of obtaining a coating according to any one of claims 1 to 4, characterized in that the step or steps of the rectilinear flat lattice or grid is selected in accordance with the given radar reflection angles.  6. A flexible tape for reducing backward radar reflection, comprising a flexible electrically insulating film and an electrically conductive layer deposited on it in the form of a lattice or grid, characterized in that the electrically conductive layer is made in the form of a rectilinear slit lattice or a rectilinear slit grid consisting of sections of a radially opaque conductive film, separated by slots, and the step or steps of the lattice or mesh selected from an interval equal to at least one point five hundredths and not more than two point whole working wavelength of the radar radiation.

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