RU224202U1 - Combined heat-resistant radio-absorbing coating - Google Patents

Abstract

The utility model relates to the field of camouflage of ground military objects, in particular to the creation of camouflage coatings with adaptively controlled physical parameters of spectral characteristics and structural and functional indicators. The combined heat-resistant radio-absorbing coating contains a flexible base and a filling material fixed on its surface, made in the form of interconnected layers of coating with different resistivities, which is made of n-separate modules. The individual coating modules are connected to each other along the perimeter with clamps made of heat-resistant cord of the ShKM brand with a diameter of 4.0 mm. The coating on the surface of a ground military facility is secured using a network with a mesh of 400.0×400.0 mm, made of heat-resistant cord of the ShKM brand with a diameter of 4.0 mm, laid on the surface of its second outer layer of filling material. The outer layer is made in the form of an artificial grass lawn made of LDPE 11503-070 polypropylene, modified with TUBALL brand carbon nanotubes. The network on the inside of the coating is secured with clamps made of heat-resistant cord of the ShKM brand with a diameter of 4 mm to brackets welded to the surface of the protected object. The utility model allows you to reliably hold a combined radio-absorbing heat-resistant coating on the surface of a ground-based military facility. 3 salary f-ly, 4 ill.

Description

The utility model relates to the field of camouflage of ground military objects, in particular to the creation of camouflage coverings with adaptively controlled physical parameters of spectral characteristics and structural and functional indicators to ensure concealment and protection of mobile or stationary ground military objects located on the ground from technical reconnaissance equipment (TCP) and guidance systems for high-precision weapons (HPE) simultaneously in the visible, infrared (IR) and radar (RL) ranges of the spectrum of electromagnetic wavelengths (EMW) in conditions of the use of incendiary weapons by a potential enemy.

The continuous development of technical means of camouflage (TCM) is determined primarily by their importance for the timely concealment of ground military objects, especially mobile military equipment, from the TCP complex and the guidance of military equipment. [Efimov V.A., Kolchevsky V.E. Chermashentsev S.G. Disguise. Part I. Fundamentals and techniques of camouflage. Textbook. - M.: VIA, 1971. - P. 221-254, 273, 274.].

In addition, modern trends in the development of armed warfare impose additional requirements for the protection of ground military facilities from primary and secondary factors of the destructive thermal effect of incendiary weapons of a potential enemy on ground military facilities. [Ardashev A.N. Flamethrower-incendiary weapon. - M.: Astrel, ACT, 2001. - 288 p. Characteristics of incendiary weapons. Incendiary substances, their composition and combat properties. Methods and means of using incendiary weapons // Voenservis.rf [Electronic resource]. URL: http://voenservice.ru/boevayapodgotovka (access date: 10/01/2023)].

The effectiveness of detection and recognition of camouflaged ground military objects based on the results of ground, air and space reconnaissance depends on the tactical and technical capabilities of TCP and on the tactical and technical capabilities of the applied technical means of hiding ground military objects, capable of reducing the values of reflected electromagnetic energy radiation from ground military objects in the visible, IR and RL ranges of the spectrum of computer lengths towards the radiation receiver. [Efimov V.A., Kolchevsky V.E. Chermashentsev S.G. Disguise. Part I. Fundamentals and techniques of camouflage. Textbook. - M.: VIA, 1971. - P. 43-147.].

The effectiveness of protecting ground military facilities from incendiary weapons depends on the thermophysical properties of materials used in protective coatings and structures based on them, which reduce the vulnerability of ground military facilities from primary and secondary factors of destructive thermal effects.

The claimed utility model is designed to simultaneously solve these two scientific and technical problems in order to preserve the survivability of ground-based military installations while they are performing combat missions.

The required camouflage effect of hidden ground military objects in conditions of complex reconnaissance using modern optical-electronic and radar equipment can be achieved by simultaneously reducing the brightness and thermal contrasts between the surface of the object and the surrounding background of the area, as well as reducing their effective scattering area (ESR, m ² ).

Incendiary weapons have damaging factors that act in time and space and are divided into primary and secondary factors. Primary damaging factors (thermal energy, smoke and toxic combustion products) manifest themselves on the target from several seconds to several minutes during the use of incendiary weapons. Secondary damaging factors, as a consequence of emerging fires, manifest themselves from several minutes and hours to days and weeks.

The protective effect of troops from incendiary weapons is assessed based on the results of measures to prevent or minimize its impact on troops, as well as preventing the occurrence and spread of massive fires and ensuring, if necessary, their localization and extinguishing through the use of trenches and shelters equipped with ceilings, natural shelters, tarpaulins, awnings and covers, coverings made from local materials, service and local fire extinguishing agents [Grabovoy I.D., Kadyuk V.K. Instructions for protection against incendiary weapons. - M.: Military Publishing House, 1987].

It becomes obvious that the possibility and consequences of the enemy’s sudden use of incendiary weapons should be taken into account as a factor determining the preservation of the survivability of a ground-based military facility during its performance of combat missions.

A solution to the emerging contradictions in the practice of protection in the conditions of the predicted combat use of ground-based military facilities in the conditions of the enemy’s use of incendiary weapons can be the development and use of coatings that would have both camouflage and thermal protective properties, ensuring, without interfering with crews, control and combat use weapons in the conditions of performing assigned tasks, while simultaneously shielding the electromagnetic radiation reflected from a camouflaged ground military object towards the line of sight “reconnaissance means - object” and reducing their vulnerability from the destructive thermal effects of incendiary weapons.

Analogs of the claimed utility model are known technical solutions, which include: standard camouflage coatings and camouflage coatings installed on the surface of equipment from local materials [Manual on military camouflage. Part II. Camouflage techniques and camouflage of military installations. - M.: Military Publishing House of the USSR Ministry of Defense, 1956. - P. 68...71.], fan masks [Efimov V.A., Kolchevsky V.E. Chermashentsev S.G. Disguise. Part I. Fundamentals and techniques of camouflage. Textbook. - M.: VIA, 1971. - P. 252, 253, 254.], deforming masks [Kiselev K.F., Yasin E.Z. Military camouflage. Part II. Camouflage technique. - M.: VIA, 1957. - P. 129-133; patent for utility model No. 175328 according to application No. 2016142474 dated October 28, 2016].

The main disadvantage of these technical solutions is, first of all, that these means do not provide concealment of military facilities and military equipment in the radar range of the electromagnetic wave spectrum. In addition, these technical solutions do not solve the problem of reducing the vulnerability of ground military facilities from the factors of incendiary weapons used by the enemy in combat conditions.

There is a known method of masking moving objects with cut vegetation [Method of masking moving objects with cut, including preserved, and/or artificial vegetation. Description of the invention to Patent RU No. 2284002 of 2006 No. 2004123944/02 of 08/06/2004 Bull. No. 26 of September 20, 2006], including preserved and/or artificial vegetation attached to a moving object, also chosen as an analogue of the claimed utility model.

The disadvantage of the known method is that this technical solution is aimed at providing a camouflage effect mainly in the visible range of the spectrum of electromagnetic wavelengths, which follows from expressions that provide calculation of the density of foliage in the mask in the presence of transparency created by cut or artificial branches, and does not have masking properties in the IR and X-ray ranges of the electromagnetic wave spectrum. In addition, this method also does not solve the problem of reducing the vulnerability of ground military facilities from the factors of incendiary weapons used by the enemy in combat conditions.

A device is known for masking moving objects, containing a frame fixed to them with artificial vegetation in the form of leaves made of film that imitates the vegetation of the underlying background. [Device for masking moving objects. Description of the invention to the author's certificate No. 828804 dated October 27, 1999. Bull. No. 30 according to application No. 2868853/23 dated January 14, 1980]. However, this technical solution is aimed only at providing a masking effect for moving objects mainly in the visible range of the electromagnetic wavelength spectrum and is not intended for its use as a TCM that provides a masking effect in the IR and RL ranges of the electromagnetic wavelength spectrum. In addition, this technical solution does not reduce the vulnerability of ground military facilities from incendiary weapons.

A known technical solution is “A method for camouflaging moving objects with artificial vegetation, arranging artificial branches and a device for attaching branches to a moving object to implement the method” [Patent RU No. 2495357 dated 10.10.2013 from IPC class: F41H 3/00].

The essence of the solution is to use artificial material for the mask in the form of branches of deciduous or coniferous trees, containing radio-absorbing, or radio-scattering, or radio-reflective additives in the form of thin layers of metallized or graphite coating, woven or stapled fibers with different cutting lengths.

The disadvantage of this technical solution is, first of all, the significant labor intensity in bringing the structure into a working transport position on a moving object, the creation of certain difficulties and interference for crews, which reduce the effectiveness of control and combat use of weapons in the conditions of performing assigned tasks. In addition, this technical solution is unable to protect ground military facilities from incendiary weapons.

The general significant disadvantages of the above technical solutions using freshly cut vegetation as a filling material for masking coatings is that cut vegetation changes its spectral reflection characteristics in the ultraviolet (UV) range of the spectrum of electromagnetic wavelengths and differs from the reflection spectrum of living vegetation in the spectrozonal wavelength range . This circumstance leads to an increase in the contrasts of camouflaged equipment using cut vegetation in relation to the surrounding background of the area and increases the likelihood of its detection and recognition by optical-electronic technical reconnaissance equipment (TCP). In addition, none of the technical solutions considered is capable of protecting ground-based military installations.

Also known, chosen as analogues, are camouflage coatings that are used to hide ground objects from optical and radar reconnaissance systems [German Patents No. 300947 for 1986, No. 289186 for 1976 in the IPC class: F41H 3/00]. In these coatings, elements that have an internal electrically conductive layer in the form of metal, carbon fillers, etc. are attached to the network base.

A camouflage coating is also known, having a base in the form of a network made of dielectric threads with individual elements of electrically conductive material woven into it with a protective color [Patent RU No. 2171442, 2001 according to IPC class: F41H 3/00].

The disadvantages of these camouflage coatings are that they, first of all, do not provide a reduction to the required level of the power of the reflected signal in the spectral range of wavelengths of 0.2...30 cm, as well as the probability of detecting high-contrast TCP objects in the visible and IR ranges of the spectrum of wavelengths EMV. In addition, none of the camouflage coatings considered is capable of protecting ground military targets from the factors of incendiary weapons.

It is also known “Broadband radio-absorbing camouflage coating and method of its manufacture” Patent RU No. 2280229 dated June 24, 2004 according to IPC class: F41H 3/00], also chosen as an analogue.

This invention relates to the field of camouflage, in particular to radio-absorbing camouflage coatings. A broadband radio-absorbing camouflage coating consists of two enamel-coated modules connected around the perimeter, made of a network base of dielectric threads with filling material woven into it. The filling material is made of complex threads of various resistances, including glass threads entwined with a microwire made of iron with the addition of cobalt with a diameter of 3 microns for one module and 5 microns for another module, while the resulting composition is secured by entwining glass thread with a minimum pitch. The filling material of one module is made with a resistance of 300 kOhm/m, and the other - 60 kOhm/m. When using the invention, the probability of detecting high-contrast objects by means of optical and radar reconnaissance is reduced.

At the same time, despite the positive results achieved in ensuring a camouflage effect in the visible and radar ranges of the electromagnetic wave spectrum, as a result of the use of this technical solution of a broadband radio-absorbing camouflage coating, it is characterized by a number of disadvantages that limit in practice the scope of its application as a means of hiding mobile VVST, which primarily include:

- absence of a camouflage effect to reduce the thermal contrast of heated areas of the surface of a camouflaged VHF using this camouflage coating;

- lack of structural and functional capability of the process of adaptive control of the physical parameters of the spectral characteristics of the camouflage coating during its operation as a technical means of hiding a camouflaged object simultaneously in the visible, IR and RL ranges of the spectrum of electromagnetic wave lengths relative to the physical and climatic conditions of the environment and the underlying background of the area , (for example, changes in temperature, relative humidity, spectral brightness coefficients of the underlying background of the area);

- creating interference for crews when placing this camouflage coating on the surface of a moving object, reducing the effectiveness of control and combat use of weapons in the conditions of performing assigned tasks.

Also known, chosen as an analogue, is a fire-resistant radio-absorbing composition [Patent RU 2650931], used for application to the textile base of military uniforms and civilian clothing, for the purpose of protection against damage by incendiary weapons, application to metal surfaces to reduce radar signature. The disadvantage of this technical solution is that the task of creating radio-absorbing properties of a protected product treated with the declared composition is solved with experimental confirmation of the properties only in the range from 900 to 1000 MHz of the electromagnetic wave spectrum, which is not included in the frequency range of the TCP operation of a potential enemy. The effectiveness of the radio absorption properties of the composition in the electromagnetic wave length range “up to 12 GHz” is stated in the formulation “not excluding the presence” without confirmation. Confirmation of effectiveness for the task of fire resistance does not have supporting information due to the lack, first of all, of evidence of the intumescent properties of the composition, the qualitative characteristics of the resulting coke, in particular the magnitude of the adhesive properties and the time of maintaining the integrity of the composition foaming under the influence of a thermal field on textiles and on metal surfaces.

Technical solutions are also known, described in the inventions “Thermal and weather-resistant paint-coating” [RF Patent No. 2382803 dated 08/14/2008], “Heat-moisture-proof paint-coating” [RF Patent 2310670 dated 07/31/2006]. Both of these coatings solve problems with high efficiency only in terms of fire resistance and thermal protection of structures made of various materials, expanding the operating temperature range and increasing the service life of coatings. The disadvantages of these coatings are that they do not reduce the power of the reflected signal from the ground military equipment they protect in the spectral range of EMW lengths, 0.2...30 cm, as well as the probability of TCP detection of high-contrast ground military objects in the visible and IR spectral ranges EMW lengths.

The technical solution described in the invention “Heat-protective fire-resistant kit” is also known [RF Patent 2537819 dated December 6, 2013]. This kit solves the problem with high efficiency of only maintaining the thermal resistance of high-energy materials under the destructive effects of the thermal field of cellulose and hydrocarbon fires. However, the disadvantage of this kit is that it is radio transparent and does not reduce the power of the reflected signal from the ground military equipment it protects in the EMW length spectrum range of 0.2...30 cm.

“Camouflage coating” Patent RU No. 206354 dated December 28, 2020 for IPC class: F41H 3/00] is also known, chosen as a prototype.

This utility model relates to the field of camouflage, in particular to the creation of camouflage coatings with adaptively controlled physical parameters of spectral characteristics to ensure the concealment of mobile or stationary military objects located on the ground from technical reconnaissance equipment (TCP) simultaneously in visible, infrared (IR) and radar (RL) ranges of the spectrum of electromagnetic wavelengths (EMW).

The known camouflage coating is made of n-separate coating modules, interconnected along the perimeter by removable-detachable flat polymer flexible tapes, structurally forming hollow cells into which coating modules are built, fixed in each individual cell by internal double-sided integrally cast grooves on the sides of each cell and clamps-limiters screwed to the bottom row of flat polymer flexible tapes. In this case, the flexible base of the coating module is made in the form of continuous glass fabric, which is a dielectric, on the surface of which is glued the first lower continuous layer of filling material, made of water-absorbing silicon foam organic polymer with a thickness of 5 mm to 10 mm with the possibility of water absorption by volume from 25% to 45 %, impregnated with electrically conductive nanodispersed graphite to achieve a surface resistivity from 50 Ohm to 100 Ohm, to the front upper part of which is sewn a second layer of filling material, made in the form of an artificial grass lawn made of polypropylene with a density of 15-20 stitches per dm ² of coating and pile height from 5 mm to 25 mm with colloidal nanodispersed graphite sprayed onto its surface, providing a surface resistivity of the second top layer of coating from 300 Ohm to 600 Ohm and having a camouflage color. At the same time, to attach the camouflage coating to the surface of a military object, bolted connections with union nuts are screwed to the base of the flexible tapes, and threaded rods (studs) are welded to the surface of the military object.

At the same time, despite the positive results achieved in providing a camouflage effect in the visible, IR and RL ranges of the spectrum of electromagnetic wavelengths, the known camouflage coating chosen as a prototype, according to its technical solution, has reduced performance characteristics due to the complexity of the structural articulation of the coating modules, fixed on the surface of a ground-based military object in the operating position in solidly cast grooves of flat polymer flexible tapes, which during its operation under conditions of high and low ambient air temperatures leads to an increase in the recovery time (replacement) of damaged structural elements. It is this factor that ultimately has a negative impact on ensuring the timely concealment of a ground-based military facility after the camouflage coating is restored to a working condition, in conditions of continuous reconnaissance.

In addition, as mentioned above, in the context of constant improvement of means of armed warfare, modern trends in the development of weapons of destruction impose additional requirements for the protection of ground-based military facilities from primary and secondary factors of the destructive thermal effect of incendiary weapons of a potential enemy on ground-based military facilities [Ardashev A.N. Flamethrower incendiary weapon. - M.: Astrel, ACT, 2001. - 288 p. Characteristics of incendiary weapons. Incendiary substances, their composition and combat properties. Methods and means of using incendiary weapons // Voenservis.rf [Electronic resource]. URL: ttp:/voenservice.ru/boevayapodgotovka (date of access: 01.102023)].

Under these conditions, the effectiveness of protecting ground military facilities from incendiary weapons will depend on the thermophysical properties of the materials used in the structures used in protective coatings and structures based on them, which reduce the vulnerability of ground military facilities from primary and secondary factors of destructive thermal effects. The well-known utility model “Camouflage Covering” chosen as a prototype does not have this kind of physical properties and mechanism for counteracting incendiary weapons and therefore does not protect a camouflaged ground military object from fire.

At the same time, despite the positive results achieved in providing a camouflage effect in the visible, infrared and radar ranges of the electromagnetic wave spectrum, the coating is not capable of protecting ground military facilities from the factors of incendiary weapons.

Thus, the well-known devices discussed above in their design do not meet modern requirements for camouflaging ground objects and at the same time protecting them from the thermal effects of incendiary weapons used by a potential enemy.

Therefore, one of the current trends in the field of camouflage and increasing the thermal resistance of ground-based military facilities from the effects of incendiary weapons is the development of technical solutions for coatings that provide:

firstly, attenuation (screening) of electromagnetic radiation reflected from a camouflaged object towards the line of sight “reconnaissance vehicle - object” with adaptively controlled physical parameters of the spectral characteristics of the camouflage coating and its structural and functional indicators;

secondly, the protection of ground military facilities from the factors of incendiary weapons without interfering with crews, reducing the effectiveness of control and combat use of weapons when performing assigned tasks.

The solution to such a complex scientific and technical problem is especially relevant in the field of creating camouflage coatings that ensure the reliability of holding a combined radio-absorbing heat-resistant coating on the surface of a ground-based military facility during its operation in conditions of high and low ambient air temperatures while maintaining the thermal resistance of ground-based military facilities from the effects of incendiary factors weapons and their timely detection from modern TCP and VTO guidance systems in the visible, IR and RL ranges of the electromagnetic wave spectrum.

The problem solved in the claimed utility model is to simplify the design solution of a combined heat-resistant radio-absorbing coating, increase its camouflage properties simultaneously in the visible, infrared and radar ranges of the spectrum of electromagnetic waves from ground, air, space reconnaissance and high-tech guidance systems, as well as the same protection of a camouflaged ground military object from the use of incendiary weapons by a potential enemy during its operation, due to adaptively controlled changes in the physical parameters of the spectral characteristics of the coating and its structural and functional indicators, ensuring a decrease in the level of electromagnetic radiation reflected from the coating away from the line of sight of the “means” reconnaissance - object" with simultaneous shielding of electromagnetic radiation and heat flow reflected from a camouflaged ground military object and maintaining thermal resistance from the effects of incendiary weapons without interfering with the crews.

The technical result of the utility model is the reliability of holding a combined radio-absorbing heat-resistant coating on the surface of a ground-based military facility.

At the same time, the reliability of holding the combined radio-absorbing heat-resistant coating on the surface of a ground-based military facility is ensured by the direct strength of the material of the flexible base of the coating, made of dielectric perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm, heat-resistant fabric of the E1-125P brand (95 ), the strength of a network with a mesh of 400.0 × 400.0 mm and clamps made of heat-resistant cord brand ShKM TU 23.99.19-015-87401176-2019 with a diameter of 4.0 mm, as well as the density of connection of the coating with the surface of a ground military facility with with a pitch of 400 mm and the strength of the selected type of nodal connections.

This task is achieved by the fact that in a combined heat-resistant radio-absorbing coating containing a flexible base and a filling material fixed to its surface, made in the form of interconnected layers of coating with different resistivity, which is made of n-separate modules interconnected along the perimeter, in this case, the flexible base of the coating module is made in the form of fiberglass, which is a dielectric, on the surface of which, on the front upper side, a continuous layer of filling material is glued, made of water-absorbing silicon foam organic polymer with a thickness of 5 mm to 10 mm with the possibility of water absorption in volume from 25 % to 45%, modified with electrically conductive nanodispersed material achieving a surface resistivity from 50 Ohm to 100 Ohm, to the front upper part of which a second layer of filling material is sewn, made in the form of an artificial grass lawn made of polypropylene with a density of 15-20 stitches per dm ² of coating and a pile height from 5 mm to 25 mm, providing a surface resistivity of the second top layer of coating from 300 Ohm to 600 Ohm and having a camouflage color, with the possibility of attaching a camouflage coating to the surface of a ground-based military facility:

firstly, individual coating modules are connected to each other along the perimeter with clamps made of heat-resistant cord brand ShKM TU 23.99.19-015-87401176-2019 with a diameter of 4.0 mm, and the coating itself on the surface of a ground military facility is secured using a network with a mesh of 400, 0 × 400.0 mm, made of heat-resistant cord brand ShKM TU 23.99.19-015-87401176-2019 with a diameter of 4.0 mm, laid on the surface of its second outer layer of filling material, made in the form of an artificial grass lawn made of polypropylene LDPE 11503- 070 GOST 16337-77, modified with carbon nanotubes brand TUBALL TU 20.13.21-001-91735575-2021, while the network on the inside of the coating is secured with clamps made of heat-resistant cord brand ShKM TU 23.99.19-015-87401176-2019 with a diameter of 4 mm to brackets welded to the surface of the protected object;

secondly, the flexible base of the coating is made of dielectric perforated with a density of 1.0 / cm ² and a hole diameter of 3.0 mm, heat-resistant fabric of grade E1-125P (95) GOST 19907-83, with an operating temperature from -200 ° C to + 550°C, on the surface of the lower side of which, facing the object, is applied a layer of heat-resistant Thermo-S coating with a thickness of 3.0 mm, perforated with a density of 1.0 / cm ² and a hole diameter of 3.0 mm, with a thermal conductivity coefficient of the material of 0.046 W/Km up to 0.027 W/Km and thermal resistance from -195°C to +1200°C;

thirdly, in the combined heat-resistant radio-absorbing coating, from 1.0 to 2.7 wt.% of carbon nanotubes of the TUBALL brand TU 20.13.21-001-91735575- are introduced in the combined heat-resistant radio-absorbing coating as an electrically conductive nanodispersed material, uniformly distributed throughout the entire volume of the water-absorbing silicon foam organic polymer. 2021 from the total mass of the polymer, providing a surface resistivity of the first coating layer from 50 Ohms to 100 Ohms;

fourthly, in a combined heat-resistant radio-absorbing coating as an electrically conductive nanodispersed material, uniformly distributed throughout the entire volume of polypropylene LDPE 11503-070 GOST 16337-77, made in the form of an artificial grass lawn, from 2.5 to 6.4 wt.% carbon nanotubes TUBALL TU 20.13.21-001-91735575-2021 from the total mass of polypropylene, providing a surface resistivity of the second top layer of coating from 300 Ohm to 600 Ohm and having a camouflage color.

Thus, the listed coating elements are connected to each other using assembly operations to form a structural unity that ensures the implementation of the claimed utility model.

The technical essence of the claimed utility model is presented in Fig. 1, 2, 3, 4.

Figure 1 shows an image of a combined radio-absorbing heat-resistant coating with the placement of the main structural parts in the working position, where: 1 - a network with a mesh of 400.0 × 400.0 mm, made of heat-resistant cord of the ShKM brand with a diameter of 4.0 mm; 2 - coating module with filling material; 3 - a clamp made of heat-resistant cord of the ShKM brand with a diameter of 4.0 mm.

Figure 2 shows a coating module with a flexible base and filling material, where:

a) appearance of the coating module, where 4 is a flexible coating base made of dielectric perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm, heat-resistant fabric brand E1-125P (95), 5 - a layer of heat-resistant coating Thermo-C 3.0 mm thick, perforated with a density of 1.0 / cm ² and a hole diameter of 3.0 mm; 6 - the first layer of coating of water-absorbing silicon foam organic polymer modified with carbon nanotubes of the TUBALL brand; 7 - the second outer layer of filling material, made in the form of an artificial grass lawn made of polypropylene LDPE 11503-070, modified with carbon nanotubes of the TUBALL brand; 8 - mounting holes;

b) appearance of the coating module from the side of a layer of heat-resistant Thermo-S coating 3.0 mm thick, perforated with a density of 1.0 / cm ² and a hole diameter of 3.0 mm.

Figure 3 shows a projection along section AA (see Figure 1) of a fragment of a coating mounted on the surface of a ground-based military facility,

where 1 is a network with a mesh of 400.0 × 400.0 mm, made of heat-resistant cord of the ShKM brand with a diameter of 4.0 mm; 2 - coating module with filling material; 3 - a clamp made of heat-resistant cord of the ShKM brand with a diameter of 4.0 mm; 4 - flexible coating base made of dielectric perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm, heat-resistant fabric of the E1-125P (95) brand, 5 - a layer of heat-resistant Thermo-S coating with a thickness of 3.0 mm perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm; 6 - the first layer of coating of water-absorbing silicon foam organic polymer modified with carbon nanotubes of the TUBALL brand; 7 - the second outer layer of filling material, made in the form of an artificial grass lawn made of polypropylene LDPE 11503-070, modified with carbon nanotubes of the TUBALL brand; 8 - mounting holes; 9 - bracket; 10 - surface of a ground military facility.

Figure 4 shows options for a combined heat-resistant radio-absorbing coating installed on military vehicles, where:

a) a combined heat-resistant radio-absorbing coating, made in the form of a grass lawn with protective coloring to match the color of the surrounding underlying terrain;

b) a combined heat-resistant radio-absorbing coating, made in the form of a grass lawn with deforming coloring to match the color of the surrounding underlying background of the area, which is not uniform in color.

The installation of the proposed combined heat-resistant radio-absorbing coating on the surface of a ground-based military facility, for example, on military vehicles, is in practice provided for in factory stationary conditions and is carried out sequentially in 2 stages as follows.

At stage 1, next to a ground military facility, a combined radio-absorbing heat-resistant coating is assembled. To ensure the functional and structural unity of the coating, modules 2 with a flexible base and filling material are structurally linked, connecting to each other by assembly operations using clamps 3 made of heat-resistant cord brand ShKM 23.99.19-015-87401176-2019 with a diameter of 4.0 mm and structurally made in each module of mounting holes 8 (see Figs 1, 2, 3).

In this case, the coating modules 2 with a flexible base and filling material are sequentially placed close to each other coaxially with the mounting holes 8 upwards with a second outer layer 7 of filling material made in the form of an artificial grass lawn made of polypropylene LDPE 11503-070 GOST 16337-77, modified with carbon nanotubes of the TUBALL TU 20.13.21-001-91735575-2021 and connect (tied) together along the perimeter until a flat projection of the combined radio-absorbing heat-resistant coating is completely formed, in relation to a specific sample of a ground military facility, with clamps 3 made of heat-resistant cord brand ShKM TU 23.99.19- 015-87401176-2019 with a diameter of 4.0 mm, connecting the free ends of each clamp with a straight knot.

After this, next to the ground military facility and the assembled combined radio-absorbing heat-resistant coating, network 1 is laid out with a mesh of 400.0 × 400.0 mm, made of heat-resistant cord brand ShKM 23.99.19-015-87401176-2019 with a diameter of 4.0 mm.

At stage 2, a combined radio-absorbing heat-resistant coating is installed on a ground military facility.

In this case, the installation is performed in the following sequence: on the surface of a ground military facility 10 with welded brackets 9, a combined radio-absorbing heat-resistant coating assembled on the ground is placed so that the points of intersection of the symmetry axes of the coating modules 2 with a flexible base and filling material with the junction line of adjacent ones along the perimeter modules 2 with a flexible base and filling material were located on normals to brackets 9, welded to the surface 10 of a ground-based military facility (see Fig. 3).

Next, a network with a mesh of 400.0 × 400.0 mm, made of heat-resistant cord brand ShKM TU 23.99.19-015-87401176-2019 with a diameter of 4.0 mm, is laid on the surface of the second outer layer of filling material 7, made in the form of artificial grass lawn made of polypropylene LDPE 11503-070, modified with carbon nanotubes of the TUBALL brand TU 20.13.21-001-91735575-2021 so that the network nodes are aligned with the normals to the brackets 9.

Then the coating on the surface of the ground military object is secured using a network with a mesh of 400.0 × 400.0 mm, made of heat-resistant cord brand ShKM TU 23.99.19-015-87401176-2019 with a diameter of 4.0 mm, laid on the surface of its second outer layer of filling material made in the form of an artificial grass lawn made of polypropylene LDPE 11503-070 GOST 16337-77, modified with carbon nanotubes brand TUBALL TU 20.13.21-001-91735575-2021 on the inside of the covering with clamps made of heat-resistant cord brand ShKM TU 23.99.19 -015-87401176-2019 with a diameter of 4 mm to brackets welded to the surface of the protected object.

At the same time, the reliability of holding the combined radio-absorbing heat-resistant coating on the surface of a ground-based military facility is ensured by the direct strength of the material of the flexible base of the coating, made of dielectric perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm, heat-resistant fabric of the E1-125P brand (95 ), the strength of a network with a mesh of 400.0 × 400.0 mm and clamps made of heat-resistant cord brand ShKM TU 23.99.19-015-87401176-2019 with a diameter of 4.0 mm, as well as the density of connection of the coating with the surface of a ground military facility with with a pitch of 400 mm and the strength of the selected type of nodal connections.

The implementation of a useful model of a camouflage coating installed on the surface of a mobile or stationary military object located on the ground is carried out in practice as follows.

Detection of a camouflaged military object on the ground by technical reconnaissance means (TCP) is carried out by the intensity of the signal reflected from the military object in the direction of the reconnaissance vehicle-object line of sight, characterized by the contrast values between the camouflaged military object and the surrounding background of the area simultaneously in the visible, IR and radar ranges spectrum of electromagnetic wave lengths.

With the beginning of the process of TCP detection of the location of a camouflaged single ground military object on the ground in the TCP reconnaissance coverage area, the object is irradiated with a combined heat-resistant radio-absorbing coating installed on its outer surface, which ensures a reduction in contrasts in the type of DP and signs of activity during the operation of the ground military object to required values of the probabilities of its non-detection on the ground.

Functionally, when conducting reconnaissance, the signal reflected towards the irradiation source in the direction of the line of sight “reconnaissance vehicle-object” is reduced due to the physical and technical properties of the materials filling the coating modules, thereby ensuring a timely reduction in the effective dispersion area of the camouflaged ground military object located behind the coating to the specific effective dispersion area of the surrounding area with a simultaneous reduction in the contrasts of the camouflaged military object relative to the surrounding background of the area in the visible and IR ranges of the electromagnetic wave spectrum.

In conditions where a potential enemy uses incendiary weapons, a combined heat-resistant radio-absorbing coating provides protection for a ground-based military facility due to the flexible coating base included in the module, made of dielectric perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm, heat-resistant fabric of grade E1 -125P (95), with a layer of heat-resistant Thermo-S coating applied to it, 3.0 mm thick, perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm.

At the same time, the claimed technical result in the utility model “Combined heat-resistant radio-absorbing coating” is achieved as follows.

Firstly, a sharp reduction in the thermal contrast between the surface of a ground-based military object and the surrounding background in the IR range of the electromagnetic wave spectrum and at the same time protecting the ground-based military object from the thermal effects of incendiary weapons used by the enemy is in practice carried out due to the flexible base of the coating 4, made of dielectric perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm, heat-resistant fabric of the E1-125P (95) brand, with an operating temperature from -200 ° C to + 550 ° C, on the surface of the lower side of which, facing the object, a layer of heat-resistant coating Thermo-S with a thickness of 3.0 mm, perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm was applied, having a thermal conductivity coefficient of the material from 0.046 W/Km to 0.027 W/Km and thermal resistance from -195 °C to +1200°C.

Secondly, the possibility of adaptively changing the relative humidity of a combined heat-resistant radio-absorbing coating to the conditions of changes in the relative humidity of the surrounding air environment and the background terrain adjacent to the object during the operation of the coating at a ground military facility is carried out in practice:

a) According to the first option, due to the natural moistening of the first layer of coating 6 of water-absorbing silicon foam organic polymer modified with carbon nanotubes of the TUBALL brand TU 20.13.21-001-91735575-2021. At the same time, the extreme values of the thickness of the layer of water-absorbing foamed silicon organic polymer (6) from 5 mm to 10 mm and the minimum and maximum values of water absorption by volume from 25% to 45%, established in the coating modules 2 (see Fig. 1-3), characterize the structural and functional possibility of achieving a technical result with a useful model of a combined radio-absorbing heat-resistant coating to control its relative humidity, promoting an adaptive approximation of the physical parameters of the spectral characteristics of the camouflage coating to the spectral characteristics of the surrounding background of the area with natural humidity adjacent to the military facility. Moreover, water absorption values by volume of less than 25% have practically no effect on the change in the values of the spectral characteristics of the combined heat-resistant radio-absorbing coating from non-wetted coating modules (2) in the IR and RL ranges of the spectrum of EMW lengths, and water absorption values by volume are more than 45% by volume. in relation to unwetted coating modules (2) lead to an increase in the signal reflected from the coating in the RL range of the spectrum of EMW lengths, which increases the probability of its detection by TCP. At the same time, the second outer layer of filling material, made in the form of an artificial grass lawn made of polypropylene LDPE 11503-070 GOST 16337-77, modified with carbon nanotubes of the TUBALL brand TU 20.13.21-001-91735575-2021, sewn to a flexible coating base 4 s density of 15-20 stitches per dm ² and pile height from 5 mm to 25 mm 7 (see Fig. 2, 3), due to the condensation of natural humidity from the surrounding air onto the hydrophobic pile of the grass lawn and subsequent drainage from the pile and accumulation of condensate the first layer of coating of water-absorbing foamed silicon organic polymer, modified with carbon nanotubes brand TUBALL TU 20.13.21-001-91735575-2021 with a thickness of 5 mm to 10 mm with the possibility of water absorption by volume from 25% to 45%, with its retention in a layer of water-absorbing foam silicon organic polymer 6 (see Figs 2, 3), from premature evaporation of moisture accumulated in the layer of flexible base coating 4, a coating made of dielectric perforated with a density of 1.0 / cm ² and a hole diameter of 3.0 mm heat-resistant fabric of grade E1 -125P (95) GOST 19907-83, with operating temperatures from -200°C to +550°C, on the surface of the lower side of which, facing the object, a layer of heat-resistant Thermo-S coating, 3.0 mm thick, perforated, with a density 1.0 /cm ² and a hole diameter of 3.0 mm TU 2316-001-83143553-2010 (4 see Figs 2, 3) from the heated surface of a military facility 10 (see. Fig.3).

Surface resistivity of the first layer of coating of water-absorbing silicon foam organic polymer modified with carbon nanotubes brand TUBALL TU 20.13.21-001-91735575-2021 6 coating modules 2 (see Fig. 1, 2, 3) and the second outer layer of filling material made in the form of an artificial grass lawn made of polypropylene LDPE 11503-070 GOST 16337-77, modified with carbon nanotubes of the TUBALL brand TU 20.13.21-001-91735575-2021 7 coating modules 2 (see Fig. 1, 2, 3) were measured according to GOST R 53734.2.3-2021 "Methods for determining the electrical resistance of solid flat materials used to prevent the accumulation of electrical charge."

With the established ingredients thickness from 5 mm to 10 mm of the first layer of coating of water-absorbing silicon foam organic polymer, modified with carbon nanotubes of the TUBALL brand TU 20.13.21-001-91735575-2021 6 with the possibility of water absorption by volume from 25% to 45%, its surface is achieved resistivity from 50 Ohm to 100 Ohm, and with the installed ingredients of the second outer layer of filling material, made in the form of an artificial grass lawn made of polypropylene LDPE 11503-070 GOST 16337-77, modified with carbon nanotubes brand TUBALL TU 20.13.21-001-91735575- 2021 sewn to a flexible base of coating 4 with a density of 15-20 stitches per dm ² and a pile height from 5 mm to 25 mm 7 (see Figs 2, 3), a surface resistivity of 300 Ohm to 600 Ohm is provided.

b) According to option 2, due to the forced moistening of a combined radio-absorbing heat-resistant coating installed on the surface of a ground-based military object, a generator for placing a controlled water foam-aerosol mask over the ground object to interfere with the guidance means of high-tech weapons (see RF patent for utility model No. 183038 on application No. 2018113135 dated April 11, 2018) ensuring the possibility of water absorption by volume from 25% to 45% to achieve surface resistivity of the first layer of coating module 6, variable from 50 Ohm to 100 Ohm (see Fig. 1, 2, 3), as well as due to the simultaneous forced moistening of the outer second layer of filling material 7 (see Fig. 1, 2, 3) with the achievement of its surface resistivity from 300 Ohms to 600 Ohms.

Real-time control of the relative humidity of electrically conductive materials of a combined radio-absorbing heat-resistant coating, when a ground-based military facility is located on the ground according to two options, opens up prospects for adapting the physical parameters of the spectral characteristics and structural and functional indicators of the combined radio-absorbing heat-resistant coating to changes in the relative humidity of the surrounding air environment and adjacent to the object of local materials, natural vegetation and the creation of a controlled camouflage effect:

- in the IR EMW range, by regulating the emitted temperature contrast of the combined radio-absorbing heat-resistant coating relative to the temperature of the underlying background;

- in the EMW radar range, by regulating in real time the frequency dispersion in the electrically conductive materials of the combined radio-absorbing heat-resistant coating, their effective dielectric constant and ensuring the required attenuation of the intensity of the EMW reflected signal in a given frequency range.

The use in the design of the module of a flexible coating base made of dielectric perforated heat-resistant fabric, coated with a layer of heat-resistant Thermo-S coating, which has a thermal conductivity coefficient of the material from 0.046 W/Km to 0.027 W/Km and thermal resistance from -195°C to +1200° C, provides a guaranteed sharp reduction in the thermal contrast between the surface of the object and the surrounding background of the area in the IR range of the electromagnetic wave spectrum, as well as protection of a camouflaged military object from the thermal effects of incendiary weapons.

The assessment of the effectiveness of the functioning of a combined heat-resistant radio-absorbing coating installed on the surface of a ground-based military object was carried out by calculation and experiment according to the selected criteria for not detecting a ground-based military object TCP in the visible, IR and radar ranges of the spectrum of electromagnetic waves [Fundamentals of protection against technical reconnaissance: a textbook / Yu.K. . Menshakov. - M.: Publishing house of MSTU im. N.E. Bauman 2011, - 478 p.] and maintaining the thermal resistance of a ground military facility from the factors of incendiary weapons [GOST R 53295-2009 “Fire protection means for steel structures. General requirements. Method for determining fire retardant efficiency", GOST 7076-99 "Building materials and products. Method for determining thermal conductivity and thermal resistance under stationary thermal conditions."]

As a result of the tests of the developed versions of experimental samples of a combined heat-resistant radio-absorbing coating, it was established that: control in an adaptively variable mode of the structural and functional indicators and physical parameters of the spectral characteristics of experimental samples of a combined heat-resistant radio-absorbing coating simultaneously in the visible, IR and radar ranges of the spectrum of electromagnetic wave lengths can be ensured by a simultaneous reduction in brightness and thermal contrasts between the surface of the object and the surrounding background of the area, as well as a reduction in the effective scattering area (ESR, ^m2 ) of the hidden ground military object. Wherein:

- in the visible range of the spectrum of electromagnetic wavelengths, a decrease in the brightness contrast between the surface of the object and the surrounding background of the area is achieved due to camouflage protective or deforming coloring of a combined heat-resistant radio-absorbing coating to match the color and structure of the natural grass cover of the surrounding background of the area [Efimov V.A., Kolchevsky V.E. . Chermashentsev S.G. Disguise. Part I. Fundamentals and techniques of camouflage. Textbook. - M.: VIA, 1971. - 348 p.] while ensuring light stabilization of the spectral brightness coefficients (SBC) of camouflage dyes or pigments, due to the newly developed composition of a hydrosol of silver cations in an aqueous dispersion introduced into their composition [Gerasimenya V.P., Klykov M.A., Zakharov S.V., Slepnev A.A., Kutavin A.N., Vavilova S.S. RU patent for invention 2640925 dated September 19, 2016. Method for producing dyed textile materials treated with silver cations hydrosol with a complex of light-stabilizing, antimicrobial and antitoxic properties.” Published January 12, 2018, Bulletin. No. 2.];

- in the IR range of EMW lengths, a decrease in the thermal contrast of a ground-based military object relative to the underlying terrain background is achieved by changing in real time the relative humidity of the electrically conductive material of the combined heat-resistant radio-absorbing coating, leading to regulation of the emitted thermal contrast of the ground-based military object relative to the underlying terrain background. Calculations were carried out with a temperature contrast between the military facility and the environment from 15°C to 20°C, relative air humidity W = 65-70%, temperature of the radiation source 65-75°C and the location of the object on a plant background with T _rf = 12-15 °C indicate that the conditions are not detectable according to the established criterion of not detecting an object in the infrared range of the spectrum, electromagnetic waves are carried out in a strictly established process of shielding, absorption and dispersion of thermal radiation of a ground-based military object in the process of using the proposed combined heat-resistant radio-absorbing coating. The ability to control humidity opens up prospects for adapting these materials to changing environmental conditions of the area. In addition, the inclusion in the design of the module of a flexible coating base 4, made of dielectric perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm, heat-resistant fabric of the E1-125P (95) brand, with an applied layer of heat-resistant Thermo-S coating 3.0 mm thick perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm, additionally ensures a reduction in the thermal contrast of a camouflaged ground military object relative to the underlying terrain to the level of the contrast sensitivity threshold of TCP and VTO guidance systems, since it is heat-resistant Thermo-S coating has a thermal conductivity coefficient of the material from 0.046 W/Km to 0.027 W/Km and thermal resistance from -195°C to +1200°C.

- in the EMW radar range, a decrease in the radar contrast of a ground-based military object relative to the underlying terrain background is achieved by reducing the level of the reflected signal in the frequency range 1-40 GHz from 10 to 25 dB, which corresponds to the performance of the best radio-scattering camouflage materials. The required attenuation of the level of the signal reflected from the surface of a camouflaged ground military object in a given frequency range of electromagnetic waves is ensured by the selected thickness and experimentally created radiophysical properties of the materials of the first and second - upper layers of the coating module, as well as adaptive regulation of the relative humidity of the material of the first layer of the coating module, leading to a change real-time frequency dispersion of its effective dielectric constant.

Thus, the reliability of holding a combined radio-absorbing heat-resistant coating on the surface of a ground-based military facility during its operation in conditions of high and low ambient air temperatures is ensured by structurally linked and interconnected individual modules of the flexible coating base, made of perforated dielectric, with a density of 1. 0 / cm ² and a hole diameter of 3.0 mm, heat-resistant fabric brand E1-125P (95), strength of the network with a mesh of 400.0 × 400.0 mm and clamps made of heat-resistant cord brand ShKM TU 23.99.19-015- 87401176-2019 with a diameter of 4.0 mm, as well as the density of the connection of the coating with the surface of a ground-based military object with a pitch of 400 mm and the strength of the selected type of nodal connections, which in turn, which in turn makes it possible to achieve the problem solved in the claimed utility model.

Claims (4)

1. A combined heat-resistant radio-absorbing coating containing a flexible base and a filling material fixed to its surface, made in the form of interconnected layers of coating with different resistivities, which is made of n-separate modules interconnected along the perimeter, with a flexible base of the module The coating is made in the form of glass fabric, which is a dielectric, on the surface of which, on the front upper side, is glued a continuous layer of filling material made of water-absorbing foamed silicone polymer with a thickness of 5 mm to 10 mm with the possibility of water absorption by volume from 25% to 45%, modified electrically conductive nanodispersed material achieving a surface resistivity from 50 Ohm to 100 Ohm, to the front upper part of which a second layer of filling material is sewn, made in the form of an artificial grass lawn made of polypropylene with a density of 15-20 stitches per ^dm2 of coating and a pile height of 5 mm up to 25 mm, providing a surface resistivity of the second top layer of coating from 300 Ohm to 600 Ohm and having a camouflage color, with the possibility of attaching a camouflage coating to the surface of a ground-based military facility, characterized in that the individual coating modules are interconnected along the perimeter with clamps made of heat-resistant cord brand ShKM with a diameter of 4.0 mm, and the coating itself on the surface of a ground military facility is secured using a network with a mesh of 400.0 × 400.0 mm, made of heat-resistant cord of the ShKM brand with a diameter of 4.0 mm, laid on the surface of its second outer layer filling material made in the form of an artificial grass lawn made of polypropylene LDPE 11503-070, modified with carbon nanotubes of the TUBALL brand, while the network on the inside of the covering is secured with clamps made of heat-resistant cord of the ShKM brand with a diameter of 4 mm to brackets welded to the surface of the protected object. 2. Combined heat-resistant radio-absorbing coating according to claim 1, characterized in that the flexible base of the coating is made of dielectric perforated, with a density of 1.0 / cm ² and a hole diameter of 3.0 mm, heat-resistant fabric of grade E1-125P (95), with operating temperature from -200°C to +550°C, on the surface of the lower side of which, facing the object, is applied a layer of heat-resistant Thermo-S coating 3.0 mm thick, perforated with a density of 1.0 / cm ² and a hole diameter of 3, 0 mm, having a thermal conductivity coefficient of the material from 0.046 W/Km to 0.027 W/Km and thermal resistance from -195°C to +1200°C, 3. The combined heat-resistant radio-absorbing coating according to claim 1, characterized in that from 1.0 to 2.7 wt.% of TUBALL brand carbon nanotubes of the total mass is introduced as an electrically conductive nanodispersed material, uniformly distributed throughout the entire volume of the water-absorbing foamed organosilicon polymer. polymer, providing a surface resistivity of the first coating layer from 50 Ohms to 100 Ohms. 4. The combined heat-resistant radio-absorbing coating according to claim 1, characterized in that from 2.5 to 6.4 wt. % of TUBALL carbon nanotubes from the total mass of polypropylene, providing a surface resistivity of the second top layer of coating from 300 Ohms to 600 Ohms and having a camouflage color.