RU183038U1 - Generator of a controlled water-based foam-aerosol mask-interference to the WTO guidance means over a ground object - Google Patents

Abstract

The inventive utility model relates to the field of camouflage, in particular to technical means of mechanization with controllable structural elements that provide automated staging above a masked ground object of an aqueous foam-aerosol mask-noise, which reduces the visibility of the object when the WTO ammunition is aimed at the target.

The technical result is achieved by introducing into the generator device of the autonomous control system the formulation of an aqueous foam-aerosol formation above the ground object for automatic control of nozzles and an electromagnetic valve integrated into the pipe channel for timely spraying of the water mixture over the masked ground object with the formation of an aerosol foam-mask that provides reduction of contrasts between the masked object and the background simultaneously in the visible, infrared and radar range ah spectrum EMW lengths in the direction of the WTO system targeting.

The essence of the model is the introduction into the generator device of an autonomous control system of nozzles and an electromagnetic valve integrated into the pipeline channel for timely spraying of a water mixture over a masked ground object with the formation of a foam-aerosol mask-interference. At the same time, the required camouflage effect of the object under the direction finding of the target and pointing to it with modern WTO means using the inventive utility model is achieved by timely proactive adaptive change in the position of the nozzles for spraying the water foam-aerosol mask-noise relative to the line of sight "means of guiding the WTO - object" , which allows to achieve the following camouflage effect:

- complicates the recognition by means of guidance of the type of an object in the visible range of the EMW length spectrum by reducing the brightness contrast between the background and the object;

- reducing the thermal contrast between the surface of the masked object and the surrounding background in the infrared range of the EMW length spectrum due to the weakening of the thermal radiation of the heated parts of the surface of the object;

- reducing the effective dispersion surface (EPR) of the object in the radar range of the EMW length spectrum due to the attenuation and dispersion of the electromagnetic wave of the radar irradiation of the masked object by means of guiding the WTO. 1 n.p. f-ly, 2 z.p. f-ly.

Description

The inventive utility model relates to the field of camouflage, in particular to technical means of mechanization with controllable structural elements that provide automated staging above a masked ground object of an aqueous foam-aerosol mask-noise, which reduces the visibility of the object when aiming a high-precision weapon (WTO) ammunition.

The required camouflage effect of the object under direction finding of the target being hit and guidance of modern WTO means using the inventive utility model is achieved by timely proactive adaptive change in the position of the nozzles for spraying an aqueous foam-aerosol mask-interference relative to the line of sight "WTO guidance facility - object", which allows you to achieve the following camouflage effect:

- complicates the recognition by means of guidance of the type of an object in the visible range of the length spectrum of electromagnetic waves (EMW) by reducing the brightness contrast between the background and the object;

- reduces the thermal contrast between the surface of the masked object and the surrounding background in the infrared (IR) range of the EMW length spectrum due to the attenuation of the thermal radiation of the heated parts of the surface of the object;

- reduces the effective dispersion surface (EPR) of the object in the radar range of the EMW length spectrum due to the attenuation and dispersion of the electromagnetic wave of the radar (RL) irradiation of the object.

One of the tasks of camouflage is to disrupt guidance (aiming) and the application of active interference to the analyzers of homing heads of the WTO at the moment of their aiming at the target by reducing the visibility of the ground object simultaneously in the visible, infrared and radar ranges of the length spectrum (EMW).

To ensure the search, detection and recognition of targets in the homing heads, the following guidance equipment is used:

analyzers working on the principle of space scanning (optical and radar ranges);

analyzers with multi-element receivers (laser, semi-active guidance systems);

analyzers that use microstructures of the target image in the visible and IR wavelength ranges (television and thermal imaging guidance systems).

Smoke munitions are known that are used to hide ground targets, which are devices for the formation of aerosols (smokes) and smoke curtains to blind the enemy, in order to reduce the visibility of ground targets and the actions of their forces (troops) in the course of solving various tactical tasks. Such tools include hand smoke grenades and smoke bombs, differing in size and smoke-generating compositions, consisting of a body and an igniter device with an igniter composition. [one].

A known method of thermal protection of objects by producing opaque fog (patent GB 2000575 (A), 10/01/1979, IPC F41H 9/06). According to a known method, a cloud similar to fog is formed in which a powder (talc, calcium carbonates, kaolin) is used. The cloud is cold, neutral, non-toxic, opaque to visible and IR radiation in the wavelength range from 3 microns to 5 microns and from 8 microns to 14 microns.

There is also a method of reducing infrared radiation of heated surfaces and gas flows of industrial facilities (application 2011109710/11 of 03.15.2011, patent RU 2466346 published 10.11.2012, F41H 9/06). In it, to reduce the infrared radiation of heated surfaces and gas flows of industrial facilities, thermal shielding of these objects is carried out using polydisperse fog. The fog is created using filtered unheated water using ultrasonic generators operating in continuous mode, which are located near heated objects.

The disadvantages of the considered analogues is that they do not provide a decrease in the visibility of ground objects in the radar range of the EMW length spectrum, but are effective only in one of the EMV ranges: visible or IR. In addition, clouds impervious to visible rays interfere with the operation of their own optical monitoring devices and staff performance. In practice, the presence of wind in the zone of setting smoke curtains limits their use for effective thermal masking of heated surfaces and gas flows, since when mineral “mist” aerosol particles enter the heated medium and heat up, they themselves become a powerful IR radiation source, additionally unmasking an object. In addition, the smoke and aerosol screening facilities used do not have devices for detecting the radiation of a hidden ground object by the used electromagnetic radiation sources for guiding the WTO to the target.

The known "Infrared masking method and device for infrared masking" by applying a three-layer cover to the surface of the technique, having a fibrous or porous outer and inner layers and having a waterproof layer between them, a piping system having periodically arranged permanent or removable on the outer surface of the object, or nozzles spring-loaded in the backward direction for watering the masked object (patent application 2004123943/02 of August 6, 2004, patent RU 2552903, published June 20, 2006, F41H3), selected as prototype.

In this known invention, the use of a three-layer cover that gets wet as a result of watering (spraying) with a liquid (water, low-boiling liquid, non-freezing liquid or their mixture), thereby creating an aqueous layer on the surface of the equipment and cools it, reducing the thermal contrast between the equipment and the underlying background.

According to the known method, a three-layer cover is installed on the outer surface of the object, having fibrous or porous outer and inner layers with a waterproof layer integrated between them, which is cooled by watering or spraying with water, a boiling liquid, non-freezing liquid, or a mixture thereof.

A device for implementing the method is a fluid tank, a high pressure pump, a piping system with periodically built-in periodically fixed, either retractable, or spring-back nozzles for spraying over an object that are structurally linked to each other and to the surface of a ground object; liquids. The surface of the object may be doused with water from buckets, a hose and / or sprayed with liquid from nozzles. Water remains in the baths, absorbed into the inserts, and gradually evaporating reduces the temperature of the object.

The main disadvantage of the known device for infrared masking of an object selected as a prototype is, first of all, the lack of the possibility of using it to achieve the reduction of unmasking signs in the visible and radar ranges of the EMW length spectrum.

In addition, the uncontrolled use of water for wetting a three-layer cover placed on the surface of the object, when the cover moisture is exceeded by more than 50-60%, leads to an increase in unmasking signs in the radar range of the EMW length spectrum, since it sharply increases the EPR (m ² ), almost like from a flat metal plate . Such uncontrolled accumulation on the surface of an excess amount of liquid (water) enhances the radar portrait of equipment and increases the effectiveness of its destruction by the WTO.

Thus, the above known devices in their constructive solution do not meet modern requirements for providing, when used as technical means of aerosol mask-jamming, means for guiding the WTO to reduce the visibility of a masked ground object simultaneously in the visible, infrared and radar ranges of the EMW length spectrum.

The problem to be solved in the utility model under consideration is to improve the design and increase camouflage properties due to the controlled creation of an aqueous foam-aerosol mask-noise above the ground object relative to the line of sight “WTO guidance system - object”, which provides real-time counteraction to WTO guidance systems to the target simultaneously in the visible, infrared and radar range of the EME spectrum

The technical result is achieved by introducing into the generator device an autonomous control system of setting an aqueous foam-aerosol formation above the ground object to automatically control nozzles built into the pipe channel and

solenoid valve for timely spraying of a water mixture over a masked ground object with the formation of a foam-aerosol mask-interference, which reduces contrasts between the masking object and the background simultaneously in the visible, infrared and radar ranges of the EMW length spectrum in the direction of pointing the WTO system at the target.

This object is achieved by the fact that the generator of placing a controlled water foam-aerosol mask-obstacle over the ground object with the WTO guidance means contains a liquid tank, a high pressure pump, a piping system with periodically built-in pipelines that are structurally linked to each other and the surface of the ground object nozzles for spraying a liquid over an object. At the same time, nozzles built into the pipeline include a housing with a lateral bilateral threaded connection to the pipeline, inside to the lower part of which a step-by-step electric motor is mounted, which ensures the necessary position of the nozzle nozzle, from the top of which a part of the nozzle with the nozzle is rotated around the horizontal axis and hermetically jointed with the upper part of the body. The nozzle from the inside of the nozzle is connected by a threaded connection to the pipe channel, and from the outside it has an outlet of an aqueous foaming fluid supplied to it under pressure.

For timely creation of a foam-aerosol formation above the object, the generator is additionally equipped with an electromagnetic valve, an integrated threaded connection in the pipeline between the high-pressure pump and the first nozzle integrated in the piping system, the electric drive of which is connected to an autonomous control system for setting above the ground object, which is additionally included in the generator device water foam aerosol formation, including a sensor for detecting laser, infrared and radiol radiation exposure of a ground camouflage object, a decision-making and command generation device, a control line for autonomously providing an aqueous foam-aerosol formation in the area where the masked ground object is located at the moment of detecting a threshold value of the electromagnetic field level and / or laser irradiation by systems of guiding the ammunition to the target in the last section its trajectory, perceived in real time by means of signal detection sensors built into the autonomous control system guidance guided munitions. In this case, all the structural elements of the setting generator above the ground object of the controlled water foam aerosol formation are interconnected by assembly operations due to their articulation, and / or screwing, and / or riveting, and / or welding, and / or crimping, and / or soldering with the formation of functional structural unity of the device.

The length of the piping system and the configuration of its location on the surface of the masked ground object, as well as the number of nozzles periodically built into the pipeline included in the generator set, depends on the type of masked ground object and the masking method pre-selected in accordance with the plan.

The liquid mixture poured into the tank may depend on the type of masked ground object and the masking method preselected in accordance with the design and may be a colored foam-forming mixture of a 2.0 ... 5.0% (mass) solution of an anionic surfactant, for example, Stream ", Or" Cascade ", or" PO-A ", 0.5-1.0% (mass) of a dye of a given color, for example, either green-protective color, or gray-yellow color, or light brown color, 0, 5-1.0% (mass) of electrically conductive additives, such as nanotubes, or graphene and water, or not flickering at low temperatures unpainted foaming mixture of 2.0 ... 5.0% (mass) solution of anionic surfactant brand "Potok", or "Cascade", or "PO-A", 20-40% (mass) of a solution of propylene glycol , 0.5-1.0% (mass) of electrically conductive additives, such as nanotubes, or graphene and water.

As a result of using the generator of placing a controlled water foam-aerosol formation above the surface of the masked ground object above the surface of the masked ground object, creating a controlled water foam-aerosol mask-interference in the direction of the line of sight of the means of guiding the WTO, which reduces the visibility of the object simultaneously in the visible, infrared and radar ranges of the length spectrum EMV.

The technical nature of the claimed utility model is presented in FIG. 1-2.

In FIG. 1 is a schematic structural diagram of the operation of a staging generator over a ground object of a controlled aqueous foam-aerosol mask-interference to the means of guiding the WTO, where:

1 - high pressure pipeline, 2 - nozzle, 3 - object body, 4 - solenoid valve, 5 - high pressure pump, 6 - liquid tank, 7 - decision-making and command generation device, 8 - control lines, 9 - detection sensor laser / infrared / radar exposure, 10 - controlled water foam aerosol mask-interference.

In FIG. 2 shows the design of the nozzle with an electric control drive, where:

1 - high pressure pipeline, 11 - nozzle body, 12 - rotary part of the nozzle, 13 - stepper motor, 14 - possible position of the nozzle nozzle, 15 - nozzle nozzle.

The functioning of the generator is as follows: a laser / infrared / radar detector (9) detects the irradiation of an object of a guided submunition guidance system at a target at the last stage of its flight path or the operation of a laser guidance system, transmits data to a command decision making device (7). It determines the threshold values, upon reaching which a decision is made to set the water foam aerosol mask-interference (10), and transmits a command to the stepper motor (13). The latter rotates the spray nozzle of the nozzle (15) in the direction of flight of the submunition. Then, the high pressure pump (5) is turned on, using the on-off relay, the liquid pressure is created in the pipeline (1), nozzles (2) and a water foam aerosol mask is placed above the ground object (10). After work, for a certain period of time, the high pressure pump is turned off. The solenoid valve (4) of the high pressure pump equalizes the pressure of the liquid in the pipeline with atmospheric. The system goes into standby mode.

The required camouflage effect of the object in the conditions of bearing and guidance by modern WTO means using the inventive utility model “Generator of placing a controlled water foam-aerosol mask-obstacles to the means of guiding the WTO” above the ground object is achieved by adaptively changing the position of the nozzles for spraying the water foam aerosol mask -interference with respect to the line of sight "means of guiding the WTO - the object", which allows to achieve the following camouflage effect:

- in the visible range of the EMW spectrum, the effect of concealment is achieved by reducing the brightness contrast between the background and the object, which makes it difficult to recognize the type of object;

It was established [3] that the illumination of the optical image E _{from a} distant object is proportional to the brightness of this object,

where: B is the brightness of the object;

d _about - the diameter of the lens;

ƒ _about ^{_ the} focal length of the lens;

τ ₀ is the transparency coefficient of the optical system.

The response of the receiver depends on the brightness of the background and the object. Therefore, the capabilities of the optical means of reconnaissance of the enemy are determined primarily by the contrast between the background and the object in brightness: [2]

where: B ^I - the brightness of the object;

B ^II - the brightness of the object;

If the values of B ^I and B ^{II are} approaching each other, then at some moment the object cannot be distinguished from the background and K will reach a certain threshold of contrast sensitivity. The presence of an aqueous foam-aerosol mask between the object and the observer leads to a weakening of the light rays coming from the subject and background, and to the scattering of the aqueous foam-aerosol mask of light coming from all other directions. If B ^I _{t the} brightness of the object through an aqueous foam-aerosol mask, then [2]

where: r is the radius of the particles;

n is the concentration of particles per unit volume;

l is the thickness of the aerosol layer.

K _e threshold contrast ratio: K _e ≤ 0.2 (imperceptible) [3]

The background brightness in this case is equal to: [2]

External light scattered by an aerosol creates a glow whose brightness G is superimposed on the brightness of the object and background. In these conditions, the contrast is equal to: [2]

The brightness of the aerosol is assumed to be 0.1 [4], the concentration of droplets per unit volume is n≈3 × 10 ⁹ [5].

Using the values of the spectral brightness coefficient for some materials and types of underlying surfaces [3], the brightness coefficients of contrasting surfaces in the visible range of the EMW spectrum between a rectangular object with painted NTs-22I paint 6 m long, 3.4 m high, 2.6 m wide are calculated and various underlying backgrounds, between the object and the observer, in the absence and presence of an aqueous foam-aerosol mask between them. The calculation data are summarized in table 1.

The results of the calculations show that in the visible electromagnetic field, the decrease in brightness contrast between the object and the background, at different wavelengths, is up to 24%, and when using color, the corresponding background color is up to -70%.

In the infrared region of the EMW spectrum, the use of an aqueous foam-aerosol mask will reduce the temperature contrast K _ik between the heated surfaces of the object and the background, thereby changing the thermal portrait of the object; [6].

where T _about , T _f - radiation temperature of the object and background, respectively, in degrees Celsius or Kelvin.

It is known that water vapor is the main component of the atmosphere that absorbs infrared radiation [3]. To calculate the absorption of infrared radiation by water vapor, the concept of the amount of precipitated water co (measured by the thickness of the water layer in mm) is introduced, which will be obtained if, for a given section of the layer, all the water vapor contained in the atmosphere turns into water. The value of co characterizes the conditions of absorption of infrared radiation can be calculated by the formula: [3]

where T _B is the air temperature, K;

f is the relative humidity of the air (the percentage of the amount of water vapor contained in the air to the maximum amount that can be contained in saturated air at a given temperature);

e is the vapor pressure.

The values of the elasticity of saturated vapors are determined according to the table adopted in 1946 by the International Agreement as a standard [3].

The amount of precipitated water is determined by the nomogram, [3] allowing the amount of precipitated water ω to be determined from the set temperature and relative humidity values ω

The temperature of the vapor-air mixture t _cm during evaporative cooling is found from the heat balance equation [5]

where t _in - air temperature;

t _s is the temperature of the injected;

r is the heat of evaporation of water, [5];

ω is the amount of precipitated water.

The analysis of the calculation results (the calculation was carried out at a background temperature of 20 ° C) according to the above method showed that the use of an aqueous foam-aerosol mask-noise created above the surface in the infrared region of the EMW length spectrum will reduce the thermal radiation of heated sections of the object's surface relative to the background to 30% , thereby changing the thermal portrait of the object and reducing the likelihood of its destruction by the WTO.

In the radar range of the EMW length spectrum, the camouflage effect can be achieved due to the attenuation and dispersion of the electromagnetic wave of the radar irradiation of the masked object by means of guidance and destruction of the WTO, thereby reducing the effective dispersion surface (EPR) of the ground object.

According to [7], computer attenuation in fog can be expressed as follows:

where K _l the attenuation coefficient,

M is the water content of the fog.

Where, f is the frequency;

η is the gain of the dielectric constant of water.

и

- это действительная и мнимая части комплексной диэлектрической проницаемости воды [8].

and

are the real and imaginary parts of the complex dielectric constant of water [8].

The results of calculations of the EMF attenuation in the radar range of the EMW length spectrum showed that the magnitude of the EMF attenuation will depend on weather conditions, the water content of the foam-aerosol mask, the operating frequency of the range and transmitter power of the scanning object and will be at least 5-10% of the radar exposure of the object masking means of guidance and destruction of the WTO, thereby reducing the effective dispersion surface (EPR) of the object.

The analysis showed that when using a generator of placing a controlled water foam-aerosol mask-interference mask over a ground object, the means of guiding the WTO can achieve significant results in order to mask objects in the visible and IR ranges of electromagnetic waves, as well as attenuation of electromagnetic radiation in the radar range of electromagnetic waves.

Thus, in the claimed utility model, the scope of application of an aqueous foam-aerosol interference mask created above a masked ground object is expanded due to the use of automatically controlled nozzles for finely dispersed foamed liquid, or low-boiling liquid, or non-freezing liquid, or their mixture over the masked surface of an object, which allow you to create a controlled water foam aerosol mask-interference in the direction of the impact of the guidance systems of the WTO, which reduces the contrasts between masking the object and the background in the visible range and 24% in the infrared - up to 30%, in the radar range - to 10% which correspondingly reduce ESR masked ground object. The use of a water-based color scheme, corresponding to the background color, will further reduce the color contrast in the visible range of the EMW spectrum to 70%.

Information sources

1. Textbook sergeant chemical troops. Edited by Major General Melnik Yu.R. - M .: Military Publishing House, 2004.

2. X. Green, W. Lane. Aerosols - dust, fumes and mists. Ed. 2nd, Sr .: Chemistry, 1972.

3. Menshakov, Yu.K. Fundamentals of protection against technical intelligence: a training manual / Yu.K. Menshakov; under the general. red M.P. Sychev. - M.: Publishing House of MSTU. N.E. Bauman, 2014.

4. Yu.I. Weizer, G.P. Luchinsky. Masking smoke. - M., L .: GNTI chemical literature, 1947.

5. P.I. Voropay, A.A. Shlenov. Improving the reliability and efficiency of piston pumps. M., Nedra, 1980.

6. Disguise of troops and military facilities: a training manual / V.A. Krivilev, A.G. Bulakhov, S.S. Volkov. -M .: VIA, 1996.

7. Buoy C.T. et al. Comparison of attenuation of electromagnetic waves of the millimeter and infrared ranges in hydrometeors and dust // Bulletin of the Moscow Aviation Institute. 2015. - No. 84. C 123-143.

8. Antropov L.I. Theoretical electrochemistry. Textbook for chemical technologists of special higher educational institutions - 4-ed. Recycled and add. - M. Higher School, 1984.

Claims (3)

1. A generator for placing a controlled water foam aerosol formation above a ground object, comprising a liquid tank, a high pressure pump, a pipe system with periodically built-in nozzles for spraying a liquid above the object, structurally interconnected with the surface of the ground object, characterized in that the nozzles built into the pipeline include a housing with a lateral bilateral threaded connection to the pipeline, inside to the bottom of which a step-by-step electric motor is mounted, which ensures the necessary position of the nozzle nozzle, from the top onto the drive of which a part of the nozzle with the nozzle, rotatable around the horizontal axis, is hermetically jointed with the upper part of the housing, while the nozzle from the inside of the nozzle is connected by a threaded connection to the pipe channel, and from the outside has an outlet of an aqueous foaming liquid supplied to it under pressure, and for the timely creation of a foam-aerosol formation above the object, supplement the generator It is equipped with an electromagnetic valve, an integrated threaded connection between the high pressure pump and the first nozzle integrated into the piping system, whose electric drive is connected to an autonomous control system for additionally placing an aqueous foam-aerosol formation above the ground object, which includes a detection sensor laser, infrared and radar irradiation of a ground-based camouflage object, a decision-making and development device omand, control lines for autonomously providing water foam-aerosol formation in the area where the masked ground object is located at the moment of registering the threshold value of the electromagnetic field level and / or laser irradiation by the systems of guiding the ammunition to the target at the last part of its trajectory, perceived in real time by the built-in systems autonomous control of sensors for detecting signals of guided ammunition guidance means, while the listed elements are interconnected and assistance in assembly operations due to their articulation, and / or screwing, and / or riveting, and / or welding, and / or crimping, and / or soldering with the formation of a functional-structural unity of the device. 2. The generator of placing a controlled water foam aerosol formation over a surface object according to claim 1, characterized in that the length of the piping system and the configuration of its location on the surface of the masked ground object, as well as the number of nozzles periodically built into the pipeline included in the generator set depends on on the type of masked ground object and the masking method pre-selected in accordance with the design. 3. A generator for placing a controlled water foam aerosol formation over a surface object according to claim 1, characterized in that the liquid mixture poured into the tank depends on the type of the surface object being masked and the masking method pre-selected in accordance with the design.

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