RU2518389C1 - Self-propelled turret of detection, tracking and illumination of targets, of orienting and launching missiles of medium range air defence missile system - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: self-propelled turret of detection, tracking and illumination of targets, of orienting and launching missiles of medium range air defence missile system comprises a first antenna system, a radiodetector, a digital computing system, a rotary launcher with missiles, on which the gyroscopic system for measuring angles of vector, inclination and pitch is mounted, the system of navigation, topographic precise positioning and orientation, placed on the self-propelled chassis, intelligent system (IS), the laser rangefinder, the optical-electronic system connected through the interface equipment to the IS.

EFFECT: invention enables to increase the combat effectiveness of air defence missile systems under conditions of power energy suppression.

2 dwg

Description

The proposed technical solution relates to the field of defense technology, in particular to mobile anti-aircraft missile systems (SAM), and can be used to organize air defense of troops and military installations from defeating enemy air attack weapons.

In the structure of modern air defense (air defense), a radar station (RLS) is the main and almost the only source of information about the air situation of air attack weapons (ATS), and the tactical order of modern aviation, together with ballistic missiles and cruise missiles designed to break through air defense, necessarily provides fire suppression of air defense, since the radar provides control of the area of responsibility of air defense and the issuance of target designation by active-targeting radar systems - З K and fighter aircraft.

Known SAM "Krotal - NG" (see. Modern anti-aircraft and anti-missile systems and their use as part of air defense / missile defense systems (Analytical review based on materials of foreign information sources). Publishing house Scientific and Information Center GosNIIAS. M .: 2011), containing SOTS, SNR, OES and launchers for 8 VT-1 missiles in TPK, placed on one self-propelled combat vehicle. The complex has enhanced automation of combat work, survivability in the context of the use of PRR and electronic suppression, and higher productivity due to increased ammunition. The presence of two parallel operating radar detection and tracking allows the complex to simultaneously fire several targets, however, placing all systems on the same chassis requires a long deployment time of the complex, which increases the reaction time and reduces the effect of its use.

The SAMT / T SAM system is known (see Modern anti-aircraft and anti-missile systems and their use as part of air defense / missile defense systems (Analytical review based on materials from foreign information sources). Publishing House, Scientific Information Center GosNIIAS, Moscow: 2011), consisting of MF Radar of the "Arabel" all-round radar with AFAR, six launchers with eight Aster-30 missiles, command post. The complex is multi-purpose and is located on several wheeled vehicles.

Known SAM MEADS (see. Modern anti-aircraft and anti-missile systems and their use as part of air defense / missile defense systems (Analytical review of the materials of foreign information sources). Publishing house Scientific and Information Center GosNIIAS, M .: 2011), consisting of MF radar sector detection, command post and launcher with SAM RAS-3.

Known SAM SLAMRAAM (see. Modern anti-aircraft and anti-missile systems and their use as part of air defense / missile defense systems (Analytical review of materials from foreign information sources). Publishing house Scientific and Information Center GosNIIAS, M .: 2011), consisting of mobile launchers installations intended for placement, transportation, preliminary guidance and inclined launching of up to six AIM-120 V / S missiles, three-coordinate MF Sentiel AN \ MPQ-64 all-round radar, a fire control center mounted on the chassis of a Hammer automobile.

Known SAM NASAMS II (see. Modern anti-aircraft and anti-missile systems and their use as part of air defense / missile defense systems (Analytical review of the materials of foreign information sources). Publishing house Scientific and Information Center GosNIIAS, M .: 2011), consisting of mobile launchers with six missiles in transport-launch containers, MF radar AN \ MPQ-64, which provides detection, recognition and tracking of up to 60 air targets, as well as guidance on selected targets up to three missiles.

The above analogues have one or another of the following main disadvantages:

- Separate deployment of radar for detection, tracking, illumination of targets for guiding missiles and a launcher with missiles on several SAM systems;

- a significant deterioration in the tactical and technical characteristics of air defense systems in a complex jamming environment.

The closest in technical essence and the achieved result is a self-propelled firing installation for detecting, tracking, guiding and launching missiles of a medium-range anti-aircraft missile system, which ensures effective combat operation in difficult jamming conditions (see patent RU No. 2333450 IPC F41H 11/02, 2008 .), containing the first antenna system, the output of which is connected to the first input of the radar station, the first output of which is connected to the first input of the digital computer system. The first output of the digital computing system is connected to a rotary launcher with missiles, on which a gyroscopic system for measuring heading angles, roll and pitch is installed, the input of which is connected to the output of a navigation, topographic and orientation system located on a self-propelled chassis. The output of the gyroscopic system for measuring heading angles, roll and pitch is connected to the second input of the digital computer system, the second output of the digital computer system is connected to the second input of the radar station, the second output of which is connected to the input of the first antenna system, the output of the second antenna system is connected to the input of the receiving device, the output of which is connected to the first input of the intelligent system, the output of the intelligent system is connected to the third input of the digital computer system, the third output of which th is connected to the second input of the intelligent system.

The disadvantage of this technical solution is a significant deterioration in the tactical and technical characteristics of air defense systems in an interference environment.

The technical result of the invention is to improve the performance characteristics of a self-propelled firing system in an interference environment

The essence of the invention lies in the fact that the self-propelled firing system for detecting, tracking and illuminating targets, guiding and launching medium-range anti-aircraft missile systems contains a first antenna system, a radar station, a digital computer system, a rotary launcher with missiles, a gyroscopic system for measuring heading angles , roll and pitch, navigation system, topographic location and orientation, the second antenna system, receiving device, intelligent system. The output of the first antenna system is connected to the first input of the radar station, the first output of which is connected to the first input of the digital computer system, the first output of which is connected to a rotary launcher with missiles, on which a gyroscopic system for measuring heading angles, roll and pitch is connected, the input of which is connected to the output of the navigation, topographic and orientation systems located on the self-propelled chassis, and the output of the gyroscopic system for measuring heading, roll and pitch angles is connected to the second digit input new computing system, the second output of the digital computing system is connected to the second input of the radar station, the second output of which is connected to the input of the first antenna system, the output of the second antenna system is connected to the input of the receiving device, the output of the receiving device is connected to the first input of the intelligent system, the output of the intelligent system is connected with the third input of the digital computing system, the third output of which is connected to the second input of the intelligent system.

New in the proposed technical solution is the introduction of an optoelectronic system (OES), a laser range finder (LD) and a coupler (US). The output of the ECO is connected to the input of the DC, the output of the DC is connected to the third input of the intelligent system, the output of the LD is connected to the fourth input of the intelligent system.

Figure 1 shows a structural diagram of a self-propelled fire installation for detecting, tracking and illuminating targets, guiding and launching missiles of a medium-range anti-aircraft missile system.

Figure 2 presents a functional diagram of a self-propelled fire installation for detecting, tracking and illuminating targets, guiding and launching missiles of an anti-aircraft missile system of medium range.

A self-propelled firing installation for detecting, tracking and illuminating targets, guiding and launching missiles of a medium-range anti-aircraft missile complex (SOU) contains a first antenna system 1, a radar station 2, a digital computer system (CVS) 3, a rotary launcher with missiles (PU) 4, moreover, on a rotary launcher with missiles 4 there is a gyroscopic system for measuring heading angles, roll and pitch (GS) 6, which is necessary to stabilize the beam of the first antenna system 1, the second antenna system 7. On a self-propelled chassis A navigation, topographic and orientation (SNTO) system 5, a receiving device 8, an intelligent system 9, a laser range finder 10, an optoelectronic system 11, and a pairing device 12 are located.

The output of the first antenna system 1 is connected to the first input of the radar station 2, the first output of which is connected to the first input of the digital computer system 3. The first output of the digital computer system 3 is connected to a rotary launcher with missiles 4, on which a gyroscopic system for measuring heading angles and pitch 6, the input of which is connected to the output of the navigation, topographic and orientation system 5, located on the self-propelled chassis. The output of the gyroscopic system for measuring heading angles, roll and pitch 6 is connected to the second input of the digital computer system 3, the second output of the digital computer system 3 is connected to the second input of the radar station 2, the second output of which is connected to the input of the first antenna system 1. The output of the second antenna system 7 connected to the input of the receiving device 8, the output of the receiving devices 8 is connected to the first input of the intelligent system 9, the output of the intelligent system 9 is connected to the third input of the digital computing system s 3, a third output which is connected to the second input of the intelligent system 9, the output of the laser range finder 10 is coupled to a third input of the intelligent system 9, and the output of opto-electronic system 11 through the interface unit 12 is connected to a fourth input of the intelligent system 9.

Self-propelled firing installation for detecting, tracking and highlighting targets, guiding and launching missiles of the medium-range anti-aircraft missile system (SOU) works as follows.

After setting the SDA to the combat position from the navigation, topographic and orientation system 5 into the gyroscopic system for measuring heading angles, roll and pitch 6, TsVS 3, the directional angle of the SDA is entered (the angle between the longitudinal axis of the SDA and the north direction). The heading angle of the SDA is used in the gyroscopic system for measuring heading, roll and pitch 6 angles as initial conditions, and in the process of further work, the gyroscopic system for measuring heading, roll and pitch 6 angles gives the course value taking this angle into account. In CVS, the SDA course angle is used in correction sessions to calculate the angle ψ _calc , where ψ _calc is the calculated angle.

The signals from the output of the first antenna system 1 are issued to the input of the radar 2, which performs the detection, capture, tracking and illumination of targets.

After amplification and conversion, target signals are issued from the first output of the radar 2 to the first input of the DAC 3, in which the control signals of the launcher 4 are generated to generate lead angles and the formation of missile guidance signals. The generated signals are issued from the first output of the DAC 3 to the input of the PU 4.

A gyroscopic system for measuring heading angles, roll and pitch 6 is installed on the control unit 4, which is necessary to stabilize the beam of the first antenna system 1 in space when turning the control unit 4 in the horizontal plane and in the presence of rolls. The measured values of the heading angles from the exit of the gyroscopic system for measuring heading angles, roll and pitch of the angular coordinates 6 ψ _ISM , are fed to the second input of the CVC 3, where ψ _ISM is the horizontal angle of the SDA measured in the horizontal plane.

After averaging, the difference Δ = ψ _ism -ψ _{calculation is calculated} , which is used in the DAC to stabilize the beam of the first antenna system 1.

The second antenna system 7, the receiving device 8 and the intelligent system 9 provides effective combat operation of a self-propelled firing system in difficult interference conditions.

When the interference level reaches a critical value for microwave elements of radar receiving devices (the analysis of the interference level is carried out using an intelligent system), the intelligent system generates a command to enable the target detection and tracking mode using an optoelectronic system and measure the distance to the target using a laser rangefinder.

IP training is carried out using well-known methods and methods of countering interference in radar (see Yudin L.M., Fomichev K.I. Radio-electronic countermeasure systems. Storing high-frequency signals. - Electronics, NTB, 1999, Vakin S.A., Shustov L. .N. Fundamentals of electronic warfare.VVIA named after Prof. N.E. Zhukovsky, 1998, Paly A.I. Radioelectronic warfare. - M.: Military Publishing, 1981, Vakin SA, Shustov L.N. Fundamentals of radio countermeasures and of electronic intelligence. - M .: Sov. radio, 1968., Tuzov GI. Immunity of radio systems with complex signal. Ami. - M .: Radio and communications, 1985, Protection against radio interference, edited by M.V. Maksimov, M .: Soviet radio, 1976, Gutkin, L.S., Theory of optimal methods of radio reception during fluctuation interference. M .: Sov. Radio, 1972, etc.), the algorithms of various methods and methods of protection against various classes of interference are stored in the digital computer and are turned on by a command from the IC.

It is known (see Perunov Yu.M., Fomichev K.I., Yudin L.M. Radio-electronic suppression of information channels of weapon control systems M .: "Radio Engineering", 2003. - pp. 26-29) that the basis of methods of radio-electronic suppression (REP) Radar SOU constitute active and passive interference, aimed at creating a masking or misinforming effect. In addition to them, the main REP methods include methods of power energy suppression designed to disable certain elements of receiving devices, as well as methods of environmental impact, in which radio signals of suppressed radars propagate, distortion of the shape of the sounding and reflected from the object signals that attenuate the power of the probing and reflected signals; methods to reduce the effective scattering area (EPR) of targets.

Thus, the proposed self-propelled firing installation for detecting, tracking and illuminating targets, guiding and launching medium-range anti-aircraft missile systems can provide effective combat operations under conditions of power energy suppression designed to disable microwave elements of radar receiving devices without reducing the main tactical and technical characteristics of the SDA.

Claims (1)

Self-propelled firing system for detecting, tracking and illuminating targets, guiding and launching missiles of a medium-range anti-aircraft missile system, comprising a first antenna system, a radar station, a digital computer system, a rotary launcher with missiles, a gyroscopic system for measuring heading angles, roll and pitch, a navigation system , topographic location and orientation, the second antenna system, receiver, intelligent system, and the output of the first antenna system is connected to the first input of the radio a location station, the first output of which is connected to the first input of a digital computer system, the first output of which is connected to a rotary launcher with missiles, on which a gyroscopic system for measuring heading angles, roll and pitch is installed, the input of which is connected to the output of the navigation, topographic and orientation system, located on a self-propelled chassis, and the output of the gyroscopic system for measuring heading, roll and pitch angles is connected to the second input of the digital computer system, the second digital output will calculate the system is connected to the second input of the radar station, the second output of which is connected to the input of the first antenna system, the output of the second antenna system is connected to the input of the receiving device, the output of the receiving device is connected to the first input of the intelligent system, the output of the intelligent system is connected to the third input of the digital computing system, the third output of which is connected to the second input of the intelligent system, characterized in that a laser range finder is introduced, the output of which is connected to the third input Predictive systems, opto-electronic system which is connected via an interface to a fourth input of the intelligent system.

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