RU2186331C2 - Anti-shipping missile - Google Patents

Abstract

FIELD: armament and systems of its guidance, applicable in striking anti-shipping armament complexes of submarines, surface ships and aviation. SUBSTANCE: in the known anti-shipping missile, having a control system with a missile monitor unit and a target seeker, range computer and a warhead with a safety- actuator mechanism, whose input is connected to the output of the target seeker via the range computer, additionally introduced are a detachable war unit made in the form of an aircraft underwater rocket containing an inertial control system, propulsion system, warhead with a safety-actuator mechanism, NOT unit and an AND unit, threshold device, or unit and a war unit separation mechanism. The input of the war unit separation mechanism is connected to the output of the range computer via the threshold device and the OR unit, whose second input is connected to the output of the missile monitor unit. The input of the inertial control system is connected to the output of the war unit separation mechanism via the NOT unit and the AND unit, whose second input is connected to the target seeker output, the input of the safety-actuator mechanism of the war unit separation mechanism via the propulsion system. EFFECT: enhanced efficiency of target hitting in the conditions of its fire and radio-engineering counteraction. 1 dwg

Description

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

 Known anti-ship missiles containing a control system with a coordinator of the target, a warhead with a contact fuse and an engine. A representative of this type of missile is the Mayverik rocket [see Combat aircraft equipment: Aviation weapons / D.I. Gladkov, V.M. Baluev, P.A. Sementsov et al. Ed. DI. Gladkova. - M .: Military Publishing House, 1987, pp. 52-53, 62].

 The main advantage of such missiles is their autonomous functioning on the flight path to the target, which frees the missile carrier from maintaining radar contact with the target after launching the missiles. 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.

 When a missile misses the target, the latter remains intact even if the miss is less than the radius of the target’s defeat by the damaging factors of the missile’s warhead. The likelihood of such a miss for a target such as a surface ship with its developed superstructures and corner reflectors installed over the affected contour of the ship is very high.

 The target remains unaffected even in the event of a missile damage by the target's air defense weapons. In addition, in the event of a malfunction in the missile control system along its flight path, the missile becomes dangerous for its forces.

 The noted drawbacks were partially eliminated in an anti-ship missile, containing a control system with an internal missile control unit and a chain coordinator, a range calculator and a warhead with a safety-executive mechanism, the input of which is connected to the output of the chain coordinator through a range calculator [Normah Friedman: The Naval Institute Guide to World Wearoms Systema 1997-1998, pp. 242-243, English] - prototype.

 In the prototype solution, the signal from the range calculator enters the safety-executive mechanism of the missile warhead. If the values of the distance to the chain become negative, which occurs when the missile misses the target, the safety-executive mechanism generates a signal to undermine the warhead. In the range calculator, the distance to the target is calculated both from information from the circuit coordinator using mainly measurements to the target and vice versa, and by calculation if the information from the circuit coordinator ceases to come as a result of either a homing in the immediate vicinity of the circuit and “suppression” of the circuit coordinator radio engineering countermeasures. This provides an increase in the efficiency of a chain lesion. So, with a missile missile smaller than the radius of the chain damage, the latter can be hit due to the implementation of a non-contact explosion of the warhead of the rocket. The inclusion of an internal missile control unit in the missile ensures increased safety of the combat use of anti-ship missiles due to the possibility of implementing missile self-destruction regime on missiles along its flight path when malfunctions occur in its nodes or deviations from the normal functioning of its control system.

 However, the technical solution does not eliminate the disadvantages associated with the impossibility of hitting a target when a rocket is damaged by means of fire countermeasures of a target by a missile strike.

 Especially dangerous for such missiles are short-range and short-range air defense weapons. When approaching the target of a missile having significant dimensions, these means create a continuous field of damaging elements ("fire curtain"), overcoming of which with a missile leads to the defeat of the latter with a high probability. The disadvantages associated with the non-hit of the target during missed missiles are only partially eliminated in the indicated technical solution: when the miss is greater than the radius of the target’s defeat by the damaging factors of the missile’s warhead, the target remains unaffected even if the warhead of the missile is not contacted. In addition, for the prototype solution, there is another drawback associated with the excessive cost of missiles. The fact is that such missiles have a large flight range, which, in the absence of target designation with external means, cannot be fully realized. Obviously, this drawback is especially pronounced for export variants of missiles, since in the "third countries" where the anti-ship missile under consideration can be exported, there are no long-range targeting systems.

 The objective of the claimed technical solution is to eliminate the noted drawbacks, namely, increasing the efficiency of hitting a target in conditions of its fire and radio-technical counteraction to a missile strike.

 The technical result is achieved by the inclusion of new blocks and a different connection between the blocks in the anti-ship missile, 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, consisting in that it additionally introduced a detachable warhead made in the form of an aviation submarine missile containing an inertial control system, a propulsion system, a warhead with a safety-executive mechanism, a NOT block and an AND block, a threshold device, an OR block and a warhead separation mechanism, while the input of the warhead separation mechanism is connected to the output of the range calculator through a threshold device and an OR block, the second input of which connected to the output of the missile’s internal control unit, the input of the inertial control system is connected to the output of the warhead separation mechanism through the NOT block and the And block, the second input of which is connected to the coordinator’s output and input-safety actuator warhead combat unit connected to the output mechanism unit combat compartment through the propulsion system.

 The idea of the proposed technical solution is to equip the anti-ship missile with an additional detachable warhead made in the form of an aviation underwater missile. The separation of the indicated combat unit from the missile is carried out in the region of the target to the range of fire weapons of short-range targets. At the same time, the command to separate the combat unit is formed either upon the missile reaching the established range to the target, or upon the damage to the missile. Information for the inertial control system of the combat unit comes from the missile control system, as a result of which, after the separation of the combat unit, the last information available at the time of separation remains in its control system. Since the speed of the underwater missile in the underwater section of its trajectory reaches 200 knots, due to the short range of separation of the warhead from the target, the guidance errors of the underwater missile corresponding to the range of the underwater missile provide acceptable accuracy of the latter. The short range of the submarine missile and its high speed ensure the difficulty of counteracting it with anti-submarine defense means of the target, and the lack of homing of the submarine missile makes it impossible to set sonar interference. In this case, the inclusion of additional units in the anti-ship missile is carried out by reducing the fuel supply on the rocket, which at a shorter firing range becomes redundant for firing conditions without long-range target designation.

 We show the materiality of the distinguishing features.

 The introduction of a detachable warhead into an anti-ship missile is a new solution for anti-ship missiles. It provides an increase in the probability of hitting a target by increasing the damaging elements in a missile salvo. The implementation of a separate warhead in the form of an aviation mobile missile is a new solution for detachable warheads used in weapons. After separation, the rockets and the warhead, in contrast to the known solutions, continue to move toward the target in various physical environments. As applied to ballistic missile warheads, such movement occurs in one environment, and accordingly, the execution of warheads can be the same for all. In the proposed solution, the implementation of the combat unit in the form of an aviation submarine rocket provides the possibility of its separation from the rocket under the aerodynamics of the rocket and the possibility of its splashdown without destruction. Only aviation submarine missiles provide the implementation of the regime of separating it from the aircraft and splashdown in the event of significant overloads in the design of the aircraft submarine rocket.

 The introduction of a threshold device into a missile is a new solution for anti-ship missiles. It provides the formation of a signal to separate the combat unit while reducing the distance to the target to a predetermined value.

 The introduction of the OR block into the rocket and the connection of its input with the output of the range calculator through a threshold device, and the output of the OR block with the input of the warhead separation mechanism is a new solution. It provides the separation of the warhead from the rocket at a predetermined range to the target. The connection of the second input of the OR block with the output of the missile’s internal control block ensures the separation of the combat block from the missile when the missile loses its ability to hit the target due to damage to the target range set in the threshold device.

 The implementation of a detachable warhead in the form of an aviation submarine missile containing an inertial control system, a propulsion system, a warhead with a safety-actuating mechanism, an NOT block and an I block with their connections to each other is a new solution for an anti-ship missile. The connection of the inertial control system input with the output of the warhead separation mechanism through the NOT block and the I block, the second input of which is connected to the output of the target coordinator, provides information about the coordinates of the target to the inertial control system until the warhead is separated from the missile and this information is recorded at the moment Department of the combat unit.

 The connection of the water of the safety-executive mechanism of the warhead of the warhead with the output of the warhead separation mechanism through the propulsion system is a new solution for anti-ship missiles. It ensures the safety of separation of the warhead from the missile due to the non-introduction of the warhead of the warhead immediately at the time of separation, when large overloads experienced by the warhead can trigger the actuator of its warhead. This solution also provides for cocking the warhead of the warhead upon the fact of entering the propulsion mode.

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

 The anti-ship missile contains block 1 — the body of the anti-ship missile, block 2 — the control system, block 3 — the internal missile control block, block 4 — the target coordinator, block 5 — the range calculator, block 6 — the warhead, block 7 — the safety-actuating mechanism.

 Blocks 1-7 characterize the prototype. In addition to blocks 1–7, new blocks were introduced into the anti-ship missile.

 Block 8 is a threshold device. An amplifier with a relay characteristic of the dependence of the voltage of the output signal on the voltage of the input signal can be used as such a block. In particular, as a block 8, a triode thyristor (trinistor) can be used, which makes it possible to control the operating voltage [see, for example, Handbook of an amateur radio designer, M .: Radio and communication, 1984, pp. 466-468].

 Block 9 - OR block with two inputs.

Block 10 - the separation mechanism of the combat unit. As such a block, a well-known forced separation mechanism can be used, described, for example, in [Combat aircraft equipment]: Aviation weapons / D.I. Gladkov, V.M. Baluev, P.A. Sementsov et al. Ed. DI. Gladkova. - M .: Military Publishing House, 1987, pp. 157-160.]
Block 11 - detachable combat unit. An Orlan-type aviation submarine rocket, an export version of which is being developed by the Russian aviation industry, can be used as such a unit.

 Block 12 - inertial control system. Inertial control systems are widely used as autonomous control systems for aircraft weapons. They are described, in particular, in [the above source on pages 106-107].

 Block 13 - propulsion system. As such a block, the rocket jet engine described in [the above source on pages 62-68] can be used.

 Block 14 - warhead detachable warhead. This block is similar to block 6. The device of such blocks is described, in particular, in [the above source on pages 58-62].

 Block 15 - safety-executive mechanism of the combat unit. The device of this block is similar to the device of block 7 of the prototype. A description of his device is given in [the source above on page 61].

 Block 16 - block NOT.

 Block 17 - block And with two inputs.

 Anti-ship missile operates as follows. In flight of rocket 1 to the target, the missile control system 2 controls the course and direction. At the same time, the internal control unit of the rocket 3, according to the built-in program, interrogates the rocket units for their serviceability. The coordinator of the target 4 determines the angular position of the target relative to its axis and gives an error signal to the missile control system for guidance to the target. In addition, based on the measurement of the propagation time of radiation from the coordinator of the target to the target and vice versa, a signal containing information about the distance to the target is generated at the output of the coordinator of target 4. This signal is fed to the input of the range calculator 5, 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 5, the signal is fed to the input of the safety-executive mechanism 7 of the warhead 6 of the rocket. If the range to the target becomes negative, which corresponds to the case of a missile flying past the target without contacting it, the safety-executive mechanism 7 forms a command to undermine the warhead 6.

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

 The signal about the output of the range calculator 5 goes to the input of the threshold device 8, and if the range to the target becomes less than the value set in the threshold device 8, a signal is generated at the output of the threshold device 8, which goes to the first input of the OR block 9. From the output of the OR block 9, this the signal enters the input of the separation mechanism of the combat unit 10. The operation of the latter leads to the appearance of a signal at its output, which is transmitted at the input of the HE 16 units and the propulsion system of the detachable block 13. At the output of the HE 16 block disappears from ignal, which leads to the disappearance of the signal at the first input of block And 17. Therefore, the signal to the input of the inertial control system 12 from the output of the coordinator of target 4 through the second input of the side And 17 ceases to be received, and in the inertial control system 12 of the combat unit remains the latest information about the position of the target at the time of the appearance of the signal at the input of the separation unit 10 of the combat unit 11. In this case, the signal to the input of the separation mechanism 10 may also come through the second input of the OR block 9 from the output of the internal control unit of the missile 3 in case of damage about the set range to the target.

 When a signal appears at the input of the propulsion system 13, the latter is launched and the combat unit 11 is detached from the rocket 1, since by this moment the separation unit 10 is no longer holding the combat unit. When the propulsion system "to mode" at its output, a signal appears that is fed to the input of the safety-actuating mechanism 15 of the warhead 14 of the warhead 11. The warhead14 is cocked. The combat unit 11 follows the target on its own. The probability of hitting a target is determined, in contrast to the prototype solution, by the sum of the probabilities of hitting a target with a missile and warhead.

 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 set goal - to increase the efficiency of hitting the target in the conditions of its fire and radio-technical countermeasures of a missile strike. The proposal is implemented in the form of a simulation model, confirming during its tests on a computer a significant increase in the probability of hitting a target like a surface ship in conditions of counteraction of a ship to a missile strike by fire and radio equipment.

Claims (1)

 An anti-ship missile 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 through a range calculator, characterized in that a detachable warhead is additionally introduced into it, made in the form of an aviation underwater missile containing an inertial control system, a propulsion system, a warhead with a safety-executive mechanism, block N , AND block, threshold device, OR block, and warhead separation mechanism, while the input of the warhead separation mechanism is connected to the output of the range calculator through the threshold device and the OR block, the second input of which is connected to the output of the internal missile control unit, the input of the inertial control system is connected with the output of the separation mechanism of the warhead through the NOT block and the And block, the second input of which is connected to the output of the target coordinator, the input of the safety-executive mechanism of the warhead of the warhead is connected to the course of the separation mechanism of the warhead through the propulsion system,