RU2287770C1 - One-time bomb cluster and cluster war component - Google Patents

Abstract

FIELD: ammunition.

SUBSTANCE: the cluster includes the nose with a fuse installed in it, body with a stabilizer, central perforated tube with flanges located in the body, rows of war components are located between the flanges around the tube, peripheral perforated tubes resting on the flanges, and elastic metal shells resting on the central and peripheral tubes, the shells are profiled with the surfaces of the war components adjacent to them and of the peripheral tubes, and a common gas dynamic system for unpacking of the cluster, actuation of the fuses of the war components adjacent to them and the peripheral tubes, and a common gas dynamic system for unpacking of the cluster, actuation of the fuses of the war components and scattering of the war components. The war component has a body with a stabilizer, nose and bottom sections, fuse and a war element. A tube is installed in the bottom section of the war component in its central axis, the fuse adjoining the bottom section is located in the tube cavity, a bush with a gas by-pass orifice is positioned on the rear end face.

EFFECT: enhanced reliability and efficiency of action and stability of technical characteristics both of the cluster proper, and of the war components.

10 cl, 14 dwg

Description

The proposed inventions relate to military equipment, namely to single-shot bomb cartridges, in particular to cartridges equipped with military elements - small-caliber anti-submarine bombs.

Aviation cartridges are ammunition of area action and contain a significant number of warheads, which allows for the use of salvo or serial-volley use of cartridges to cover with warheads with a given density a large area of the possible location of the target, and in order to ensure the given efficiency, warheads (PLA bombs) must (calculated) density is evenly distributed in the target area. This is necessary so that at least one of the dropped bombs hits the target. In order to most likely meet the above requirements, taking into account, at the same time, the accuracy of target designation systems and the small size of the target (submarine) in a wide range of application modes, for cluster munitions, their actuators (fuses, pyrotechnic devices, systems for dispersion of combat elements) and Reliability of their work requires particularly high technical requirements.

The designs of the known cartridges are different, however, they all contain characteristic structural elements, such as a body, stabilizer, combat elements, armature, various pyrotechnic devices. The location of such structural elements in the cartridges is also different and is determined by the functional and design features of the actuating elements.

From the considered analogues, the "Cluster warhead" according to the patent of the Russian Federation No. 2150078, class 7 IPC F 42 B 12/58 of 1999, the "Cluster warhead for an air-to-surface missile with a device for ejecting munitions" according to the US patent can be selected No. 3865034, class NKI 102-7.2 from 1975 and "Device for dispersion at different speeds in the radial direction of small shells" according to US patent No. 3938439, class NKI 102-72 from 1971

The cassette warhead according to RF patent No. 2150078 contains a shell, a central explosive charge, elongated combat elements with a conical head part, pins fastened to the shell. Combat elements are laid on the outer surface of the shell on the end intermediate rings having recesses for the end and conical surfaces of the combat elements. On top of the combat elements, a female ring is installed, placed in a through groove of clamping strips made of spring steel and mounted on top of the rings. The straps are located between at least two combat elements of the same row and are fastened at the ends with pins. When a central explosive charge of a cluster warhead is undermined by the action of detonation products acting on the shell, combat elements receive a radial impulse. When the elements move, the ring enveloping them breaks, freeing the output of the combat elements from the cartridge. The design of the warhead allows the separation of warheads from the carrier’s body under the influence of an explosive pulse. However, this solution has several disadvantages. Firstly, the duration of the effect of an explosive impulse on combat elements is several microseconds, which, with a large mass of a combat element (for example, PLAB bombs), can lead to damage to a combat element, initiating its charge. In addition, fuses built on an electronic or hourly principle of operation may not withstand large overloads obtained during the separation of military elements. Secondly, in the given design of the analogue there is no subsequent movement of the shell to disperse the combat element. The combat element, receiving a powerful initial explosive impulse, is separated from the shell. However, to ensure a given dispersion of combat elements on the ground, this is clearly not enough. Therefore, the design of the analogue will not be able to provide a rational dispersion of combat elements on the ground, to exclude the overlapping of zones of destruction from these combat elements. Thirdly, the given design of the analogue does not allow the cocking of fuses having a pyrotechnic or other principle of engagement.

The cassette warhead according to US patent No. 3865034 consists of a cylindrical body made of brittle material and closed at both ends by caps, a plurality of warheads (ammunition) located inside the circumference of the body, ammunition dispersion means located in the center coaxially to the body and surrounded by radial layers of ammunition. Scatter tools consist of rubber and aluminum diaphragms supporting a steel pipe and a gas generator with a powder charge. The rubber diaphragm in the "undressed" state has the shape of a hollow cylinder. The aluminum diaphragm is made of a soft aluminum alloy and in the “undressed” state has the shape of a corrugated cylinder. Steel perforated pipe mounted in an aluminum diaphragm. The aluminum diaphragm is located inside the rubber diaphragm coaxially with the latter. A gas generator with a powder charge is placed inside a steel central perforated pipe fixed at its ends with the housing covers. To ensure operability, the rubber diaphragm, the aluminum diaphragm, the supporting perforated pipe and the gas generator have corresponding attachment points with the housing and with each other. This design allows you to provide both the necessary speed of dispersion of combat elements, and their dispersion. However, it, like the design of the previous analogue, does not provide for the possibility of cocking fuses with a pyrotechnic or other principle of engagement. In addition, in the design of the examined cluster warhead there are no guides for the release of ammunition, which can lead to their uneven distribution in the target area and, therefore, to reduce the effectiveness of the cluster warhead. The components of the dispersion system (rubber diaphragm, aluminum diaphragm, supporting a steel perforated pipe) in combination with a body made of brittle material (plexiglass) in the assembly have a significant volume and weight, which will lead to an increase in the overall mass characteristics of the cartridge warhead. At the same time, this analogue provides for the complex design of the assembly designed to ensure the tightness of the rubber diaphragm, and the body made of Plexiglass has significant dimensions, as well as complex assemblies intended for placement and fastening of it in the cartridge.

Of the selected analogues, the closest is the device according to US patent No. 3938439, adopted as a prototype. The device consists of a casing, in which in several rows around the central perforated pipe there are placed combat elements made in the form of small shells covered by a light bandage. The rows are divided among themselves by bases. Under the lower row of shells there is a gas generator, during operation of which the produced gas enters the central perforated pipe passing through the entire device, and through the radial holes located at the level of each row, into the chamber formed by a rubber diaphragm sealed to the pipe at the junction with grounds. The gas produced by the generator acts on the rubber diaphragm with a force sufficient to break the light bandage covering the shells. In this case, the projectiles scatter in the radial direction at different speeds.

The disadvantages of the considered design of the prototype include:

- the complexity of the structural unit designed to ensure the tightness of the rubber diaphragm when filling it with powder gases;

- the absence of guides for the ejection of shells, as well as the relatively low strength of the tightening brace, since an increase in its strength will lead to the need to increase the stiffness of the rubber diaphragm, which, ultimately, will lead to a decrease in stroke during its expansion, and therefore to a decrease in the ejection speed shells and their dispersion zones;

- relatively low indicators of the reliability of the action, as there are cases of destruction of the rubber diaphragm both in the places of its attachment to the perforated pipe and in the spaces between the shells, due to the uneven distribution of external pressure around the perimeter of the diaphragm;

- the impossibility of using fuses of shells having a pyrotechnic or any other principle of cocking.

Known small-sized cluster warhead according to the patent of the Russian Federation No. 2243492 from 2003, class. 7 IPC F 42 B 12/10 is a prototype that includes a cylindrical body with a stabilizer, a head and a bottom, a fuse and a warhead, a target sensor and a safety-actuating mechanism. The target sensor is made in the form of a piezoelectric sensor and has the shape of a cylinder with an axial channel. The stabilizer is made of elastic steel arcuate plates, the inner ends of which are rigidly fixed in the stabilizer block, and the outer ends are interconnected with the possibility of sliding, and when laying in a cassette are compressed to the outer diameter of the housing. The target sensor and stabilizer are mechanically and electrically connected to the body of the combat element.

However, having undoubted advantages, relative simplicity of design, reliability of operation, the specified combat element cannot be used in single-shot bomb cartridges containing a single gas-dynamic system that ensures the disclosure of the cartridge and the dispersion of the combat elements placed in it with the necessary expansion speed, since the design of the specified combat element does not elements are provided to ensure the engagement of fuses of combat elements from the gas-dynamic system of the cartridge.

The problem solved by the claimed inventions is to increase the efficiency of a single bomb cartridge.

The technical result achieved by the implementation of a single bomb cartridge is to increase the reliability of the cartridge and increase the speed of dispersion of its combat elements.

The technical result is achieved by the fact that a single bomb cluster includes a head with a fuse installed in it, a housing with a stabilizer, a central perforated pipe with flanges located in the housing, between which rows of military elements are placed around the pipe, based on the peripheral perforated pipes and resting on the central flanges and peripheral pipes, elastic metal shells, profiled along adjacent surfaces of military elements and peripheral pipes, and a single gas-dynamic system the process of unpacking the cartridge, engaging the fuses of military elements and the dispersion of military elements.

Compliance with these signs will improve the reliability of the cartridge and increase the speed of dispersion of its combat elements. In addition, the stability of the technical characteristics of a single bomb cluster increases, and the range of its combat use expands.

The execution in the cartridge, including the central perforated pipe, of peripheral pipes resting on the flanges, will allow, on the one hand, to increase the strength of the cartridge by creating a power frame that allows you to place and hold combat elements in the cartridge until the latter opens on the air path of its flight, and , on the other hand, to increase the spread rate of the warheads of the cartridge by increasing the gas-dynamic flow and, accordingly, increasing the pressure in the internal cavities formed by elastic metal shells, while ensuring both the actual increase in the rate of their dispersion and the increase in the reliability of the cartridge.

The implementation of the elastic metal shells resting on the central and peripheral pipes profiled along the surfaces of the combat elements and peripheral pipes adjacent to them will strengthen the cartridge’s power frame and, therefore, its strength, create internal cavities in the cartridge that are elements of the cartridge’s gas-dynamic system, and, accordingly , increase the speed of dispersion of the combat elements of the cartridge, increasing the reliability of its action. Since each shell installed in a particular row (section) of the cartridge between the transverse flanges may consist of separate parts, the adjacent ends of which are supported by the corresponding peripheral pipes of the cartridge frame, are sealed and rigidly connected to each other, the cartridge frame is strengthened, and better conditions are provided for its assembly, transportation of the cartridge from storage to the carrier, its transportation as part of the carrier, and also after separation of the cartridge from the carrier until it is opened onto an air trajectory and flight.

The introduction of a unified gas-dynamic system into the cassette of its unpacking, engagement of fuses of warheads and dispersion of warheads will allow gas-dynamic communication between the gas generator (gas source), the chambers of the shells and the pyroelectric device of warheads through the through holes of the perforated tubes of the frame, due to which it will spread the warheads and cover the specified area of the water area of the probable location of the target, thereby increasing the probability of hitting at least one combat element in the target she (bombs). In this case, there is an increase in the gas-dynamic flow in the system, due to which the spreading speed of the combat elements of the cartridge increases, and its reliability increases. In addition, the proposed gas-dynamic communication system will allow, due to the introduction of peripheral pipes, to unload the central pipe, making it lighter, reducing its wall thickness and diameter, which will reduce the overall dimensions of the cartridge and accommodate large-sized combat elements.

In certain specific cases, the design of a single bomb cartridge can be performed using the dependent features indicated in the claims.

So, the proposed design of the gas generator and its placement in the channel of the front flange will improve the conditions for the initiation and operation of the powder charges of the gas generator. This is achieved by reducing the length of the fire chain, since the powder charges of the proposed design of the gas generator are placed in a single housing, and their combustion chambers are adjacent to each other. In addition, due to the implementation of the gas generator from three separate powder charges connected by a fire chain, a reliable effective gas-dynamic effect on the actuators is achieved, while the first powder charge affects the detachable connection of the cartridge, the third powder charge through the central tube and radial channels of the flanges acts on firing devices of fuses adjacent to the warhead of the combat elements, and a second powder charge through the front, annular chamber and gas transfer the holes of the flange and peripheral pipes acts on the elastic shells of the first and subsequent rows of combat elements. Due to the installation of a delay device between the second and third powder charges of the gas generator, the necessary time interval is provided for reliable guaranteed cocking of fuses of military elements (air bombs) until they disperse. In general, all this helps to increase the reliability of the cartridge.

A single gas-dynamic system may include several interconnected chambers. The front chamber is located between the head of the cartridge and the front flange, the second and subsequent chambers are formed by elastic metal shells of the first and subsequent rows of combat elements. The gas generator can be installed in the central channel of the front flange. The front chamber, connected through the holes of the flange and pipe channels with cavities (chambers) formed by elastic shells, is a cylinder into which the products of the combustion of the powder charge of the gas generator are fed under pressure, equalizes pressure emissions during operation and allows more stable dispersion characteristics of warheads on air flight path, due to which to ensure zones of dispersion of combat elements on the water surface, close to the calculated.

The peripheral tubes may be located at a predetermined distance from the central tube, and the outer diameter of the central tube may be selected to be greater than or equal to the outer diameter of the peripheral tube. This can, for example, be carried out by selecting the distance of the fastening of each peripheral pipe from the outer diameter of the central tube of the frame and will allow you to pre-select the necessary expansion parameters of each combat element in the section.

In all flanges of the cartridge, except for the front flange, radial channels can be made that extend to the lateral surface of the flanges coaxially with the gas bypass holes of the warhead elements adjacent to them. This will allow gas-dynamic connection of the chamber formed around the fuse of the combat element with the gas generator (gas source) of the cartridge and the fuses of the military elements from the gas-dynamic system of the cartridge to be reliably used. Camora can, for example, be made in the form of a pipe installed in the bottom of the combat element along the central axis. A fuse adjacent to the warhead of the combat element can be placed in the cavity of the tube, and a sleeve with a gas bypass hole can be located at the rear end of the tube, providing an emphasis on the warheads in the flange of the cartridge, on the one hand, the gas-dynamic system of the cartridge is closed and, on the other hand parties, reliable preloading of combat elements in the longitudinal direction when placed in a cartridge. This significantly increases the reliability of the operation of nodes and elements of both the cartridge itself and the combat elements placed in it.

Thus, the combination of all the above features will improve the reliability and stability of the technical characteristics of both the single bomb cluster and the combat elements placed in it, increase the effectiveness of the cluster and expand the range of its combat use. At the same time, the implementation of standard cassettes in the smallest possible dimensions is ensured, significantly reducing their mass and overall dimensions in comparison with the design of the prototype. Due to the spread of warheads from different sections of the cartridge with predetermined speeds relative to each other, obtained when powder gases enter the shell chamber through the through holes of the front flange and the holes on the walls of the peripheral pipes, the rational area of the water area is increased, the probability of hitting at least one of the scattered combat elements.

In order to solve the task and achieve the technical result declared during the implementation of the one-time bomb cartridge, it is necessary to develop such a combat element that would enable its use in one-time bomb cartridges with a gas-dynamic system.

The technical result achieved during the implementation of the combat element consists in providing the possibility of using the gas-dynamic flow generated when the gas-generator of the gas-dynamic system of the cartridge is triggered to engage fuses (or other work units: pyrotechnic elements, moderators, initiators, etc.) of combat elements.

The technical result is achieved in that the cluster warhead contains a housing with a stabilizer, a head and a bottom, a fuse and a warhead. A pipe is installed in the bottom of the combat element along its central axis, in the cavity of which there is a fuse adjacent to the warhead, and at the rear end there is a sleeve with a gas bypass hole that can extend beyond the end of the stabilizer of the combat element.

The installation of a pipe in the cavity of which a fuse is located adjacent to the warhead of the combat element will allow a chamber to be formed around the fuse of the combat element through which fuses (or other work units) of the warheads can be activated from a gas-dynamic flow having predetermined characteristics (pressure P, temperature T).

Placing a sleeve with a gas transfer hole at the rear end of the tube, which may extend beyond the end face of the combat element stabilizer, will allow the chamber formed around the fuse of the combat element to have a gas-dynamic cartridge system, while certain predetermined sizes of the gas transfer hole provide reliable engagement of the fuse (or other operating units) ) a combat element from a gas-dynamic flow having predetermined characteristics (pressure P, temperature T) and formed at AANII gasifier gazodinamicheskoj cassette system.

The combat elements placed in the cartridge can be made in the form of any ammunition necessary for solving a specific combat task, for example, in the form of small-caliber anti-submarine bombs.

The proposed cluster warheads can be used as part of other designs of disposable bomb cartridges having their own, different from those proposed in this application, gas-dynamic systems for scattering of warheads and the use of their working units.

Thus, the totality of all the above characteristics will improve the reliability and stability of the technical characteristics of both the single bomb cluster and the combat elements placed in it, ensure the use of combat elements in it, using their fuses (or other operating units) from the gas-dynamic cluster system, increase its effectiveness, expand the range of combat use of the cartridge and the combat elements placed in it.

Figure 1 presents a General view of the proposed in this application of a single bomb cartridge, figure 2 - placement of combat elements in a separate section of the cartridge, figure 3 - gas generator, located in the head of the cassette, figure 4 - structural elements of the gas generator , Fig.5 - the location of the openings on the peripheral tubes of the cartridge, Fig.6 - graphs of experimentally obtained data on the ratio of the squares of the through openings on the wall of the peripheral pipes in the front and rear sections of the placement of combat elements "Sper. / Shv." and velocities "V" of the dispersion of combat elements, Fig.7 is a graph of the pressure "P" in the chambers of the shells when the dispersion of military elements from time to time "τ" with the pressure designation "Razr. home." rupture of the clamp tightening the warheads, Fig. 8 - placement of the fuse of the warhead in the cavity of the pipe located on the Central axis of the warhead, Fig.9 - graph of the pressure "P" in the chamber around the fuse of the warhead from time "τ", obtained during experimental testing of the cartridge, figure 10 is a diagram of the dispersion of combat elements from the front and tail sections when opening the cartridge and the distribution of combat elements on the surface of the water area, figure 11 - installation of peripheral tubes at the same distance "Ao" from the forces oh (central) pipe in a single section of combat elements, Fig. 12 is a diagram of the distribution of combat elements on the surface of the water when installing peripheral pipes at the same distance "Ao" from the power (central) pipe in a separate section of combat elements, in Fig. .13 - installation of peripheral pipes at different distances "Ah" and "Au" from the power (central) pipe in a single section of combat elements, Fig. 14 is a diagram of the distribution of combat elements on the surface of the water when installing peripheral pipes at different distance "Ax" and "Ay" of the power (center) of the pipe in a particular section of submunitions.

A single bomb cluster includes (see Figs. 1 and 2) a head part 1 with a fuse 2 installed in it, a body 3 with a stabilizer 4, a central perforated pipe 5 with flanges 6 located in the body 3, between which rows of combat elements are placed around the pipe 5 7, based on the flanges 6, peripheral perforated pipes 8 and elastic metal shells 9, supported on the central 5 and peripheral 8 pipes, profiled on adjacent surfaces of the combat elements 7 and peripheral pipes 8. The cartridge contains a single gas-dynamic istemu unpacking tape engagement fuze submunitions 7 and the spread of the latter.

In certain specific cases, the design of a single bomb cartridge can be performed using the dependent features indicated in the claims.

So, a single gas-dynamic system can include a gas generator 10 (Fig. 1; 3; 4; 8), made as a single unit and containing three successive powder charges 11, 12, 13, while the front charge 11 adjacent to the fuse 2 of the cartridge is gasdynamically connected with a detachable connection 14 of the head part 1 of the cartridge and the front flange 15, the rear charge 13 with pyroreceptive devices 16 fuses 17 of the combat elements 7, and the intermediate charge 12 with internal cavities formed by elastic metal shells 9. The detachable connection of the 14th the back part 1 of the cartridge and the front flange 15 can be made in the form of a cork lock, characterized by simplicity of design, manufacturability in manufacturing and reliability in operation.

A single gas-dynamic system can, in addition, include several interconnected chambers. The front chamber 18 is located between the head part 1 of the cartridge and the front flange 15, and the second and subsequent chambers 19 are formed by elastic metal shells of the first and subsequent rows of combat elements 7. The gas generator 10 is installed in the Central channel 20 of the front flange 15.

The peripheral pipes 8 (11; 13) can be located at a predetermined distance from the central pipe 5, and the outer diameter of the central pipe 5 can be chosen to be greater than or equal to the outer diameter of the peripheral pipe 8. This will allow the central pipe to be unloaded, making it lighter and smaller in diameter , which, in turn, will reduce the mass-dimensional characteristics of the cartridge.

The location of the peripheral pipes 8 is selected, on the one hand, based on the length of the shell 9 and the deflection associated with the length of the shell of the boom when the combat elements 7 are scattered, and therefore the speed of their dispersion, and, on the other hand, based on the dimensions of the cassette body 3, going beyond which leads to an increase in the overall dimensions of the cartridge or to a decrease in the overall dimensions of the combat elements collected in the cartridge 7. For the same reason, the outer diameter of the peripheral pipe 8 is chosen to be less than or equal to the outer diameter of the central pipe 5. Placement iferiynyh pipe 8 between adjacent submunitions 7 at a predetermined distance from the central tube 5 allows to select in advance the necessary settings of each combat expansion element 7 in a single row (section) of the cassette. This can, for example, be carried out by selecting the mounting distance of each peripheral pipe 8 from the outer diameter of the central pipe 5. If the pipes 8 are placed at the same distance "Ao" from the pipe 5 (see Fig. 11), then the combat elements 7 in a row (section) distributed on the surface of the water around the circumference (see Fig.12). If the pipes 8 are placed at different distances "Ah" and "Au" from the pipe 5 (see Fig. 13), then the combat elements 7 of the row (section) will be distributed on the surface of the water area along the ellipse (see Fig. 14). The outer diameter of the peripheral pipe 8 is selected to be less than or equal to the outer diameter of the pipe 5. By selecting the distance “A” of the fastening of each peripheral pipe 8 from the outer diameter of the pipe 5, you can pre-select the necessary expansion parameters of each combat element 7 in the row (section) of the cartridge, and the expansion parameters of the combat elements 7 installed in different rows (sections) of the cartridge.

In the transverse (except for the front 15) flanges 6 (Fig. 8), radial channels 21 can be formed that extend to the lateral surface of the flanges 6 coaxially with the gas bypass holes 22 adjacent to the flanges 6 of the bushings 23 mounted on the end of the pipe 24 of the combat elements 7. This will allow gas-dynamic to connect the chamber formed around the fuse 17 of the combat element 7 with the gas generator (gas source) 10 of the cartridge. The sleeve 23 is mounted on the end of the tube 24 of the combat elements 7 with emphasis on the transverse flange 6, while the axis of the hole 22 coincides with the axis of the adjacent opening 21 of the flange 6 of the cartridge. This is necessary, on the one hand, to ensure the closure of the gas-dynamic system of the cartridge and, on the other hand, to ensure reliable compression of the combat elements 7 in the longitudinal direction when placing them in the cartridge.

The set of features of the independent claims will improve the reliability and stability of the technical characteristics of both the cartridge itself and the combat elements placed in it, increase the effectiveness of the cartridge and expand the range of its combat use. At the same time, it is possible to carry out typical cassettes in the smallest possible dimensions, significantly reducing their mass-dimensional characteristics in comparison with the design of the prototype.

At the same time, in some specific cases, the design of a single bomb cluster can be performed using the dependent features indicated in the claims. This will allow, due to the dispersion of warheads from different sections of the cartridge with different predetermined speeds relative to each other, obtained upon receipt of the powder gases from the actuation of the gas generator into the shell chambers through the through holes of the front flange and the holes on the walls of the peripheral pipes, to ensure the covering of a rational area of a given water area, increasing, at the same time, the probability of hitting at least one of the scattered combat elements in the target. So, the placement of peripheral tubes between adjacent combat elements in the section will allow you to pre-select the necessary parameters for the expansion of each combat element in the section, as well as the parameters of the expansion of military elements installed in different sections of the cartridge. This can, for example, be carried out by selecting the distance "A" (see Figs. 11 and 13) of the fastening of each peripheral pipe 8 from the outer diameter of the power pipe 5. With the same distance "Ao" of the location of the pipes 8 from the pipe 5 (see Fig. 11 and 12) for each combat element 7 in a row (section), combat elements fly out of the cartridge at a speed of "Vo" and are distributed on the surface of the water area along a circle 25. At different distances "Ax" and "Au" the location of the pipes 8 from the outer diameter of the pipe 5 (see Fig. 13 and 14) for each combat element 7 in a single row (section i) combat elements scatter from the cartridge with speeds of "Vx" and "Vy" and are distributed in the water area along the ellipse 26. At the same time, in the manufacture of typical cartridges, the use of the dependent features indicated in the claims will make it possible to select workable easily executable tested cartridge components that increase reliability and safety of combat elements placed in it.

The cartridge warhead 7 contains (see Fig. 1; 8) a body 27 with a stabilizer 28, a head 29 and a bottom 30, a fuse 17 and a warhead 31. In the bottom part 30, a pipe 24 is installed along the central axis of the munition 7, in the cavity of which a fuse 17 is located adjacent to the warhead 31. At the rear end of the pipe 24 there is a sleeve 23 with a gas bypass hole 22, which can extend beyond the end face of the stabilizer 28 of the combat element. This will allow the use of fuses 17 placed in the cartridge combat elements from the gas-dynamic system of the cartridge.

The combat elements placed in the cartridge can be made in the form of any ammunition necessary for solving a specific combat mission, for example, in the form of small-caliber anti-submarine bombs, concrete-piercing, fragmentation, high-explosive fragmentation and other military elements.

The proposed combat element is directly involved in achieving the technical result of the whole object - a one-time bomb cluster, which consists in ensuring the reliability of the cartridge by engaging the fuse of the military element from the gas-dynamic system of the cartridge.

Thus, the totality of all the above features will improve the reliability of the action and the stability of the technical characteristics of both the single bomb cluster and the combat elements placed in it, increase the effectiveness of the cluster and expand the range of its combat use.

Claims (10)

1. A one-time bomb cluster, including a warhead with a fuse installed in it, a housing with a stabilizer, a central perforated tube with flanges located in the housing, between which rows of combat elements are placed around the tube, peripheral perforated tubes resting on the flanges and resting on the central and peripheral tubes elastic metal shells, profiled along adjacent surfaces of combat elements and peripheral tubes, and a unified gas-dynamic system for unpacking the cartridge, involved Ia fuses of military elements and the spread of military elements. 2. The cartridge according to claim 1, characterized in that the single gas-dynamic system includes a gas generator, made as a single unit and containing three successive powder charges, while the front charge adjacent to the cartridge fuse is gasdynamically connected with a detachable connection of the cartridge head and the front flange, rear - with pyroreceiving devices for fuses of combat elements, and an intermediate charge - with internal cavities formed by elastic metal shells. 3. The cartridge according to claim 1 or 2, characterized in that the single gas-dynamic system includes several interconnected chambers, with the front camera located between the head of the cartridge and the front flange, the second and subsequent chambers are formed by elastic metal shells of the first and subsequent rows of combat elements, and the gas generator is installed in the central channel of the front flange. 4. The cartridge according to claim 1 or 2, characterized in that the peripheral pipes are located at a predetermined distance from the central pipe, and the outer diameter of the central pipe is selected to be greater than or equal to the outer diameter of the peripheral pipe. 5. The cartridge according to claim 3, characterized in that the peripheral pipes are located at a predetermined distance from the central pipe, and the outer diameter of the central pipe is selected to be greater than or equal to the outer diameter of the peripheral pipe. 6. The cartridge according to claim 1 or 2, characterized in that in all the flanges, except the front, there are radial channels extending to the side surface of the flanges coaxially with the gas bypass holes of the warhead elements adjacent to them. 7. The cartridge according to claim 3, characterized in that in all the flanges, except the front, there are radial channels extending to the side surface of the flanges coaxially with the gas bypass holes of the warhead elements adjacent to them. 8. The cassette according to claim 4, characterized in that in all flanges, except the front, there are radial channels extending to the side surface of the flanges coaxially with the gas bypass holes of the warhead elements adjacent to them. 9. A cartridge warhead including a body with a stabilizer, a head and a bottom, a fuse and a warhead, while a pipe is installed in the bottom of the central axis of the warhead, in the cavity of which a fuse is located adjacent to the warhead, and at the rear end of the pipe a sleeve with a gas outlet is located. 10. The combat element according to claim 9, characterized in that the sleeve with a gas bypass hole extends beyond the end of the stabilizer.

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