RU2285632C2 - Shipboard system for protection of ship against low-altitude air attack means - Google Patents

Abstract

FIELD: anti-aircraft defense; systems for protection of ships against low-altitude air attack means; surface ship armament complexes.

SUBSTANCE: proposed system includes device for destruction of helicopters containing engagement unit, hydrophone channel, microphone channel, barometer channel, AND gate with three inputs, blasting device and blasting device engagement unit; system is additionally provided with shipboard rocket bomb mount and radio complex; helicopter destruction device includes additionally timer, buoyancy control unit, radio channel, ballast discharge unit, flooding unit, mode setting unit, two NOT gates, three OR gates and four AND gates; output of engagement unit is connected with input of blasting device through radio channel, first NOT gate, second AND gate, first OR gate, blasting device engagement unit and third AND gate whose second input is connected with output of engagement unit through timer, second OR gate, four AND gates, ballast discharge unit, third OR gate and second NOT gate; second input of third OR gate is connected with output of second OR gate through fifth AND gate and flooding unit; second input of fourth AND gate is connected with first output of mode setting unit whose second output is connected with second input of fifth AND gate; second input of second OR gate is connected with third output of radio channel whose second output is connected with second input of first OR gate; second input of second AND gate is connected with output of first AND gate; input of buoyancy control unit is connected with output of engagement unit and output of shipboard bomb mount is connected with input of shipboard radio complex; setting of buoyancy control unit forming signal for control of depth of submergence of device for destruction of helicopters is selected depending on mass of explosive contained in blasting unit and setting of range forming by shipboard radio complex for explosion of blasting device is selected depending on speed of air attack means and mass of explosive in blasting device; blasting device is provided with non-water-resistant hydrophilic explosive.

EFFECT: enhanced efficiency due to destruction of anti-shipping missiles by explosion pattern "sultan".

1 dwg

Description

The invention relates to air defense, in particular to a ship’s defense system against low-flying air attack weapons.

Known anti-aircraft missile systems, including anti-aircraft guided missiles, systems and devices that provide the preparation of data for firing, launch, pointing the missile at the target and hitting the target [Handbook of an air defense officer / Ed. G.V. Zimina. - M.: Military Publishing, 1981, p. 256]. The advantage of anti-aircraft missile systems is their all-weather, mobility. universality, degree of automation of the processes of conducting combat work, reliability. However, the analog solutions have a number of drawbacks that are manifested in the reflection of low-flying air attack systems by ship anti-aircraft missile systems. Combat work is possible only from the state of combat readiness of the anti-aircraft missile system, when its means for detecting and tracking targets operate in an active mode, wasting ship’s resources and demanding the presence of the complex’s personnel at combat posts. In addition, the active operation of the means for detecting and tracking the targets of the complex unmasks the ship and creates the conditions for the enemy to use the means of destruction aimed at the radiation source.

The noted drawbacks are partially eliminated in the system for protecting the ship from low-flying air attack means, including a device for hitting helicopters, comprising a device activation unit, a hydrophone channel, a microphone channel, a barometer channel, an I block with three inputs, a blasting device and a blasting device activation means block [Patent USA No. 4207819, 1980] is a prototype.

The main advantage of the prototype solution is the autonomy of the functioning of the device for hitting helicopters after setting it up by a ship defending from air attack means. However, the disadvantage of the prototype solution is its low efficiency in the reflection of low-flying anti-ship missiles by the ship. Since anti-aircraft missiles starting from the ship are also a source of information for the channels of the hydrophone, microphone and barometer of the prototype solution, these devices for hitting helicopters will be detonated from their anti-aircraft missiles. In addition, information from the channel of the barometer when flying over the device of a high-speed anti-ship missile to the block of means for activating a subversive device will come too late, and the damaging factors of the subversive device will be able to affect the anti-ship missile only after it. This disadvantage of the prototype solution is especially pronounced if it is used to destroy supersonic anti-ship missiles, when information from the microphone channel will also come after the anti-ship missile flies to the device’s location. And in the prototype solution, unlike anti-aircraft missiles, the time to undermine the subversive device does not agree with the speed and relative position of the target, which significantly reduces the effectiveness of the prototype solution for hitting anti-ship missiles. Another significant drawback of the prototype solution is the danger of ships navigating in the device placement area created by unexploded devices, and the associated difficulties of using the prototype solution in exercises.

The objective of the claimed invention is to eliminate the noted drawbacks, namely, the possibility of hitting a device for hitting helicopters with low-flying high-speed targets during the implementation by a ship of intercepting these targets by anti-aircraft missile systems, matching the time of undermining the device with the speed and relative position of the low-flying target, as well as reducing the danger for swimming in device placement area and the possibility of their use in exercises.

The technical result is achieved by the inclusion of new blocks and a different connection between the blocks in the system of protecting the ship from low-flying air attack means, including a device for hitting helicopters, containing a device for activating the device, a hydrophone channel, a microphone channel, a barometer channel, an I block with three inputs, a blasting device and a block of means for activating a subversive device, characterized in that it additionally includes a ship missile bomb installation and a radio engineering complex, and in devices o for the destruction of helicopters, a timer, a buoyancy control unit, a radio channel, a ballast reset unit, a device flooding unit, a mode setting unit, two glare NOT, three OR blocks and four AND blocks were additionally introduced, while the output of the device activation unit is connected to the input of the blasting device through radio channel, first block NOT, second block AND, first block OR, block of means for activating the subversive device and third block AND, the second input of which is connected to the output of the block for activating the device through a timer, the second block OR , the fourth AND block, the ballast reset unit, the third OR block and the second NOT block, the second input of the third OR block is connected to the output of the second OR block through the fifth AND block and the device flooding block, the second input of the fourth block AND is connected to the first output of the mode setting block, the second output of which is connected to the second input of the fifth block AND, the second input of the second block OR is connected to the third output of the radio channel, the second output of which is connected to the second input of the first block OR, the second input of the second block And is connected to the output of the first block AND, the input of the block buoyancy control is connected to the output of the device’s activation unit, and the output of the ship’s missile bomb installation is connected to the input of the ship’s radio engineering complex, and the buoyancy adjustment unit’s setting, which generates signals for adjusting the immersion depth of the device for hitting helicopters, is selected from the relation

,

,

where N is the immersion depth of the device, m,

M is the mass of explosive in a blasting device, equivalent to the mass of TNT, kg,

and the range setting for the formation of a signal for the detonation of a subversive device by a ship’s radio engineering complex is selected from the relation

,

,

where D is the distance between the device for hitting helicopters and means of air attack, m,

V is the speed of the air attack, m / s,

wherein the blasting device is made with a water-resistant hydrophilic explosive.

The idea of the proposed technical solution is to set up airborne anti-aircraft artillery and anti-aircraft missile systems with the help of a rocket bomb in the gap between the zones of shelling the aircraft with airborne targets and control these devices using the ship’s radio engineering complex via radio channel. Functioning as beacon transponders, the devices provide the ship with accurate determination of the coordinates of each device relative to the ship. This makes it possible, during the reflection of a raid by a ship, of high-speed low-flying anti-ship missiles, to put a water curtain in front of anti-ship missiles due to the creation of explosive sultans that occur when subversive devices are detonated. At the same time, by controlling the optimal depth of immersion of the device, the maximum dimensions and elevation of the explosive sultan are ensured, and the proposed ratio for setting the range of formation of a command to detonate the explosive device of the device ensures the coordination of the time of elevation of the sultan with the flight height of anti-ship missiles. If anti-ship missiles do not fly over the device setting area, or the ship for some reason has not issued a command to detonate the device, then the latter is flooded or pops up (if it is used in exercises) at the command of the ship or after a certain period of time. At the same time, the safety of possible handling of the device is ensured by breaking the chain of passage of the command to detonate the explosive of the explosive device, and when the device is flooded, by additionally dissolving the explosive in water.

We show the materiality of the distinguishing features.

The introduction of a ship missile bomb installation into the ship’s protection system against low-flying airborne attack is a new solution. Due to the high rate of fire of the rocket bomb installation and the high speed of its rockets, this solution ensures the timely deployment of devices when a ship detects air attack means,

The introduction of its radio engineering complex into the ship’s protection system and the connection of the latter’s entrance with the missile’s exit from a bomb installation is a new solution. It provides the ship with the determination of the relative coordinates of the exposed devices, as well as the detonation of the exposed devices on command from the ship, as well as the ascent or flooding of the devices on command from the ship.

The implementation of the device for hitting helicopters additionally containing a timer, a buoyancy adjustment unit, a ballast reset unit, a device flooding unit, a mode setting unit, a radio channel unit, two NOT blocks, four AND blocks, three OR blocks with their connections between themselves and other device blocks is new decision. It provides the possibility of eliminating the operation of the device from the noise of anti-aircraft missiles launching from the ship and ensures that the device is triggered only by command from the defending ship.

The introduction of a buoyancy control unit into the device and its implementation with the setting for diving depth regulation in accordance with the specified ratio is a new solution for ship missile bomb installations. It ensures that the device is held at the optimum depth in terms of maximum dimensions of the explosive sultan.

The introduction of a mode installation unit, a ballast discharge unit, and a device flooding unit with their connections between each other and other device units is a new solution. It provides the ability to remove a failed device both by flooding (when using the “on-the-fly” system) and by floating the device to the surface for reuse (when used in exercises). The introduction of a timer with its connections with other units of the device provides the ability to remove a failed device if it is not possible to form a command to remove a failed device on the ship that exposed the device.

The implementation of a subversive device with a water-resistant hydrophilic explosive is a new solution. It ensures the exclusion of explosives from the seabed of the seabed, which is undesirable for the water areas of the naval bases, since the water-resistant, water-wetted (hydrophilic) explosive of the explosive device quickly decomposes and dissolves in sea water after flooding the device.

The connection of the second input of the third AND block with the timer output through the second OR block, the fourth AND block, the ballast reset block, the third OR block and the second NOT block, the connection of the second input of the second OR block with the third output of the radio channel, as well as the connection of the second input of the third OR block with the output of the second OR block through the fifth block AND and the flooding unit of the device and the connection of the outputs of the mode setting unit with the second inputs of the fourth and fifth AND blocks is a new solution. It provides the exclusion of the possibility of giving a command to undermine the subversive device when the device emerges, which ensures the safety of handling it in preparation for reuse. This also ensures the elimination of the possibility of undermining the subversive device of the flooded device.

The introduction of a radio channel with its connections with other units of the device and the formation of a signal to undermine the subversive device in accordance with the specified ratio is a new solution. It provides coordination of the rise time of the explosive sultan to the flight altitude of low-flying anti-ship missiles with their flight speed.

The essence of the proposed technical solution is illustrated by the drawing, which shows a diagram of the proposed system of defense of the ship from low-flying air attack weapons.

The ship’s protection system against low-flying air attack means contains:

1 - a device for hitting helicopters,

2 - channel hydrophone,

3 - microphone channel,

4 - channel barometer,

5 - the first block And with three inputs,

6 - unit activation device

7 is a block of means for activating a subversive device,

8 - blasting device,

9 - ship.

Nodes 1 ... 9 characterize the prototype. In addition to them, new units and blocks were introduced into the ship’s protection system from low-flying air attack weapons. 10 - Ship missile bomb installation (aka RBU, or a bomber). A device for hitting helicopters 1 is essentially a mine. Mines are very diverse in their purpose, design features and production methods. Ship missile launcher is essentially a jet mortar. Therefore, any fundamental technical difficulties when using a ship's bomb installation for setting device 1 is not expected. Description of naval bomb installations, see V. Hvoshch. Submarine tactics. - M .: Military Publishing House, 1989, p. 123.

11 - Ship radio engineering complex. For the joint operation of the ship’s radio engineering complex and the radio channel of device 1, one of the many options for radio engineering systems can be used, in particular, ship equipment of the DIBUS system, for a description of which see A. Prostakov Electronic key to the ocean (Hydroacoustic technology today). - 2nd ed. L .: Shipbuilding, 1986, pp. 90-92.

12 - Buoyancy control unit. For a description of such a unit, see the indicated source p. 80.

13 - Radio channel with three outputs. In relation to the radio channel for device 1, sonar buoy radio equipment can be used, for a description of which see the indicated source p. 90-92.

14 - Timer. As it can be used one of the widely used in the technology of electronic timers.

15 - Block installation mode. As it can be used the simplest command device in the form of a switch with two outputs. For a description of command devices operating both in manual and automatic mode, 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. 222.

16 - Ballast dumping unit. For a description of such a block, see Prostakov A.L. Electronic key to the ocean (Hydroacoustic technology today). - 2nd ed. L .: Shipbuilding, 1986, p. 80.

17 - Block flooding device. The device of such a unit is similar to the device of unit 16. The only difference is in the actuator of the unit, which provides depressurization of the device 1.

18 and 19 - respectively, the first and second blocks are NOT.

20, 21 and 22 - respectively, the first, second and third blocks OR with two inputs.

23, 24, 25 and 26, respectively, the second, third, fourth and fifth AND blocks with two inputs.

(и при благоприятном курсовом угле воздушной цели, когда траектория цели проходит над устройством 1), радиотехнический комплекс формирует кодированный сигнал, который принимается и распознается радиоканалом 13, и последний на своем втором выходе формирует сигнал, который через первый блок ИЛИ 20, блок средств задействования подрывного приспособления 7 и третий блок И 24 поступает на вход подрывного приспособления 8, вызывая взрыв последнего. Возникает взрывной султан, время подъема которого на максимальную высоту соответствует времени пролета воздушной целью расстояния между устройством 1 и воздушной целью на момент выдачи команды на подрыв подрывного устройства 8. В этом случае, если высота полета цели меньше высоты подъема взрывного султана, происходит встреча цели с взрывным султаном, в результате которой цель поражается. Подъему взрывного султана на максимально возможную высоту способствует погружение устройства 1 на оптимальную глубину. После попадания устройства 1 в воду с выхода блока задействования устройства 2 на вход блока регулировки плавучести 12 поступает сигнал, и последний начинает функционировать, удерживая глубину погружения устройства 1, в соответствии с предложенным соотношением.The system for protecting the ship from low-flying air attack facilities operates as follows. To protect against helicopters, the ship 9 carries out the setting of devices 1 by one of the known methods of setting mines. When the device 1 enters the water, the activation unit of the device 2 is triggered, which leads to the beginning of the functioning of the channel of the hydrophone 3, the channel of the microphone 4 and the channel of the barometer 5. If a helicopter flies over the device 1 at a low height, then channels 3, 4, and 5 appear at the outputs the signals that enter the first, second and third inputs of the first block And 6. At the output of the latter, a signal is generated, which through the second block And 23, measuring block OR 20, the block of means for activating the blasting device 7 and the third block And 24 enters the input d blasting device 8, causing the explosion of the latter. In the proposed solution, if the device is staged by a ship’s missile bomb installation 10, after the last shot, a signal is received at the input of the ship’s radio engineering complex 11. The radio complex 11 begins to emit coded radio signals at the operating frequency of radio channel 13. In the case when the signal from the output of the activation unit of device 2 is present at the input of the latter, a signal is generated at the first output of radio channel 13, which is input to the first block of HE 18, causing the signal to disappear at the first input of the second block And 23. Thus, the channel of the hydrophone 3, the channel of the microphone 4 and the channel of the barometer 5 is blocked. Radio channel 13 carries out re-radiation received from the ship radio nical complex radio signal 11 that allows radio using known methods to measure the current position relative device 1. If the ship 11 performs complex Radiotechnical support aerial target, then when the distance to the purpose of the device 1, corresponding to said ratio

(and at a favorable directional angle of the air target, when the target trajectory passes over the device 1), the radio complex generates an encoded signal that is received and recognized by the radio channel 13, and the latter generates a signal at its second output, which through the first block OR 20, the block of means of activation blasting device 7 and the third block And 24 enters the input of blasting device 8, causing the explosion of the latter. An explosive sultan arises, the rise time of which to the maximum height corresponds to the time the aerial target flies the distance between device 1 and the air target at the time of issuing a command to detonate the blasting device 8. In this case, if the target’s flight height is less than the height of the explosive sultan, the target encounters explosive sultan, as a result of which the target is hit. The rise of the explosive sultan to the highest possible height is facilitated by the immersion of the device 1 to the optimum depth. After the device 1 enters the water from the output of the activation unit of the device 2, a signal is received at the input of the buoyancy adjustment unit 12, and the latter starts functioning, holding the immersion depth of the device 1, in accordance with the proposed ratio.

If the mode 15 installation block is set to the ascent mode of device 1 and a signal is generated on the third output of radio channel 13 as a result of transmission of the encoded radio signal by the ship’s radio engineering complex, then the signal from the third output of radio channel 13 is transmitted through the second block OR 21 and the fourth block AND 25 to the input of the ballast dumping unit 16. The ballast is reset, the device 1 pops up. At the output of the ballast dumping unit, a signal is generated which, through the third block OR 22, is fed to the input of the second block HE 19, causing the signal to disappear at the second input of the third block AND 24. This will break the blasting circuit of the blasting device 8. If the mode is set to 15 flooding of device 1, the circuit operates in a similar way, only the signal to the second input of the third block And 24 passes from the output of the second block OR 21 not through the fourth block And 25 (there is no signal at its second input), but es fifth block and the block 26 and flooding the device 17. When the device 1 occurs flooding and flooding of the blasting device 8 and its nevodostoykoe hydrophilic substance over time lose its explosive properties, dissolving in water. If for some reason using the ship’s radio engineering complex it is not possible to give a command to ascend or flood the device 1, after a certain time it will float to the surface or will be flooded (depending on the mode set in the installation block of mode 15) according to the signal generated timer 14.

Thus, based on the analysis of the structure and functioning of the scheme of the proposed technical solution, we can conclude that the ship’s protection system from low-flying air attack means, in which this solution is implemented, has the advantages that meet the stated objective — that it enables the device to destroy low-flying high-speed helicopter helicopters to the time the ship takes to intercept these targets with anti-aircraft missile systems, and coordinate the time to detonate the device with speed and from the relative position of a low-flying target, as well as reducing the danger to swimming in the area of setting devices and providing the possibility of their use in exercises.

Claims (1)

A system for protecting a ship from low-flying air attack means, including a device for hitting helicopters, comprising a device activation unit, a hydrophone channel, a microphone channel, a barometer channel, an I block with three inputs, a blasting device and a blasting device activation means unit, characterized in that additionally introduced a ship missile bomb installation and a radio complex, and a timer, a buoyancy adjustment unit, diochannel, ballast dumping unit, device flooding unit, mode setting unit, two NOT blocks, three OR blocks and four AND blocks, while the output of the device activation block is connected to the input of the blasting device via a radio channel, the first block is NOT, the second block AND, the first block OR, a unit for activating a blasting device and a third block AND, the second input of which is connected to the output of the unit for activating the device through a timer, the second block OR, the fourth block AND, the ballast reset unit, the third block OR and the second block NOT, the second input this OR block is connected to the output of the second OR block through the fifth block AND and the device flooding block, the second input of the fourth AND block is connected to the first output of the mode setting block, the second output of which is connected to the second input of the fifth block AND, the second input of the second OR block is connected to the third the output of the radio channel, the second output of which is connected to the second input of the first block OR, the second input of the second block AND is connected to the output of the first block AND, the input of the buoyancy control unit is connected to the output of the device activation unit, and the output is Missile bomb cabling installation connected to an input of ship radio complex, the setpoint adjustment unit buoyancy forming signals to control the depth of immersion device for helicopters lesion is selected from the relation

, where H is the immersion depth of the device, m; M is the mass of explosive in a blasting device, equivalent to the mass of TNT, kg, and the range setting for the formation of a signal for the detonation of a subversive device by a ship’s radio engineering complex is selected from the relation

, where D is the distance between the device for hitting helicopters and means of air attack, m; V is the speed of the air attack, m / s, wherein the blasting device is made with a water-resistant hydrophilic explosive.