RU114770U1 - AUTOMATIC COMPLEX OF ACTIVE INDIVIDUAL PROTECTION OF UNIVERSAL PURPOSE - Google Patents

Abstract

1. An automatic complex of active individual protection, containing radar means of detecting and identifying targets, radar means of tracking targets and guiding missiles, television-optical means of tracking targets and equipment for launching automation, characterized in that it additionally includes a passive millimeter-wave radar channel, ensuring the detection of ammunition flying up to the object of protection by their own radio-thermal radiation, the all-weather use of the complex and the ability to work in conditions of intense radio and / or thermal counteraction, a heat direction finder that provides a rough determination of the coordinates of an approaching ammunition, a system for accurate determination of coordinates operating in the near infrared range at illumination of an approaching munition by infrared radiation of a laser illumination with a strobing unit, a visible detection channel, an ultraviolet detection channel, a control electronics I am the vehicle and the coordinator of the anti-missile missile, connected to its automatic control system and issuing signals proportional to the azimuth, elevation and range to the incoming ammunition. ! 2. Automatic complex of active personal protection according to claim 1, characterized in that the system for precise determination of coordinates provides information about the azimuth and angle of the approaching munition. ! 3. Automatic complex of active personal protection according to claim 1, characterized in that the system for accurate determination of the coordinates of the incoming ammunition operates in the infrared range. ! 4. Automatic complex of active

Description

The inventive utility model relates to complexes (systems) of active protection (SAZ) of various objects from flying ammunition (means of destruction), and specifically to complexes (systems) of active individual protection (KAIZ, SAIZ) of stationary and moving objects of land, sea, air and space-based from flying ammunition, regardless of how they are guided.

Known systems for active individual protection of tanks and other armored vehicles, for example: “Drozd” and “Drozd-2” of the T-55AD tank, “Arena” of the T-72, T-80, T-90 tanks (Russia); Barrier of the T-84 tank and other armored vehicles (Ukraine); EFA of the T-72M4 tank (Czech Republic); "Slide" of the company "Rockwell International Corp. Tactical Systems Division", CAZ "IDS", "APS" and "FSAP" of the Abram tank, infantry fighting vehicle (BMP) M2AZ, armored personnel carrier (BTR) AAAV and other promising models of armored vehicles technicians (USA), ASPRO-A for the Merkava-4 tank (Israel), etc. [1-13]. They include a radar station for detecting ammunition approaching the object of protection and a system for firing special shells that explode when approaching flying ammunition, creating a cloud of fragments that destroy or greatly weaken the effect of the ammunition, or a system of non-firing protective charges (in the SAZ Zaslon). Some Israeli SAZ armored vehicles include electron-optical sensors mounted on the upper surface of the vehicle body in order to ensure circular detection of flying ammunition.

The SAIZ aircraft and helicopters of the LA1RCM AN / AAQ-24V type of the Northrop-Grumman company and the DIRCM (Nemesis) system, developed by Northrop-Grumman together with BAE Systems (USA) and additionally are known equipped with a channel for detecting flying ammunition in the infrared range.

SAIZ ships are known to be equipped with radar detection and tracking means and television-optical means of threat tracking, for example, the Klinok shipborne self-defense complex, Russia [5].

The well-known tactical missile defense system for the protection of areal objects "Arrow" (the company "IAI", Israel), allowing to intercept tactical ballistic missiles such as "Scud", "Shihab-3", "Shihab-4", "No-Dong". It includes, in particular, a radar station (radar) of early detection, operating in the L-band, and a missile defense with an optoelectronic sensor.

The disadvantages of these complexes and systems of active protection of objects are: short detection ranges; insufficient sizes of protection sectors; the absence in the composition of such complexes of subsystems of accurate determination of coordinates; as the main detection system, radar stations are used that work in an active mode and therefore do not allow efficient operation in conditions of intense radio resistance; the inability to obtain additional signs of detectable threats due to work in other spectral ranges.

The closest in technical essence to the claimed utility model is the ship’s multi-functional control system of the domestic ship’s self-defense complex “Blade” [5]. The disadvantages of the prototype indicated above.

The objective of the utility model is to ensure reliable detection of ammunition flying up to the object of protection at ranges up to 100 km, accurate determination of its coordinates at ranges of at least 15-20 km and ensuring the launch of active protection means (anti-missiles, traps from heavy-duty fabric, etc.) for its neutralization (destruction, distorting changes in its trajectory, etc.) in conditions of intense radio interference.

The technical result is achieved due to the additional introduction into the composition of the automatic complex of active individual protection (AKAIZ), containing radar means for detecting and identifying targets, radar means for tracking targets and guiding missiles, television-optical means for tracking targets and start-up automation equipment, a passive radar channel of the millimeter range that ensures the detection of flying ammunition by their own thermal radiation, the suitability of the complex and the ability to work in conditions of intense radio and / or thermal counteraction; a direction finder providing a rough determination of the coordinates of the flying munition; the system of accurate determination of coordinates (STOK), operating in the near infrared range when illuminating an approaching munition with near infrared radiation of a backlight laser with a gating unit; visible detection channel; ultraviolet channel detection; a control electronic computer (computer) and a missile coordinator associated with its automatic control system (ACS) and issuing signals proportional to azimuth, elevation angle and range to the approaching munition.

The inventive utility model is illustrated by graphic materials:

figure 1 - enlarged functional diagram of a complex of active individual protection;

figure 2 is a detailed functional diagram of the complex.

Figure 1 shows the main channels of the complex and the connections between them: 1 - passive radar channel of the millimeter range; 2 - heat pegging agent; 3 - system for the exact determination of coordinates; 4 - infrared laser illumination; 5 - visible channel; 6 - ultraviolet channel, operating in the range of 0.32-0.4 microns; 7 (7 ₁ , 7 ₂ , 7 ₃ , 7 ₅ , 7 ₆ ) - signal processing units, respectively, of the passive radar channel of the millimeter range 7 ₁ , heat transfer agent 7 ₂ , accurate coordinate system 7 ₃ , visible channel 7 ₅ , ultraviolet channel 7 ₆ ; 8 - gating unit; 9 - control computer; 10 - missile coordinator; 11 - self-propelled guns anti-missile.

Figure 2 shows a detailed functional diagram of a complex of active personal protective equipment for universal use. It includes the following elements: 12 - antenna passive radar channel of the millimeter range; 13 - antenna drive; 14 - millimeter range receiver; 15 - gain block; 16 - optical system of the direction finder with a circular view; 17 - photodetector (FPU); 18 is a multi-element infrared radiation detector operating in the range of 3-14 microns; 19 - pre-amplifiers; 20 switch; 21 - deep cooling system of the receiver 18; 22 - STOK optical system; 23 - electron-optical Converter (EOP); 24 - transfer optics; 25 - a matrix of receivers with charge-coupled (CCD); 26 - fairing of the missile defense coordinator; 27 - optical system coordinator; 28 - FPU coordinator; 29 - multi-element infrared radiation receiver; 30 - pre-amplifiers; 32 - signal processing unit of the stationary coordinator; 33 - deep cooling system FPU coordinator; 34 - optical system of the laser backlight; 35 - power source of the laser backlight; 36 - optical system of the visible channel; 37 - FPU on the CCD; 38 - optical system of the ultraviolet channel; 39 - image intensifier tubes of the ultraviolet range; 40 - optics of ultraviolet channel transfer; 41 is a CCD matrix.

Passive radar channel 1 (figure 1) is designed to detect flying ammunition at long ranges (up to 150 km) and operates in the frequency range of 26-40 GHz (wavelength range - from 7.5 to 11.5 mm). In the signal processing unit 7 ₁ , a signal is generated about the direction of attack on the protected object within the radiation pattern of the receiving antenna ~ 10 × 10 °, in the range of azimuthal angles - 0-360 ° and with an angular accuracy of 2.5 °, which, after appropriate scaling, arrives at host computer 9 to generate a preliminary signal about the azimuth and approximate range to the approaching threat. This signal is used to orient the direction finder 2 in the direction of the approaching munition, which, accordingly, previously orients the STOK 3. STOK 3 gives the exact coordinates and the distance to the approaching ammunition through the signal processing unit 7 ₃ (Fig. 1) to the control computer 9, then to a signal processing unit 32 (FIG. 2) of a missile defense coordinator 10 and then to its control system 11 to launch a missile defense and destroy the threat. The channel provides a detection range of approaching ammunition with an effective scattering surface of 1 m ² to 150 km.

The direction finder 2 (Fig. 1) consists of an optical system 16 (Fig. 2) FPU 17 containing the sensitive elements of the infrared radiation receiver 18 with pre-amplifiers 19 and a switch 20. Signals about the azimuth and elevation angle of the approaching munition are fed to the signal processing unit 7 ₂ and then to the host computer 9.

The system of precise determination of coordinates 3 is triggered by a signal from the host computer 9. At the same time, the backlight laser 4 is turned on. STOK 3 consists of an optical system 22, electron-optical converters 23, transfer optics 24, a matrix of charge-coupled receivers (CCD) 25, and a processing unit signals 7 ₃ and gives from the signal processing unit 7 ₃ to the control computer 9 a signal about the direction of movement of the approaching weapon with the exact value of the coordinates relative to the optical axis STOK 3 and the distance to the ammunition. The STOK 3 optical axis is oriented toward the target by signals from the heat direction finder 2 through its 7 g signal processing unit and control computer 9. In STOK 3 of the claimed complex, four receiving devices are provided, which are used with a third generation image intensifier tube (with gallium arsenide photocathode) 23, each of which covers the field of view in azimuth and elevation 90 ° × 90 °. STOK 3 operates according to the energy brightness of the target, which is provided by laser illumination 4. The backlight 4 operates in a pulsed mode, and its power source 35 is synchronized with the operation of the image intensifier tube 23, which also operates in a pulsed mode, by means of the gating unit 8. The signal from STOK is supplied to the host computer 9 after it is established that the flying ammunition is sent to the protected object.

Computer 9 generates control signals for the coordinator 10, consisting of a cowl 26, an optical system 27, a photodetector 28, including a multi-element optical radiation receiver 29 operating in the infrared range, preamplifiers 30 and a switch 31, a signal processing unit 32, and a deep cooling 33. The coordinator 10 is triggered by signals from the host computer 9 and displayed on the operating mode. After capturing the flying ammunition from the protected object, a missile launched by self-propelled guns 11 is launched to destroy the ammunition.

The visible 5 and ultraviolet 6 channels of detection of the active personal protective equipment complex are designed to obtain additional information about the approaching weapon and serve to increase the likelihood of detection and accurate determination of coordinates when working in the lower (from high altitudes) and / or in the upper hemisphere.

The visible channel 5 operates in the visible range of optical radiation (0.38-0, 78 μm) and includes an optical system 36, an FPU on a CCD array 37, and a signal processing unit 7 ₅ .

The ultraviolet channel 6 operates in the wavelength range of 0.32-0.4 microns. It includes an optical system 38, an image intensifier tube 39 operating in the ultraviolet range of optical radiation, image transfer optics 40, a CCD matrix 41, and a signal processing unit 7 ₆ .

The use of these channels is especially effective for the protection of aircraft outside the lower atmosphere and in the absence of clouds, and the ultraviolet channel - and on space routes, to protect space objects.

The introduction to the active individual protection complex of a passive radar detection channel, a heat direction finder, and a system for accurately determining the coordinates of approaching weapons, based on the use of pulsed electron-optical converters with synchronous pulsed laser illumination of detectable weapons, as well as visible and ultraviolet channels, makes it possible to solve the problem models - provide almost 100% probability of detection and accuracy of determination of coordination to avoid slip in heavy radio and / or heat resistance.

The inventive utility model can be used to protect warships, offshore platforms, coastal infrastructure, aircraft and space objects, air defense systems, as well as any other mobile and stationary land, sea, air and space-based objects.

Literature

1.http: //com/defence-spase/missiles/slide/slide.html.

2. http://armor.kiev.ua/ptur/azt/T-55 drozd.html.

3. http.7 / www. army-guide, com / rus / article / article_1484.html.

4. http://www.army-guide.com/rus/article/article _ 1575-html.

5. Ship anti-aircraft missile systems air defense of the Navy. - http://www.rusarmv.com/pvo/pvo_vmf/zrk_osa-m.html.

6. Pat. RU 2280836. - Prior. 12/08/2004.

7. Pat. RU 2141094. - Publ. 11/10/1999.

8. Application RU 2008103631. - Publ. 08/10/2009.

9. Application RU 2006140128. - Publ. 05/20/2008.

10. Application RU 2004135961. - Publ. 05/20/2006.

11. Pat. RU 69222. - Publ. 12/10/2007.

12. Application 2000124114. - Publ. 08/10/2002.

13. Pat. RU 2335728. - Prior. 01/09/2007.

Claims (15)

1. An automatic complex of active personal protection, containing radar means for detecting and identifying targets, radar means for tracking targets and guiding missiles, television-optical means for tracking targets and starting automation equipment, characterized in that it also includes a passive radar channel of the millimeter range, providing detection of ammunition flying up to the object of protection by their own thermal radiation, all-weather use complex and the ability to work in conditions of intense radio and / or thermal counteraction, a heat finder that provides rough determination of the coordinates of the approaching ammunition, a system for accurate determination of coordinates, operating in the near infrared range when the approaching ammunition is illuminated with infrared radiation from the backlight laser with a gating unit, visible detection channel , an ultraviolet detection channel, a control computer and a missile coordinator associated with its automatic automatic control and emitting signals into it proportional to the azimuth, elevation and range to the approaching ammunition. 2. The automatic complex of active individual protection according to claim 1, characterized in that the system for the exact determination of coordinates provides information about the azimuth and elevation angle of the approaching munition. 3. The automatic complex of active individual protection according to claim 1, characterized in that the system for accurately determining the coordinates of the flying munition works in the infrared range. 4. The automatic complex of active individual protection according to claim 1, characterized in that the system for accurately determining the coordinates of the flying ammunition operates in a pulsed mode. 5. The automatic complex of active individual protection according to claim 1, characterized in that the system for accurately determining the coordinates of the approaching ammunition works by illuminating the approaching ammunition with laser radiation. 6. The automatic complex of active individual protection according to claim 1, characterized in that the laser illuminating the approaching ammunition operates in the infrared range. 7. The automatic complex of active individual protection according to claim 6, characterized in that the laser illuminates the approaching munition with infrared radiation in a pulsed mode. 8. The automatic complex of active individual protection according to claim 7, characterized in that the pulsed mode of operation of the infrared laser is provided by a gating unit. 9. The automatic active personal protection complex according to claim 8, characterized in that the gating unit sets the pulse mode of the backlight laser by the signals of the host computer. 10. An automatic complex of active personal protection according to any one of claims 1 to 9, characterized in that the system for accurately determining the coordinates of the flying munition and the laser of illumination work synchronously. 11. An automatic complex of active personal protection according to any one of claims 1 to 9, characterized in that the system for the exact determination of coordinates provides information about the range to the approaching ammunition. 12. The automatic complex of active individual protection according to claim 1, characterized in that the missile coordinator is associated with its automatic control system. 13. The automatic complex of active individual protection according to claim 1, characterized in that the missile coordinator gives out signals to its automatic control system that are proportional to the azimuth, elevation and range to the approaching munition. 14. The automatic complex of active individual protection according to claim 1, characterized in that the missile coordinator can be movable or motionless. 15. The automatic complex of active personal protection according to claim 1, characterized in that it provides a practically 100% probability of detecting flying ammunition in conditions of radio and / or thermal resistance.