WO2015084207A1

WO2015084207A1 - Radio-transparent armor

Info

Publication number: WO2015084207A1
Application number: PCT/RU2013/001090
Authority: WO
Inventors: Евгений Павлович ВОРОШИЛИН; Владимир Дмитриевич ДОЛИН; Николай Алексеевич КУЛАКОВ; Юрий Сергеевич КУЧЕРОВ; Валерий Иосифович ПОРСЕВ
Original assignee: Открытое акционерное общество "Лантан"
Priority date: 2013-12-05
Filing date: 2013-12-05
Publication date: 2015-06-11

Abstract

Radio-transparent armor for protecting land-based radar equipment against damage caused by destructive means in the form of fragmentation-type and bullet-type armor-piercing bodies, has a multilayer structure and contains a radio-transparent armor-protective screen (1), comprised of an inner layer (2) formed by ceramic elements (3) made of ceramic radio-transparent material which does not contain metal particles and which is in the form of cylinders having convex ends, positioned with the longitudinal axes thereof along the normal to the surface of the armor, wherein neighboring ceramic elements (3) in the inner layer (2) are conjugated to one another at at-least one end of one of the elements by portions of six cylinders which form (3a) a lateral surface, and form, amongst themselves, cavities (8) for accommodating fastening damping elements (9) made of a polyurethane-based material, and wherein the inner layer (2) is provided with reinforcing layers (6, 7) on the boundary surfaces thereof. The armor contains a radio-transparent structural layer (10) which is connected to a reinforcing layer (7) of the armor-protective screen (1) and which is provided with a reinforcing layer (11) on the outer boundary surface thereof, and the reinforcing layers (6, 7, 11) are made of a plastic which is reinforced using organic fibers. The armor can be provided with a superhydrophobic coating.

Description

Radiolucent armor

Technical field

The present invention relates to the field of protection of ground-based radar from damage caused by means of destruction in the form of fragmentation and bullet-proof armor-piercing bodies, in particular, to structural materials for radomes or protective covers of antennas of a radar station, and more particularly, to the composite radiopaque armor used for this purpose .

State of the art

Known armor for ballistic protection against the threat of a bullet (missile) strike (IL, 149591, A). Armor contains many composite armor elements. Each element contains a ceramic body (made of aluminum, silicon carbide, boron carbide, glass ceramics), which has a cylindrical part of the body with two end surfaces, one of which is adapted to face the threat. Each element additionally contains a non-ceramic tape element (made of a durable material: a metal alloy - aluminum, titanium, steel, or glass, carbon, aramid, Kevlar, Raylon, polycarbonate, polyamide, high-density polyethylene, carbon fibers) having internal and external surfaces and a hollow region delimited by the inner surface and adapted to accommodate the indicated ceramic body, and said tape member is mounted on the ceramic body so that said electrical ment contact surrounds the cylindrical part of the body without covering said one end surface. The specified tape element may include a reinforcement placed in it, may be made in the form of a spiral, may create internal radial pressure on the cylindrical part of the ceramic element, may have the shape of a bowl or tube and be adapted to accommodate ceramic elements in it.

The above armor may additionally include a back layer (made of aluminum, Kevlar, high-density polyethylene, aramid, fiberglass), adapted to capture fragments resulting from a ballistic threat. The armor may include a frontal anti-shatter coating (made of fiberglass, Kevlar, thermosetting plastic, thermoplastic rubber), adapted to capture fragments resulting from a ballistic threat. The specified elements of the armor can be interconnected using a binder (for example, thermosetting plastic).

However, the armor described above when using metal alloys in materials of ceramic bodies and tape elements does not have radio transparency, which does not allow its use to protect radar means. In addition, the presence in the armor of tape elements covering the ceramic bodies of the armor elements with the formation of tension areas in them leads to the creation of additional internal stresses in the armor when the armor elements are fixed to each other using a thermosetting binder .. In addition, the described armor containing no elements , which may be structural elements of protective products, does not protect the surface adjacent to it from significant impacts of damaging bodies, but the use of armor in structures with curved surfaces, for example, fairings, requires a significant thickness of their shell.

A protective shield of an onboard antenna is known (RU, 2277737, C1), in which its flat radiolucent wall is made of highly porous fibrous material based on quartz glass fiber with a dielectric constant of 1.1-1.3, and can be impregnated to the depth of 0 from the side of the antenna, 5-1.0 mm organopolymer, for example, organosilicon resin. However, in order to achieve the necessary armor protection, the screen must have a significant thickness.

Known fairing for armor protection of radar tools (IL, 163183, A), providing selective radio transparency of the armor elements and containing mainly elements of the longitudinal layer, densely and densely packed in a homogeneous matrix forming the main protective layer. The elements of the longitudinal layer are co-located with a gap between each other and electrically isolated, so that a continuous gap is formed in the main protective layer. Elements are made of materials that absorb mechanical energy, and highly plastic materials such as ceramics, nanoparticles of cermet alloys and nanoparticles of metal alloys. The surface of the elements of the layer is electrically conductive and can be provided, for example, by coating it with a layer of highly electrically conductive materials having a width of several films. The dielectric layer can be fixed, at least one boundary surface of the main protective layer to impart ballistic properties to the fairing and alignment of the impedance. A method for adjusting the working frequency of the fairing is provided by grouping the layer elements into pairs of elements having collinear principal axes placed one above the other. In this case, disks having an electrically conductive surface can be inserted into the gaps between the pairs of layer elements.

However, due to the fact that the armor itself is not a structural material, shock loads from the effects of fragmentation and bullet bodies will have to be perceived by the structural shell of the fairing itself, which will require a significant thickness of its walls, and, consequently, will lead to a significant mass of the fairing, which, in in turn, will lead to difficulties in its operation and repair.

Known combined armor for protection against armor-piercing bullets (RU, 2478901, C1), containing a crushing-deflecting layer, consisting of individual corundum elements in the form of cylinders with convex ends, interconnected by a binder based on polymers and arranged with their longitudinal axes normal to the outer the surface of the armor, and a retaining layer made of aluminum alloy or steel. The armor is equipped with a panel located on the outer or inner surface of the retaining layer and including inner and outer sheets made of metal or nonmetal, and a layer of polyurethane foam installed between them, the thickness of which is selected to ensure a given level of shock loads and / or heat and soundproofing. In this case, the panel sheet adjacent to the surface of the retaining layer can be made in one piece with it.

However, the armor described above, containing a layer of aluminum alloy or steel, does not have radio transparency, which does not allow it to be used to protect radar, and the use of armor in structures with curved surfaces, for example fairings, requires a significant thickness of their shell.

Disclosure of invention

When creating the invention, the task was to create the material of the armor shell, simultaneously possessing radio transparency and being a structural material, for use in protective shells of large-sized objects, for example, stationary or transported radar equipment operated in difficult conditions of rapidly changing climatic influences to protect against ballistic effects of bullets and fragments.

The technical result of the development of the invention was to create a lightweight high-tech structural material, making it possible to fabricate prefabricated and monoblock shell structures and having armor-protective and radiolucent properties, resistant to external shock loads from ballistic effects of bullets and fragments, and to climatic effects, in particular, frost and ice - frost deposits, fire resistant and characterized by low smoke emission.

When creating the invention, the technical task was to create a radiolucent multilayer material in which all layers would be firmly interconnected, resistant to shock and vibration loads, climatic influences, as well as fireproof and characterized by low smoke emission, and at the same time the material would have sufficient strength and rigidity for the manufacture of structural elements from it.

The problem was solved by creating a radio-transparent armor having a multilayer structure and containing ceramic elements made in the form of cylinders with convex ends located with their longitudinal axes normal to the surface of the armor, and fastened together by a binder based on polymers, characterized in that said armor contains :

- armor shield, containing:

- the inner layer formed by ceramic elements made of ceramic radiolucent material that does not contain metal particles, in which adjacent ceramic elements are interconnected at least at one of their ends by sections of six forming the lateral surface of the cylinders, and thus form cavities for accommodating fastening damping elements formed by a cured damping binder, and

- reinforcing layers on the boundary surfaces of the specified inner layer; - a structural layer connected by its one boundary surface to the reinforcing layer of the armor shield and having a reinforcing layer fixed to its other boundary surface;

and wherein said reinforcing layers are made of plastic reinforced with organic fibers.

Moreover, according to the invention, it is advisable that the ceramic elements were made of aluminum corundum.

In addition, according to the invention, it is possible that the ceramic elements are made of boron carbide.

Moreover, according to the invention, it is advisable that the damping binder is a polyurethane-based binder.

In addition, according to the invention, it is possible that the structural layer was made of structural radiolucent fiberglass, characterized by a dielectric constant in the range from 1.9 to 4.5 and a dielectric loss tangent in the range from 0.003 to 0.02.

Moreover, according to the invention, it is advisable that these reinforcing layers were made of plastic reinforced with aramid fibers.

Moreover, according to the invention, it is advisable that the plastic reinforced with aramid fibers be a multilayer layered woven material in which layers of fabric from aramid fibers are interconnected by local sections of a polymer binder that does not fill the interfiber space.

Moreover, according to the invention, it is possible for the reinforcing layers to be made of plastic reinforced with basalt fibers.

Moreover, according to the invention, it is possible for the plastic reinforced with basalt fibers to be a multilayer layered woven material in which layers of fabric from basalt fibers are connected by a polymer binder.

Moreover, according to the invention, it is possible for the reinforcing layers to be made of plastic reinforced with glass fibers.

Moreover, according to the invention, it is advisable that the plastic reinforced with glass fibers, was a multilayer laminated woven material in which layers of fabric from glass fibers are connected by a polymer binder. Moreover, according to the invention, it is advisable that the polymeric binder of the multilayer laminated woven material was a polyimide or phenolic resin.

Moreover, according to the invention, it is advisable that the radiolucent armor additionally contains a super-hydrophobic coating on the reinforcing layer of the armor shield.

Moreover, according to the invention, it is advisable that the radiolucent armor contains a super-hydrophobic coating having an outer rough cortical shell on the surface of a hydrophobic film former applied to said reinforcing layer having high adhesive properties to the reinforcing layer material.

Moreover, according to the invention, it is advisable that the cortical shell was made of microparticles of polytetrafluoroethylene and the film former was a sealant.

Brief Description of the Drawings

The invention is further illustrated by examples of the implementation of radiolucent armor and the accompanying drawings, in which:

Figure 1 - radiolucent armor according to the invention, containing a structural layer connected to the reinforcing layer of the armor shield with its boundary rectilinear surface, a transverse section CC;

Figure 2 - the inner layer of the armor shield of the radiolucent armor according to the invention, comprising a structural layer connected to the reinforcing layer of the armor shield of its boundary convex curved surface, a cross section CC in Fig.3;

Fig.Z - radiolucent armor according to the invention: a section A - A along the inner layer of the armor shield shown in Fig.1; the same, a section BB in the inner layer of the armor shield shown in FIG. 1, at the lower ends of the cylinders of ceramic elements; and the same, the section Βι-Βι along the inner layer of the armor shield shown in FIG. 2, at the lower ends of the cylinders of ceramic elements. Moreover, the above examples and drawings do not limit the possibility of implementing the invention, are not exhaustive and do not go beyond the scope of the claims.

Best Mode for Carrying Out the Invention

The radiolucent armor according to the invention has a multilayer structure, in the embodiment shown schematically in FIGS. 1,2,3, including an armor shield 1 comprising an inner layer 2 formed by ceramic elements 3 fastened together (FIG. 1), made in the form of cylinders convex ends located along their longitudinal axes normal to the surface of the armor. On the boundary surfaces 4 and 5 of the inner layer 2 are placed reinforcing layers 6 and 7, respectively.

Moreover, according to the invention, adjacent ceramic elements 3 in the inner layer 2 are interconnected by sections of six forming the lateral surface of the cylinders (Figs. 1,2,3) at least at one of their ends and at the same time form cavities 8 for placement of fastening damping elements 9 formed by a cured damping binder having high adhesive properties to the material of ceramic elements 3 and the material of the reinforcing layers 6 and 7. polyurethane is used as this.

Due to the cylindrical shape of the ceramic elements 3, the filling density of the inner layer 2 with ceramics is 85%, which provides increased radio transparency of the inner layer 2.

According to the invention, the ceramic elements 3 are made of a ceramic radio-transparent material that does not contain metal particles, preferably aluminum corundum or boron carbide, a polyurethane-based binder is used as an adhesive damping binder.

The presence of cavities 8 allows for durable and high-quality bonding of ceramic elements 3 with damping elements 5 to each other with the formation of an inner layer 2 and with the indicated two reinforcing layers 6 and 7 with the formation of an armor shield 1. Thus, the inner layer 2 together with the reinforcing layers 6 and 7 form a radio-transparent armor shield 1 having increased impact resistance and survivability. According to the invention, under the armor shield 1 there is a radiolucent structural layer 10 (FigL), which is connected by its one boundary surface to the cover layer 7 of the armor shield 1 and has a reinforcing layer 11 on its other boundary surface.

According to the invention, the structural layer 10 is made of structural radio-transparent fiberglass, for example, characterized by a dielectric constant ε in the range of values from 1.9 to 4.5 and a tangent tan δ of the dielectric loss angle in the range of values from 0.003 to 0.02, for example, made of a multilayer heterofiber polymer composite material, for example, a material containing fiberglass for construction purposes on the basis of complex twisted yarns impregnated with an epoxy binder, for example from radiolucent fiberglass brand ST-69N (Russia). This ensures the operability of the designs made from them, for example, radomes for radar equipment, in a wide frequency band, the possibility of simultaneous operation in several spaced frequency ranges and the preservation of the stability of radio technical properties in various operating conditions.

In Fig.1,3, sections aa and bb, the relative position of the ceramic elements 3 in the inner layer 2 is shown for the case when the surface of the armor formed by the reinforcing layer 6 is straight and adjacent ceramic elements 3 are interconnected by sections six generators Behind the lateral surface of the cylinders along their entire length between the upper and lower ends. While the damping elements 9 are not communicated with each other, ceramic elements 3 work only on compression.

In Fig. 2,3, the section BpBj _t shows the relative position of the ceramic elements 3 in the inner layer 2 for the case when the surface of the armor formed by the reinforcing layer 6 is convex curved and adjacent ceramic elements 3 are interconnected by sections Zb of six forming cylinder surfaces at the lower ends of the cylinders. In this case, the damping elements 9 are interconnected. The damping elements 9 are interconnected, communicated with the side surfaces of the ceramic elements 3 and only work on compression. According to the invention, the reinforcing layers 6, 7 and 11 are made of plastic reinforced with organic fibers, for example, plastic reinforced with aramid fibers, for example, reinforced with a multilayer layered woven material, in which layers of fabric from aramid fibers are connected by local sections of a binder material, not filling the interfiber space. It is known that aramid organoplastics are characterized by a low dielectric constant ε = 3.7-4.2 in a wide frequency range from 1 kHz to 10 GHz and a tangent tan δ of the dielectric loss angle in the range of tan values δ = 0.018-0.025, which allows ballistic resistance of aramid material in organoplastics up to 97%

The reinforcing layers 6, 7 and 11 can be made of plastic reinforced with basalt fibers, for example, reinforced with a multilayer layered woven material, in which the layers of fabric from basalt fiber are connected by a polymer binder.

The reinforcing layers 6, 7 and 11 can be made of plastic reinforced with glass fibers, for example, reinforced with a multilayer layered woven material, in which the layers of fabric from glass fibers are connected by a polymer binder.

Moreover, according to the invention, a polyimide or phenolic resin characterized by fire resistance and low smoke emission can be used as a binder material for these plastics reinforced with organic fibers.

According to the invention, the radiolucent armor may contain a superhydrophobic coating 12 fixed to the outer reinforcing layer 6 of the armor shield 1. For example, a superhydrophobic coating having an outer rough cortical shell 13, for example, of microparticles of polytetrafluoroethylene, mounted on a surface applied to the reinforcing layer 6, can be used. hydrophobic film former 14, for example, a sealant having high adhesive properties to the material of the reinforcing layer 6.

The constructive solution of the radiolucent armor according to the invention provides the stability of the form and the necessary strength made with its use of various protective shells, for example, radome fairings having significant external dimensions curved, for example spherical, parabolic, cylindrical surfaces.

The stiffness of the dome is determined mainly by the thickness of the structural layer 10 and, depending on the size of the protected object, by changing the thickness of the structural layer 10, you can get the necessary rigidity and strength of protection. Reinforcement of the boundary surfaces 4 and 5 of the inner layer 2 containing ceramic elements 3 with aramid organoplastic significantly increases the survivability of the armor, especially at low temperatures.

The use of three reinforcing layers 6, 7 and 11 of plastics reinforced with organic fibers, related to lightweight materials, resistant to shock and alternating loads, poorly flammable with low smoke, having fairly stable characteristics at high humidity, technologically advanced, provides additional transparent ballistic armor protection and, together with the use of radiolucent fiberglass in the structural layer 10, provides structural rigidity of the protective shells, on Example, fairings.

The constructive solution of the radiolucent armor according to the invention allows to avoid additional processing of ceramic elements to align the outer armor-resistant surface, which in other known armor-clad shells may be due to the need to eliminate significant discrepancies between the cylinders of the ceramic elements under the outer armor surface.

So, when using for a spherical protective shell having a curvature R, radiolucent armor according to the invention with ceramic elements 3 of height h cylinders and radius r of cylinders, the divergence of the cylinders of ceramic elements 3 among themselves in the same row on the upper boundary surface 4 of the inner layer 2 of the armor shield 1 will be is determined by the formula (rh) / R, and for a shell of radius R = 1000 mm using a cylinder height of h = 30 mm (a preferred range of 8 to 30 mm) with a cylinder radius of r = 15 mm (no more) the difference is 0.45mm wit, which will not affect the strength and protective properties of the structure. In this case, the specific gravity of the actual armor shield 1 containing ceramic elements 3 having a height cylinders of 8-9 mm and a radius of cylinders of 10-12 mm, will be about 36 kg / m for ceramic elements made of aluminum corundum and about 23 kg / m ² for ceramic elements made of boron carbide.

Thus, the constructive solution of radiolucent armor in accordance with the invention allows its use in the manufacture of various durable large-sized shells, for example, fairings for various radio equipment, having mated flat surfaces and surfaces of convex and concave curvature. Hardening of the boundary surfaces of the armor shield with reinforcing layers reduces impact loads on the ceramic elements of the inner layer. Damping elements placed between ceramic elements working in compression when they are mated to at least one of their ends along six sections of the forming cylinders, and in the particular case, if there is a curvature of the structural layer, when they are mated in six point sections, provide equalization of compressive loads while ensuring structural rigidity of the inner layer.

The use of a superhydrophobic coating on the outer surface of the radiolucent armor according to the invention provides the ability to protect the shells made with its use, when operating in difficult climatic conditions of high humidity, fog, frost, the formation of hoarfrost and icy-frost deposits.

Specialists in the field of armor protection of radio equipment, for example, antennas of radar stations, it should be clear that the design of the above-described embodiment of the radio-transparent armor according to the invention can be made improvements and improvements that do not go beyond the scope of the claims, for example, regarding technology options and armor structure for attachment points for monoblock radiolucent armored structures.

Industrial applicability

The radiolucent armor according to the invention can be made using known technologies from known materials, and can find application in various fields of science and technology, in particular, to protect ground radar means from damage caused by means of destruction in the form of fragmentation and bullet-piercing armor-piercing bodies, in particular, to structural materials for radomes or protective covers of antennas of a radar station, more specifically, to the composite radiopaque armor used for this purpose.

Claims

Claim

1. Radiolucent armor having a multilayer structure and containing ceramic elements made in the form of cylinders with convex ends located along their longitudinal axes normal to the surface of the armor, and fastened together by a binder based on polymers, characterized in that said armor contains:

- armor shield (1), containing:

- the inner layer (2) formed by ceramic elements (3) made of ceramic radiolucent material that does not contain metal particles, in which adjacent ceramic elements (3) are interconnected at least at one of their ends by sections of six generators ( For) the lateral surface of the cylinders, and at the same time form cavities (8) between themselves for accommodating the fastening damping elements (9) formed by the cured damping binder, and

- reinforcing layers (6,7) on the boundary surfaces of the specified inner layer (2);

- a structural layer (10) connected by its one boundary surface to the reinforcing layer (7) of the armor shield (1) and having a reinforcing layer (11) fixed to its other boundary surface,

and wherein said reinforcing layers (6,7,11) are made of plastic reinforced with organic fibers.

2. Radiolucent armor according to claim 1, characterized in that the ceramic elements (3) are made of aluminum corundum.

3. Radiolucent armor according to claim 1, characterized in that the ceramic elements (3) are made of boron carbide.

4. Radiolucent armor according to claim 1, characterized in that the damping elements (9) are made of a binder based on polyurethane.

5. Radiolucent armor according to claim 1, characterized in that the reinforcing layers (6,7,11) as a binder material of plastic reinforced with organic fibers contain a polymeric binder based on a polyimide or phenolic resin.

6. Radiolucent armor according to claim 1, characterized in that the structural layer (10) is made of structural radiolucent fiberglass, characterized by a dielectric constant in the range from 1.9 to 4.5 and a dielectric loss tangent in the range from 0.003 to 0 , 02.

7. Radiolucent armor according to claim 1, characterized in that said reinforcing layers (6,7,11) are made of plastic reinforced with aramid fibers.

8. Radiolucent armor according to claim 7, characterized in that said reinforcing layers (6,7,11) are made of plastic reinforced with a multilayer layered woven material, in which layers of fabric from aramid fibers are connected by local sections of the polymer binder that does not fill the interfiber space.

9. Radiolucent armor according to claim 8, characterized in that the reinforcing layers (6,7,11) as a plastic binder material reinforced with aramid fibers contain a polymer binder based on a polyimide or phenolic resin.

10. Radiolucent armor according to claim 1, characterized in that said reinforcing layers (6,7,11) are made of plastic reinforced with basalt fibers.

11. Radiolucent armor according to claim 10, characterized in that said reinforcing layers (6,7,11) are made of plastic reinforced with a multilayer laminated material, in which layers of basalt fibers are connected by a polymer binder.

12. Radiolucent armor according to claim 11, characterized in that the reinforcing layers (6,7,11) as a plastic binder material reinforced with basalt fibers contain a polymer binder based on a polyimide or phenolic resin.

13. Radio-transparent armor according to claim 1, characterized in that said reinforcing layers (6,7,11) are made of plastic reinforced with glass fibers.

14. Radiolucent armor according to claim 13, characterized in that said reinforcing layers (6,7,11) are made of plastic reinforced with a multilayer laminated material, in which layers of glass fiber fabric are connected by a polymer binder.

15. Radiolucent armor according to claim 14, characterized in that the reinforcing layers (6,7,11) as a plastic binder material reinforced with glass fibers contain a polymer binder based on a polyimide or phenolic resin.

16. Radiolucent armor according to claim 1, characterized in that it further comprises a superhydrophobic coating (12), mounted on an external reinforcing layer (6) of the armor shield (1).

17. Radiolucent armor according to clause 16, characterized in that it contains a superhydrophobic coating (12) having an outer rough cortical shell (13) on the surface of a hydrophobic film former (14) applied to the reinforcing layer (6), which has high adhesive properties to the reinforcing material layer (6).

18. Radiolucent armor according to claim 8, characterized in that in the superhydrophobic coating (12), the cortical shell is made of microparticles of polytetrafluoroethylene, and the film former (14) is a sealant.