RU2477832C2 - Anti-ship missile - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: anti-ship missile contains control system with inertial guidance system unit, missile internal control unit and target coordinator, ranging computer, threshold device, defensive payload with safety and arming unit, protective unit of top semi-sphere with beam pattern directed towards missile top semi-sphere and with carrying frequency of transmitted pulses and periods of their coming corresponding to the carrying frequency and period of transmitted pulses coming of anti-ship missile self-homing head, ejected dipole scatterers unit, unit OR and unit AND. Ejected dipole scatterers unit is made as a system of pyro-energy sensors the working surfaces of which are directed to front top semi-sphere. The inlet of ejected dipole scatterers unit is connected to the output of ranging computer through threshold device, unit OR, unit AND and top semi-sphere protective unit. The second input of unit OR is connected to the output of inertial guidance system, the second input of unit AND is connected to the output of missile internal control unit. Pyro-technical composition of pyro-energy sensors has dipole scatterers, the coating of which is made of high-melting metals. Protective unit of top semi-sphere is located in payload. Ejected dipole scatterers unit is located in the recess made in weapon body. Increase of efficiency of air defence zones overcoming by anti-ship missiles and effective use of released part of internal volume and mass of the missile in nuclear-powered version.

EFFECT: increase of efficiency of air defence zones overcoming by anti-ship missiles.

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Description

The invention relates to weapons and guidance systems, can be used in anti-ship strike weapon systems of submarines, surface ships and aviation.

Known anti-ship missiles containing a control system with an internal missile control unit and a target coordinator, a range calculator and a warhead with a safety-executive mechanism, the input of which is connected to the target coordinator's output through a range calculator [see Norman Friedman: The Naval Institute Guide to World Weapons Systems 1997-1998, pp. 242-243, English].

In the analog solution, the signal from the range calculator enters the safety-executive mechanism of the missile warhead. If the values of the range to the target become negative, which occurs when the missile misses the target, the safety-executive mechanism generates a signal to undermine the warhead. In the calculator, the distance to the target is calculated both from information from the target coordinator using mainly range measurement by the radar method, and by calculation if the information from the target coordinator ceases to come as a result of a homing failure in close proximity to the target, or “suppression” of the target coordinator by means of radio engineering counteraction. This ensures an increase in the efficiency of hitting a target with an anti-ship missile in a variant of nuclear equipment. So if the missile misses less than the radius of the target’s defeat, the latter can be hit by the implementation of non-contact detonation of the warhead of the missile, when the range to the target becomes negative.

An advantage of such missiles is also their autonomous functioning on the flight path to the target, which frees the missile carrier from maintaining radar contact with the target after the missiles are launched. This ensures high combat stability of the carrier, especially a submarine, which can launch such missiles from an underwater position. However, analog solutions have a number of disadvantages that reduce the effectiveness of their combat use against targets that have means of fire and radio technical countermeasures of a missile strike. In addition, the target coordinator, made primarily on the basis of the radar guidance method, has a large effective reflection area, which greatly facilitates the guidance of anti-missile systems with radar homing heads and increases the efficiency of missile damage by the striking elements of anti-missile warheads. The disadvantage of analog solutions is also the irrational use of the released part of the internal volume and mass of the rocket in the variant of nuclear equipment. Nuclear ammunition is significantly lighter than the corresponding conventional warhead, therefore, the centering of the rocket in the variant of nuclear equipment is carried out by placing ballast cargo in the ammunition that compensates for the difference in the mass of the nuclear ammunition relative to the mass of the interchangeable conventional warhead.

The noted drawbacks were partially eliminated in an anti-ship missile containing a detachable warhead, a control system with an inertial guidance system, an internal missile control unit and a target coordinator, a range calculator, a warhead with a safety-executive mechanism, the input of which is connected to the target coordinator's output through a range calculator , threshold device, OR block, separation mechanism of the combat unit, the input of which is connected to the output of the range calculator through the threshold device and bl ok OR, the second input of which is connected to the output of the rocket’s internal control unit [RF Patent No. 2186331 7 F42B 15/00] - prototype.

In the prototype solution, the separation of the detachable warhead, made in the form of an aviation submarine missile, is carried out in the target area to the short-range fire range of the target ship. In this case, the command to separate the combat unit is formed either upon the achievement of the established range to the target, or upon damage to the rocket. The short range of the underwater missile and its high speed ensure the difficulty of counteracting it with anti-submarine defense means. The continuation of the movement towards the target of the missile and detachable warhead after separation of the warhead from the missile in various physical media significantly increases the probability of not hitting at least one of the indicated means of hitting the target with fire means of counteracting the target.

However, the shortcomings associated with the interception of an anti-ship missile with long-range fire weapons, due to the large effective reflection area of the target coordinator, made mainly on the basis of the radar guidance method, and the irrational use of the released internal volume and mass of the rocket in the variant of nuclear equipment, are not eliminated by the prototype solution.

The objective of the claimed invention is to eliminate the noted drawbacks, namely, increasing the efficiency of overcoming anti-ship missiles of the air defense zones and the rational use of the released part of the internal volume and mass of the rocket in the variant of nuclear equipment.

The technical result is achieved by the inclusion of new units and a different connection between the units in the anti-ship missile containing a control system with an inertial guidance system unit, an internal missile control unit and a target coordinator, a range calculator, a threshold device and a warhead with a safety-executive mechanism, the input of which is connected to the output of the target coordinator through the range calculator, which consists in the fact that an additional protection block for the upper hemisphere with a directional diagram is additionally introduced into it a tee facing the upper hemisphere of the rocket, and with the carrier frequency of the probe pulses and their repetition period corresponding to the carrier frequency and the period of repetition of the probe pulses of the homing anti-ship missile, a block of shot dipole reflectors, made in the form of a system of pyroenergy sensors whose working surfaces are directed to the front upper a hemisphere, an OR block, and an And block with two inputs each, while the input of the block of shot dipole reflectors is connected to the output of the range calculator h cut the threshold device, the OR block, the And block, and the upper hemisphere protection block, the second input of the OR block is connected to the output of the inertial guidance system, the second input of the block And is connected to the output of the rocket’s internal control unit, and dipole reflectors are introduced into the pyrotechnic composition of the pyroenergy sensors, the coating of which is made of refractory metals, the protection block of the upper hemisphere is located in the warhead, and the block of shot dipole reflectors is placed in a recess made in the shell of the ammunition.

The idea of the proposed technical solution is to create, when approaching an anti-ship missile, an anti-aircraft missile or an anti-missile anti-missile region, increasing the “radio reflective length” of the anti-ship missile and thereby causing premature operation of the anti-missile radio fuse. Since the radiation pattern of the anti-missile fuse and the delay time of its operation are strictly matched with the expansion zone of the striking elements [see Combat aircraft equipment: Aircraft armament / D.I. Gladkov, V.M. Baluev, P.A. Sementsov and others; Ed. D.I. Gladkova. - M.: Military Publishing House, 1987, p. 58-62], the premature operation of a radio fuse of a missile defense can provide a significant reduction in the likelihood of an anti-ship missile being hit by the damaging elements of the anti-missile warhead.

We show the materiality of the distinguishing features.

The introduction into the ammunition of an anti-ship missile of the upper hemisphere protection block with a radiation pattern facing the upper hemisphere of the rocket is a new solution. It provides the possibility of detecting an approach to a missile, and also provides a more rational use of the released internal volume and mass of the rocket in the variant of nuclear equipment. In addition, it ensures that the protection block of the upper hemisphere from the underlying surface does not fire when the anti-ship missile flies at an extremely low altitude (5 m above the surface of the waves).

The implementation of the protection block of the upper hemisphere with the carrier frequency of the probe pulses and their repetition period corresponding to the carrier frequency and the period of the probe pulses of the homing anti-ship missile, is a new solution. It makes it impossible to select missiles in the variant of nuclear equipment by radiation of the upper hemisphere protection block in a mixed salvo of anti-ship missiles.

The introduction into the ammunition of an anti-ship missile of a block of shot-off dipole reflectors, made in the form of a system of pyroenergy sensors, whose working surfaces are directed to the front upper hemisphere, is a new solution. It provides the creation of a radio-reflective region, increasing the "radio-reflective length" of the anti-ship missile and thereby causing premature operation of the anti-missile radio fuse. In addition, pyroenergy sensors, which, in comparison with other mechanisms, have the highest power-to-mass ratio, ensure that, when placed in the munition, they minimize the internal size and weight of the latter.

The implementation of the shell of the ammunition with a recess, and the placement of the block of shot dipole reflectors in the recess, is a new solution. It provides explosion-proof ammunition, since pyroenergy sensors are located outside the ammunition shell. In addition, at reduced levels of ammunition readiness, the unit of shot dipole reflectors can be stored separately from the ammunition, and its replacement after the expiration of the warranty period can be carried out without undocking the ammunition body.

The introduction of the And block into the anti-ship missile with its link to the missile’s internal control block is a new solution. It ensures the elimination of false triggering of the unit of shot radar reflectors during transcendental flight conditions of the rocket, when due to the large roll of the rocket the radiation pattern of the block can “touch” the underlying surface.

The introduction of an OR block into its anti-ship missile with its link to an inertial guidance system block is a new solution. It provides the possibility of the functioning of the block of shot radar reflectors in the variant of shooting at coastal objects when it is impossible to select a radio-contrast target for the target coordinator.

The essence of the proposed technical solution is illustrated by the drawing, which shows a diagram of the proposed anti-ship missiles.

Anti-ship missile contains:

block 1 - anti-ship missile body,

block 2 - control system,

block 3 - block internal control of the rocket,

block 4 - block inertial guidance system,

block 5 - the coordinator of the goal,

block 6 - range calculator,

block 7 - threshold device,

block 8 - warhead,

block 9 - safety-actuating mechanism.

Blocks 1-9 characterize the prototype. In addition to blocks 1–9, new blocks were introduced into the anti-ship missile.

Block 10 - protection block of the upper hemisphere. Similar devices are widely used in military aviation to protect the rear hemisphere of an aircraft. They inform the pilot about the threat of attacking the aircraft from the rear. Block 10 can be made similar to a missile anti-fuse, differing only in longer range, since it does not impose requirements on matching its range with the strike area of the striking elements and the detection of an approaching missile occurs against a clear sky, and not against the underlying surface, as this occurs when a missile intercepts a low-flying target.

Block 11 is a block of shot dipole reflectors. Methods for creating a cloud of dipole reflectors are known [see Military aviation equipment: Radio-electronic equipment / V.A.Boldin, G.I. Gorgonov, V.D.Konovalov and others; Ed. V.M.Sidorina. - M .: Military Publishing House, 1990, pp. 258-261]. In the proposed technical solution, the unit of shot dipole reflectors is made in the form of a system of pyroenergy sensors, the working surfaces of which are directed to the front upper hemisphere. Pyroenergy sensors are widely used in rocket and space technology [see Brower: Pyrotechnic devices for spacecraft / Issues of rocket technology No. 10 (178), ed. "World", M., 1969, p. 56].

Block 12 - a recess in the housing of the warhead 8.

Block 13 - OR block with two inputs.

Block 14 - block And with two inputs.

The proposed anti-ship missile operates as follows. In flight of rocket 1 to the target, the inertial guidance unit 4 of the rocket 2 control system controls the course and direction. At the same time, the internal control unit 3 of the rocket, according to the integrated program, interrogates the rocket units for their serviceability. At the set range to the target, determined by reckoning, the coordinator of target 5 is turned on, which determines the angular position of the target relative to the axis of the rocket and gives an error signal to the control system 2 for guidance to the target. In addition, based on measuring the propagation time of radiation from the coordinator of the target 5 and vice versa, a signal containing information about the distance to the target is generated at the output of the coordinator of the target. This signal is fed to the input of the range calculator 6, at the output of which a signal is formed whose amplitude is proportional to the range to the target. From the output of the range calculator 6, the signal is fed to the input of the safety-executive mechanism 9 of the warhead 8 of the rocket. If the range to the target becomes negative, which corresponds to the case of a missile flying past the target without contact with it, then the safety-executive mechanism 9 generates a command to detonate the warhead 8. From the output of the range calculator 6, the signal goes to the input of the threshold device 7, at the output of which The prototype generates a signal to separate a detachable warhead.

This is how the prototype works. Anti-ship missile in the proposed technical solution operates as follows.

If the range to the target becomes less than the value set in the threshold device 7, a signal is generated at the output of the latter, which is fed to the first input of the OR 13 block. From the output of the OR 13 block, this signal is fed to the first input of the And 14 block. If the output of the internal control unit 3 if the missile signal is present, which corresponds to the case of operational condition of the rocket assemblies, then a signal is present at the second input of the And 14 block, and therefore the signal from the output of the And 14 block goes to the input of the upper hemisphere protection block 10. When a missile appears in the de action of the protection unit of the upper hemisphere 10 at the output of the latter, a signal is generated that enters the input of the unit of the shot dipole reflectors 11. Block 11 is triggered, forming in the nose of the anti-ship missile a radio-reflective region that increases the “radio-reflective length” of the anti-ship missile and thereby causes premature operation of the radio fuse missiles.

If the anti-ship missile is used in the variant of firing at a non-radio-contrasting coastal object, then at a specified range to the target, determined by reckoning, a signal is generated at the output of the inertial guidance system 4, which is fed to the input of the protection unit of the upper hemisphere 10 through the second input of the OR block 13 and the first input of block And 14.

Thus, based on the analysis of the structure and functioning of the scheme of the proposed technical solution, we can conclude that the anti-ship missile in which this solution is implemented has advantages that meet the goal of increasing the efficiency of anti-ship missiles in overcoming air defense zones and the rational use of the released part of the internal volume and mass missiles in a variant of nuclear equipment.

Claims (1)

An anti-ship missile containing a control system with an inertial guidance system unit, an internal missile control unit and a target coordinator, a range calculator, a threshold device and a warhead with a safety-executive mechanism, the input of which is connected to the target coordinator through a range calculator, characterized in that an additional upper hemisphere protection unit with a radiation pattern facing the upper hemisphere of the rocket and with a carrier frequency of probing pulses and Following them, corresponding to the carrier frequency and the period of the probing pulses of the anti-ship missile homing head, a block of shot dipole reflectors made in the form of a system of pyroenergy sensors, the working surfaces of which are directed to the front upper hemisphere, the OR block, and the AND block with two inputs each, with the input block shoot dipole reflectors connected to the output of the range calculator through a threshold device, block OR, block And and the protection block of the upper hemisphere, the second input block OR is connected to the output of the inertial guidance system, the second input of the And block is connected to the output of the rocket’s internal control unit, and dipole reflectors are introduced into the pyrotechnic composition of the pyroenergy sensors, the coating of which is made of refractory metals, the protection unit of the upper hemisphere is placed in the warhead, and the block of shot dipole reflectors placed in a recess made in the shell of the ammunition.