RU2548475C1 - Infrared radiation-absorbing composition for soaking textile articles - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to compositions intended for absorbing infrared radiation generated by external sources of electromagnetic waves in the infrared spectrum and infrared radiation coming from the object itself. The composition for soaking textile articles contains the following components (vol %): mineral, semisynthetic and synthetic industrial liquid hydrocarbons in the form of multi-grade engine oil or food-grade vegetable liquid hydrocarbons in the form of food-grade vegetable oils - 99; pigment-dye - soot in the form of monochromic, black, nonmagnetic, mechanical toner which is uniformly distributed in the medium of said liquid hydrocarbons - 1.

EFFECT: improved absorption of infrared radiation when the object is irradiated with electromagnetic waves in the infrared spectrum.

Description

The technical field to which the invention relates.

The invention relates to the field of development of camouflage means, to compositions that absorb electromagnetic radiation in the near infrared range of wavelengths used to impregnate the textile base of uniforms of military personnel and textiles used to mask military equipment, with the aim of their electromagnetic camouflage in the near infrared range of lengths waves.

The level of technology.

Public information about the analogues of the invention known to the applicants with the isolation from them of an analogue closest to the invention (prototype) by the claims has not been identified.

Information about analogues of the invention known to applicants with isolation of an analogue closest to the invention (prototype) in terms of its scope:

Known night vision devices (hereinafter - “NVD”) operating in the near infrared wavelength range (0.78-1 μm). NVDs can work both in passive and in active mode. The passive mode is applied in the presence of intrinsic radiation of the object under observation and in conditions of weak scattered radiation from random artificial or natural sources, the level of which exceeds 10 ^-5 lux. The active mode is used in conditions of complete absence of lighting to irradiate the studied object and to receive infrared light reflected from it. It is accompanied by the use of the illumination source of the observation object. Such a source can be a laser LED or a special IR illuminator, as a rule, operating in the wavelength range of 0.82-0.98 microns.

In images obtained using NVD, objects with high reflectivity look like bright silhouettes. This effect is due to infrared radiation reflected from the surface of the object coming from an external source (for example, NVD illumination).

Known approaches to masking objects from detection by infrared radiation detectors are based on the method of heat reflection through the thermal insulation technology of the masked object in order to minimize the reflection of thermal radiation of the object, equalizing the contrast of the reflection of infrared radiation between the object and the environment.

For example, US Pat. No. 5,282,460 [1] proposes a strip pattern overlaid on a porous nylon mesh. The bands are coated with silver, copper or pigment.

US Pat. No. 4,495,239 [2] uses a base layer of textile fabric. On which a metal reflective layer is deposited by gas deposition, and then camouflage painting is performed.

US Pat. No. 4,659,602 [3] uses a woven material on which a metal foil and a polyethylene film containing conductive particles are arranged.

In US Pat. No. 4,621,012 [4], the textile material is coated with a thermoplastic material containing inside the selected dipole material and having a metal layer that reflects infrared radiation.

US Pat. No. 4,064,305 [5] proposes knitwear made of cut polymer fibers and cut metal fibers that reflect radar waves.

US Pat. No. 4,529,633 [6] describes an electromagnetic reflective material consisting of a polyethylene layer, a metal coating layer, an adhesive and a fabric.

US Pat. No. 4,533,591 [7] proposes a thermoplastic resin with discrete electromagnetic particles scattered therein.

US Pat. No. 4,467,005 [8] uses a support net, on both sides of which there is a carrier web with a metal coating reflecting IR radiation.

In US patent 97118428/12 (Pat. RU 2127194) [9]. The infrared reflective coating material comprises at least one metallized microporous membrane duplicated with at least one more layer of textile material. In the material, the metallized membrane is made of microporous foamed polytetrafluoroethylene, the textile base is silk, and the metal is aluminum.

In the patent of the Russian Federation 2403328 [10] describes a material with a coating that reflects infrared radiation, containing a textile base in the form of a polyester textile material with water-repellent impregnation, a metallized layer in the form of titanium nitride deposited on a microporous membrane layer at the atomic-molecular level, and a microporous membrane layer made of thermoplastic polyurethane resin, which is placed between the textile base and the metallized layer.

In the dissertation for the degree of candidate of technical sciences on the topic "Development of the technology for the production of shielding garments" Specialty 05.19.04 - "Technology of garments" (IGTA, Ivanovo, 2007) [11] solved the problems of development and camouflage clothing for military personnel , where for the first time a metallized coating was used, the use of which significantly increases the camouflage properties of products of a similar purpose. It has been theoretically proved and practically confirmed that the use of a metallized coating will improve the shielding properties of the product. To reduce thermal radiation from the human body, packages of materials were selected using the metallization technology of coating the inner surface of the suit, which allows to increase the shielding properties of the product by 14.5 times when using aluminum, and when using titanium and titanium nitride - by 23 and 36.5 times, respectively .

The disadvantages of the above inventions are:

- a limited methodological and technological approach to creating the properties of electromagnetic camouflage, selectively based on the method of reflection of infrared radiation, by increasing the properties of camouflage materials insulating infrared radiation;

- materials, by the level of their manufacture, are products of high-tech and resource-intensive industrial production, in particular, using gas spraying technologies or pressing methods, which obviously shows the impossibility of their prompt creation in the field or restoration of such fabrics in the field in the presence of extensive damage.

However, there is another characteristic of thermal radiation - the absorption capacity of the body, determined through the absorption coefficient of the body, calculated as the ratio of the absorbed flux of radiant energy incident on the elementary area of the body to the flux of radiant energy incident on this area, due to electromagnetic waves whose length is in a given interval.

The absorption coefficient of the body depends on the wavelength of the incident radiation, on the temperature of the body, its chemical composition and surface condition. By definition, the absorption coefficient cannot be greater than 1. A body that absorbs all the radiation incident on it, regardless of the direction of incidence of the radiation and its spectral composition, is called a completely black body. For such a body, the absorption coefficient is equal to unity for all wavelengths and temperatures.

Bodies for which the absorption coefficient in a wide range of wavelengths remains constant, but less than unity, are called gray bodies. In gray bodies, the absorption coefficient depends only on temperature, material and surface condition. There is a direct connection between the spectral density of energy luminosity and the absorption coefficient of any body - such a system will come to a state of thermal equilibrium after some time - all bodies will take the same temperature equal to the shell temperature. In this state, a body with a higher spectral density of energy luminosity loses more energy per unit time per unit surface than a body that has a smaller one. Since the temperature (and hence the energy) of bodies does not change, the body radiating more energy must absorb more, i.e. have a higher spectral density of energy luminosity. Thus, the greater the spectral density of the energy luminosity of a body, the greater is its absorption coefficient for the flux of radiant energy incident on an elementary site due to electromagnetic waves whose lengths are in a given interval.

This relation expresses the law established by Kirchhoff (1859): The ratio of the spectral density of energy luminosity to the absorption coefficient does not depend on the nature of the bodies, is for all bodies the same (universal) function of wavelength (frequency) and temperature and is equal to the spectral density of energy luminosity absolutely black body.

With respect to the subject of the invention, the consequence arising from Kirchhoff’s law is of great importance:

1. Every body at a given temperature emits electromagnetic waves of that frequency, which it absorbs at the same temperature. [12].

The Stefan-Boltzmann law determines that the energy luminosity of an absolutely black body is proportional to the fourth power of temperature, and in accordance with Wien's law (the law of displacement), the wavelength at which the maximum spectral density of energy luminosity of an absolutely black body is inversely proportional to the temperature T. .e. from thermodynamic considerations it follows that the equilibrium radiation energy density depends only on temperature and does not depend on the properties of the cavity walls.

Therefore, from the statements made above regarding the subject of the invention, a fundamentally important conclusion follows:

- regardless of the known types of materials, their structural construction over time, the properties of such materials reflecting the infrared radiation of an object will decrease due to the influence of thermodynamic laws;

Thus, the application of the properties of materials that absorb electromagnetic radiation from the infrared wavelength spectrum, both in the mode of irradiating the object from the external environment and in the infrared mode of the object, acquires the level of an alternative direction in the development of electromagnetic camouflage methods.

Information is known about the methods of using the properties of materials to absorb infrared radiation, representing a certain (methodological) connection with the subject of the present invention:

RF patent 2194236 [13] describes a screen that absorbs directional optical radiation containing N cells, each of which is formed by two cylindrical surfaces and a forming surface. These cylindrical surfaces have a variable angle of inclination to the forming surface of the screen and camouflage coating in areas visible from the directions of the possible incidence of directional optical radiation. In areas that are not visible from the indicated direction of optical radiation, a coating absorbing optical radiation is deposited on cylindrical surfaces. This allows you to take the main share of the power of the directed optical radiation out of sight from the sector of the possible incidence of directional optical radiation. In areas of cylindrical surfaces that are not visible from the directions of incidence of directional optical radiation, absorption of directional optical radiation occurs

The invention relates to means of camouflage, in particular to masking screens, and can be used to counter technical means of reconnaissance of the enemy.

RF patent 2197041 [14] describes a method for producing multilayer nonwoven materials from a mixture of dielectric and electrically conductive fibers having radio-absorbing properties in a wide range of electromagnetic radiation (EMR) by pre-forming canvases from synthetic fibers, dispersing carbon fibers in a liquid or gaseous medium, and filtering the dispersion through a canvas of synthetic fibers or laying a tape of electrically conductive materials on a canvas of synthetic fibers, assembly of a multilayer package from at least two non-woven synthetic webs, one of which is applied a layer of carbon fibers or ribbons of conductive material so that a layer of carbon fibers or ribbons of conductive material alternated with fiber batts of synthetic fibers, followed by piercing the assembled multilayer needles packet. The invention relates to absorbers of electromagnetic waves and means of masking, and more particularly to methods for producing multilayer nonwoven materials from a mixture of dielectric and electrically conductive fibers having radio-absorbing properties in a wide range of electromagnetic radiation (EMR).

RF patent No. 2343547 [15] describes a method of protecting against counterfeiting of valuable products and verifying their authenticity, in which a passive protective agent of a given structure is formed on a valuable product, it is possible to control its presence and authenticity, nanosized island films of Co are used as a protective agent material level as well as multilayers. in which the island Co films are separated by nanosized layers of SiO ₂ , in this case, anomalous absorption of the probe electromagnetic radiation of the optical range is used as detectable informative features, which use laser radiation in the infrared optical wavelength range, and the ability to control the presence and authenticity of the protective agent is provided by the method analysis of optical effects during external exposure to the specified radiation and detection of informative what is the optical response of the protective agent to the aforementioned external effect, which consists in reducing the intensity of the reflected radiation, followed by a comparison of the registered parameters of the informative features with the informative features contained in the database of the detection means.

RF patent 2456558 [16] describes a device for determining the albedo of the active surface of a material. consisting of two identical heat-receiving elements, the receiving surfaces of which are multidirectional facing the infrared source and the surface of the studied material for absorbing radiant fluxes, and thermocouples, characterized in that the receiving surfaces and side faces of the metal plates of the heat-receiving elements are coated with black moisture-proof paint, the surface of the plates opposite to the receiving surfaces are covered with a layer of thermal hydroinsulation with a reflective film, thermocouples p gistriruyut heating plates in time at which mathematically calculated albedo active surface material.

RF patent 2385895 [17] describes an agro-horticultural ground cover film comprising a layer reflecting white light and containing a material reflecting white light, and a layer absorbing infrared radiation and containing nanoparticles of a material that absorbs infrared radiation. The infrared absorbing material is at least one of tungsten oxide nanoparticles and complex tungsten oxide nanoparticles, which, in turn, are coated with an oxide that contains at least one element selected from Si, Ti, Zr and Al.

RF patent 2294944 [18] describes an infrared-absorbing polyvinyl butyral composition, a layer made of it, and laminated glass containing it. Said composition comprises a melt-processable polyvinyl butyral resin and lanthanum hexaboride dispersed in said polyvinyl butyral resin, and at least one component selected from mixed indium and tin oxide and mixed antimony and tin oxide. The polyvinyl butyral sheet layer is used for car glazing and architectural glazing, a viewing cover and protective glass for paintings, documents, etc., also absorbs energy and prevents destruction.

In the patent of the Russian Federation 2325631 [19] describes a method for determining the concentration of components in the flow of a water-oil mixture. The method for determining the components in a water-oil mixture is based on the spectral dependences of the absorption coefficients of oil and water in the near infrared region, where for the technical implementation of the method there are inexpensive and compact optical emitters such as injection semiconductor lasers and high-power LEDs, and there are also inexpensive, durable, high-speed photo detectors - photodiodes based on germanium and InGaAs ternary compounds.

The disadvantages of the above inventions are:

- Inventions are not analogues of the claimed invention, cannot be qualified as its prototypes, do not apply to compositions that absorb electromagnetic radiation in the near infrared wavelength spectrum used to impregnate the textile base of military uniforms and textiles used to mask military equipment,

- materials, by the level of their manufacture, are products of high-tech and resource-intensive industrial production, in particular, using laser and semiconductor technologies, gas spraying technologies, or pressing methods, which obviously shows the impossibility of their prompt creation in the field or restoration in the field in the presence of extensive damage like materials;

It should also be noted that detailed open information about the properties of liquid hydrocarbons known to the applicants in the form of all-season motor oils or edible vegetable oils to absorb electromagnetic radiation in the infrared range of the wavelength spectrum used as the basic component of the composition in the present invention is not revealed.

The technical result of the claimed invention is the provision of electromagnetic camouflage of an object by improving the ability of a material treated with a special composition to absorb infrared radiation when the object is irradiated with electromagnetic waves of the infrared spectrum.

The technical result is achieved by potentiating the ability of the components of the composition to absorb infrared radiation. The composition contains a liquid hydrocarbon acting as the first absorber of infrared radiation, mineral, semisynthetic, synthetic or plant origin, having low thermal conductivity (interval λ 0.1-0.13 W / Mk [20]) and the second absorber of infrared radiation - evenly distributed in liquid hydrocarbon pigment-dye, in its absorption capacity, is a gray body, the absorption coefficient of thermal radiation of which is close to the absorption coefficient of an absolutely even body [21].

According to the invention, the following are used as liquid hydrocarbon:

- or all-season engine oils,

- or edible vegetable oils,

in quantity - 99% by volume (hereinafter - volume%);

- pigment dye "soot", or in the form of monochrome, black, non-magnetic, mechanical toner in an amount of 1 vol.%.

The pigment dye "carbon black" is evenly distributed in the medium of the above liquid hydrocarbons.

Empirically determined are combinations of different types of liquid hydrocarbons and pigment dye when impregnating textile materials containing a different ratio of cotton and synthetic fibers. We studied the effectiveness of the camouflage properties of the composition in night-time night vision with various indicators of the concentration of the pigment dye “soot” in liquid hydrocarbon — from 0 to 5 volume%. The following regularities of the effectiveness of camouflage composition properties were also determined: 1. The increase in pigment-dye concentration has a dependence close to direct on the specific gravity of synthetic fibers in the textile base of the material, since the structure of the latter has a greater ability to reflect infrared radiation than cotton fiber; 2. There is a dependence close to a straight line between the surfaces of the environment reflecting infrared radiation and the concentration of pigment dye. So, for example, the minimum concentration of pigment dye or its absence (0 volume%) is required for camouflage of textile fabric at night in a landscape with an abundance of deciduous shrubs and trees (the so-called "green"), the concentration of pigment dye is close to limiting (up to 5 volume%) are suitable for camouflage of textile fabric in a landscape with a predominance of conifers with a slightly pronounced undergrowth.

However, all other things being equal:

- a necessary and sufficient criterion for the concentration of liquid hydrocarbon, providing infrared electromagnetic camouflage composition, is its concentration in the amount of 99 volume%;

- a necessary and sufficient criterion for the concentration of pigment dye "soot", providing infrared electromagnetic camouflage composition, is its concentration in the amount of 1 volume%;

- a composition made on the basis of vegetable oil is subjectively more comfortable to use than compositions made on the basis of motor oils.

The composition that absorbs infrared electromagnetic radiation has an applied multivariate manufacturing technology that can be easily implemented in the field, low production costs, is applicable in a wide temperature range for the impregnation of textile products for any purpose.

Based on the claimed properties of the composition, certain disadvantages of a textile product impregnated with a similar composition follow: the fabric becomes impervious to water vapor and does not provide proper camouflage in the visible range of electromagnetic waves.

To test the infrared absorbing composition, which is impregnated with the textile material, a night vision system was used, namely the Yukon NV Exelon 4 × 50 night vision monocular (24102), the shooting was carried out using a Samsung ES28 camera. The observation was carried out at night in the range of ambient temperatures from - 7 C to + 15 C at a distance of 5 to 30 meters behind an object dressed sequentially in camouflage fabric (suit or cape) containing 100% cotton fiber, then in camouflage fabric (suit or cape) made of textile fiber containing 53% cotton fiber and 47% polyester or other synthetic fiber, and then into camouflage fabric (suit or cape) containing 57% polyester or other synthetic fiber and 43% cotton about fiber. In all types of suits, especially in suits with synthetics, the silhouette outlines of the object were determined in the NVD at a distance of at least 15-20 meters (see file: Video fragment 1. Source materials in the NVD).

Then these costumes were saturated with the claimed composition. The camouflage effect of objects dressed in suits impregnated with the inventive composition, when observed in the NVD, was provided at a distance of 5-8 m from the infrared radiation source (see file: Video fragment 2. Materials processed in the NVD), enhanced, in addition to the infrared integrated into the device illuminating device, an additional laser light source in the form of red laser radiation with a power of 5 mW.

These studies confirm that the claimed composition when it impregnates a textile material has the ability to absorb infrared radiation generated by an external source.

Example 1

An infrared absorbing composition for impregnating textiles consisting of 100% cotton fiber is obtained by mixing multigrade mineral motor oil - 99% (vol.%) And pigment - dye "soot", in the form of monochrome, black, non-magnetic, mechanical toner, in the amount of 1% (vol.%). Mixing is carried out at room temperature. Toner is evenly distributed in the oil. The uniformity of the distribution of the toner is achieved by pouring a certain volume of oil onto the calibrated volume of the toner, followed by electromechanical mixing until a homogeneous composition.

Example 2. An infrared absorbing composition for impregnating textiles consisting of 100% cotton fiber was prepared according to a procedure similar to that of Example 1, except that multigrade motor semi-synthetic oil was used.

Example 3. An infrared-absorbing composition for impregnating textiles consisting of 100% cotton fiber was prepared according to a procedure similar to that of Example 1, except that a mixture of used motor oil was used, which includes an arbitrary ratio of all-season mineral and semi-synthetic oils .

Example 4. An infrared absorbing composition for impregnating textiles consisting of 100% cotton fiber was prepared by a method similar to that of Example 1, except that edible vegetable sunflower oil was used.

Example 5. An infrared-absorbing composition for impregnating textiles consisting of 57% cotton fiber and 43% polyester or other synthetic fiber is obtained by a method similar to that of Example 1 by mixing multigrade mineral motor oil - 99% (vol.%) and pigment - dye "soot", in the form of monochrome, black, non-magnetic, mechanical toner, in an amount of 1% (vol.%), which is evenly distributed in motor oil.

Example 6. An infrared absorbing composition for impregnating textiles consisting of 57% cotton fiber and 43% polyester or other synthetic fiber was prepared according to a procedure similar to that of Example 5, except that an all-weather semi-synthetic motor oil was used.

Example 7. An infrared-absorbing composition for impregnating textiles consisting of 57% cotton fiber and 43% polyester or other synthetic fiber was prepared according to a procedure similar to that of Example 5, except that used motor oil was used, including optionally the taken ratio of all-season mineral and semi-synthetic oils.

Example 8. An infrared absorbing composition for impregnating textiles consisting of 57% cotton fiber and 43% polyester or other synthetic fiber was prepared by a method similar to that of Example 5, except that edible vegetable sunflower oil was used.

Example 9. An infrared absorbing composition for impregnating textiles consisting of 57% polyester or other synthetic fiber and 43% cotton fiber was obtained by a method similar to that of Example 1 by mixing multigrade mineral motor oil - 99% (vol.%) and pigment - dye "soot", in the form of monochrome, black, non-magnetic, mechanical toner, in an amount of 1% (vol.%), which is evenly distributed in motor oil.

Example 10. An infrared absorbing composition for impregnating textiles consisting of 57% polyester or other synthetic fiber and 43% cotton fiber was prepared by a method similar to that of Example 9, except that multigrade motor semi-synthetic oil was used.

Example 11. An infrared-absorbing composition for impregnating textiles consisting of 57% polyester or other synthetic fiber and 43% cotton fiber was obtained by a method similar to that of Example 9, except that used motor oil was used, which includes optional the taken ratio of all-season mineral and semi-synthetic oils.

Example 12. An infrared absorbing composition for impregnating textiles consisting of 57% polyester or other synthetic fiber and 43% cotton fiber was prepared by a method similar to that of Example 9, except that edible vegetable sunflower oil was used.

The file: “Video fragment 1. Source materials in NVD” presents the possibilities of absorbing electromagnetic waves of the infrared spectrum upon irradiation of an object equipped with textile material that has not been processed by the claimed composition.

In the file: “Video fragment 2. Materials processed in the NVD”, the possibilities of absorbing electromagnetic waves of the infrared spectrum when irradiating an object equipped with the same textile material that was previously processed by the claimed composition are presented.

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Claims (1)

An infrared absorbing composition for impregnating textiles containing the following components (in% by volume):
- liquid hydrocarbons of mineral, semi-synthetic, synthetic origin for technical purposes in the form of all-season motor oils or liquid hydrocarbons of vegetable origin for food purposes in the form of edible vegetable oils - 99%;
- pigment dye - carbon black, in the form of monochrome, black, non-magnetic, mechanical toner, which is evenly distributed in the medium of the above liquid hydrocarbons, - 1%.