RU2794615C1 - Cluster bomb warhead with projectiles - Google Patents

Abstract

FIELD: rocket engineering.

SUBSTANCE: development of rockets with cluster bomb warheads. Cluster bomb warhead with projectiles contains a fairing and a shell with a bottom, in which projectiles with fuses, arming assemblies and detachable brackets are placed, a piston with a forcing unit, as well as an accumulating and separating cavity equipped with power sources. The accumulating cavity is gas-dynamically connected to the arming cavities by means of peripheral channels formed between detachable brackets of the U-shaped profile, fastening the striking elements due to the radial protrusions included in the reciprocal grooves made on the adjacent radial surfaces of the fairing, the projectiles and the piston. Between the projectiles, which form the arming cavity by means of axial stops, additional power sources with receiving conical bushings are placed, oriented in mutually opposite directions, and the piston is equipped with a V-shaped seal directed by sealing surfaces towards the fairing, and a central ignition channel oriented with the inlet conical sides on the screen of the gas-powder mixture and on the thinning in the body of the separating power source from the output side of the channel.

EFFECT: rational, reliably functioning design of the cluster bomb warhead has been developed, which provides initially reliable fixation, and then reliable opening on the trajectory of all components of the warhead.

1 cl, 5 dwg

Description

The invention relates to the field of rocket technology and can be used in the development of separable cluster warheads (MSV), equipped mainly with large submunitions (PE).

One of the ways to increase the combat effectiveness of rocket projectiles is the development of cluster-type warheads that separate at a given point in the trajectory. When designing and developing such products, the developer needs to solve a number of issues related primarily to:

- with the search for a rational constructive solution that ensures tight packing and reliable fixation of striking elements in the product, preventing the occurrence of shock loads on structural elements in all areas of the functioning of the warhead: during launch, movement along the trajectory and separation of the warhead;

- ensuring reliable operation of the head part with minimum values of power and thermal loads acting on vulnerable structural elements.

These requirements are especially important when creating CHG using large-sized PE, when there is a need to maximize the filling of the cross section of the CHG shell. At the same time, reliable functioning is understood as the departure of the PE to a safe distance, which excludes overtaking and destruction of them by the structural elements of the rocket. At the same time, thermodynamic conditions (pulses of pressure and temperature of the combustion products) must be provided, which are necessary, for example, for the reliable activation of cocking devices - heat sinks that provide cocking of PE fuses and actuation of compartment separation devices.

To some extent, the above issues were resolved in the technical proposals set out in the bulletin of inventions of the Russian Federation. So according to patent RU No. 2187065 C1, 10.08.2002, a design of a cluster warhead is known, which can be used to accommodate large-sized combat elements.

The essence of the invention lies in the fact that in the CHG, which has in its composition a shell with a bottom, in which combat elements with explosive devices, an igniter charge, a forcing unit, a piston and a temporary device are sequentially located, an annular protrusion with radial slotted grooves, the number of which corresponds to the number of combat elements in the head. At the same time, the combat elements are rotated relative to each other at an angle equal to the angle between the slotted grooves, and are equipped with through gas ducts, in the front part of which powder charges and conical expendable washers with throttle channels are placed, and between the combat elements accumulating cavities are formed, limited by the inner surface of the sealing ring and ends of combat elements. Moreover, the igniter and powder charges of combat elements are gas-dynamically connected by means of gas ducts with the accumulating cavities of the warhead.

The use of the invention makes it possible to create cassette warheads with a high packing density of large-sized submunitions that function reliably when divided into trajectories. However, the practical implementation of such a constructive solution comes up against the need to place gas ducts with energy sources in the PE, which is not always possible and rational, because. reduces the useful volume of the striking element and excludes its autonomy.

The common features with the proposed design of the CHG are the presence of a shell with a bottom, in which large-sized striking elements with fuses and cocking devices are placed, working cavities with energy sources, a piston with a forcing unit. Between the ends of the striking elements, a cocking cavity is made, which has a gas-dynamic connection with energy sources.

The closest in technical essence of the solution is the design of the CHG, known from the patent RU No. 2280837 C1, 27.07.2006. and a piston with a forcing unit. The separating structural elements are rigidly fastened together by means of split piston half rings. The piston is fixed in the shell by means of an axial stop and a forcing assembly made in the form of explosive bolts that tighten the separated structural elements into a single cassette. Transfer powder charges and through gas ducts are located in the peripheral zones of combat elements with a uniform displacement relative to each other, and a channel is made in the bottom of the head part to provide gas-dynamic connection between the piston and rear working cavities.

The specified design, adopted by the authors as a prototype, can be used as the basis for the development of the design proposed by the authors, but, as in the previous case, it requires the placement of gas conduits and energy sources directly in the damaging element. This significantly complicates the design of the PE and, when using some liquid fillers, seems impractical.

The objective of the design discussed above was to develop a cluster-type warhead that provides reliable fixation of combat elements in the shell, excluding axial, radial and angular movements, as well as their eccentricity during the operation of the projectile. At the same time, the possibility of reducing the power loads acting on the separable structural elements in the process of opening the head part was considered.

Common features with the proposed design of the CHG is the presence of a shell with a bottom, which contains large-sized striking elements with fuses and cocking devices, working cavities with energy sources, a piston with a forcing unit and detachable half rings.

In contrast to the prototype, in the proposed design solution, the accumulating cavity is gas-dynamically connected to the cocking cavities by means of peripheral channels formed between detachable U-shaped profile brackets that fasten the striking elements due to radial protrusions included in the reciprocal grooves made on adjacent radial surfaces of the fairing, striking elements and piston.

Between the striking elements, which form cocking cavities by means of axial stops, there are additional energy sources with receiving conical bushings oriented in mutually opposite directions.

The piston is provided with a V-shaped seal directed by sealing surfaces towards the fairing, and a central igniter channel oriented from the inlet conical side to the screen of the gas-powder mixture and to the thinning in the body of the separating energy source from the outlet side of the channel.

These distinguishing features, which are covered by the requested scope of legal protection, are essential and sufficient to achieve a new technical result.

The objective of the present invention is to develop a rational design of the CHG, which ensures reliable fixation of the striking elements in the shell and the performance of the head part in the separation process in the absence of gas ducts with transfer energy sources, complicating the technology and cost of manufacturing the CHG, as well as reducing the fill factor of the usable volume of the elements that determine the effectiveness PE actions at the target.

The specified technical result is achieved due to the fact that in the well-known design of the head part, which has a shell with a bottom in its composition, in which large-sized striking elements with fuses and cocking devices are placed, a piston with a forcing unit, detachable brackets, as well as an accumulating and separating cavity, equipped with energy sources, a new set of structural units and elements has been introduced, their mutual arrangement and connections have been changed.

In particular, the presence of a gas-dynamic connection of the accumulating cavity with the cocking cavities through peripheral channels formed between detachable brackets makes it possible to create the necessary conditions in the cocking cavities (pressure and temperature pulses of the combustion products of energy sources) that ensure reliable operation of the devices for cocking fuses of striking elements. At the same time, the presence of detachable brackets of the U-shaped profile, fastening the PE due to the radial protrusions included in the reciprocal grooves made on the adjacent radial surfaces of the fairing, striking elements and piston, makes it possible to combine separable structural elements of the CHG into a rigid block.

The placement of additional energy sources with receiving conical bushings oriented in mutually opposite directions makes it possible to create local zones of high pressure and temperature in the place of direct placement of the cocking devices for PE fuses and, thereby, to increase the reliability of the cocking devices and the transmission of the igniter pulse from the head energy source to separating.

The provision of the piston with a V-shaped seal directed by sealing surfaces towards the fairing makes it possible to close the annular gaps between the shell and the piston, which contribute to the premature entry of combustion products from the accumulating cavity into the separating one and, thereby, to exclude the compression of the charge in the housing until the combustion products enter through the central channel. Thus, on the one hand, the physical factor leading to the ignition failure of the separating energy source is eliminated, and on the other hand, the conditions for triggering the PE fuse cocking devices are provided, which makes it possible to increase the stability and reliability of the CHF separation process.

At the same time, the supply of the piston with a central ignition channel, oriented from the inlet conical side to the screen of the gas-powder mixture and to thinning in the body of the separating energy source from the outlet side of the channel, allows:

- to increase the reliability of the transmission of the igniter pulse supplied to the separating energy source;

- exclude the direct force and thermal effect of the high-temperature jet on the devices for arming the fuses of striking elements during the return movement of combustion products through the igniter channel of the piston and ensure the safety and operability of the arming devices in the process of separating the CHF.

Thus, the practical implementation of the design features listed above makes it possible to develop a simple, compact and reliable design of the CHG, which ensures the placement and fixation of large projectiles in the shell. At the same time, by changing the location and shape of the gas-dynamic path, it was possible, without applying any additional structural measures, to provide the necessary power and heat impulses in the cocking cavities, as well as reliable transmission of the igniter impulse from the storage cavity to the energy source located in the separating cavity.

This approach made it possible to apply a simplified design of an autonomous submunition, excluding the use of additional elements in it (gas pipeline, energy source) and, as a result, to increase the useful volume and effectiveness of the ammunition at the target.

The essence of the invention is illustrated by the drawing, where in Fig. 1 shows a general view of the CHG, Fig. 2-5 - longitudinal and transverse sections of the structure.

The cassette warhead with striking elements contains a fairing 1 and a shell 5 with a bottom 20, in which striking elements 7 are placed with fuses, cocking devices 6, 11 and detachable brackets 4, a piston 14 with a forcing assembly 17, as well as an accumulating 2 and separating cavity 16 , equipped with energy sources 3 and 18.

The accumulating cavity 2 is gas-dynamically connected to the cocking cavities 10 by means of peripheral channels 8 formed between detachable brackets of the U-shaped profile 4, fastening the striking elements 7 due to the radial protrusions 24 included in the reciprocal grooves made on the adjacent radial surfaces of the fairing, striking elements 7 and piston 14.

Between the striking elements 7, forming by means of axial stops 9 of the cocking cavity 10, additional energy sources 21 with receiving conical bushings 22 are placed, oriented in mutually opposite directions.

The piston 14 is provided with a V-shaped seal 23 directed by the sealing surfaces towards the fairing, and a central ignition channel 15 oriented from the inlet conical side to the screen of the gas-powder mixture 13 and to the thinning 19 in the body of the separating power source 18 from the outlet side of the channel.

The operation of the cassette head part begins with the supply at the required time of the initiating pulse to the energy source 3 located in the accumulating cavity 2 of the CHG. The combustion products of the energy source 3 create in the accumulating cavity the pressure and temperature necessary to operate the cocking device 6 and at the same time, through the radial windows in the axial stop 9 of the first PE 7, through the channels between the detachable brackets 4, and also through the peripheral channels 8 between the shell 5 and PE 7 combustion products move to the cocking cavities 10.

Then, through the radial windows between the striking elements 7, the combustion products enter the cocking cavity 10, activate the additional energy sources 21 located there and, having created the necessary pressure and temperature pulses, ensure the actuation of the cocking devices 6, 11 of the striking elements 7.

Further, the products of combustion of energy sources through the radial windows in the axial stop 9 enter the pre-piston zone, from where they enter the cavity 16 of the separating energy source 18 through the central ignition channel 15 and through the thinning 19 ensure its reliable operation.

The combustion products of the separating energy source 18 fill the separating cavity of the head part 16 and when the pressure necessary to destroy the forcing assembly 17 is reached, the separable elements begin to move out of the shell 5. In the process of separation, the combustion products of the separating energy source 18 through the central channel 15 are directed to the screen 13 and, bypassing the fuse, enter the pre-piston zone, which allows, on the one hand, to increase the reliability of the activation of the cocking device 11 of the fuse, and on the other hand, it prevents the destruction of the fuse, which is possible with direct exposure to a high-temperature jet of gas-powder mixture.

When the striking elements 7 pass through the cut of the shell 5, due to the presence of internal pressure in the cavities of the CHG, the brackets 4 are separated in the radial direction, and the striking elements 7 are separated in the firing direction.

After the completion of the separation process of the CHG, due to the actuation of the cocking device 6 with the required delay, the parachute compartments 12 are activated, stabilizing the movement of the PE on the trajectory and providing an approach to the affected surface at an angle of ~ 90°, corresponding to the maximum efficiency of the PE actuation.

Thus, the practical implementation of the combination of the above design differences in the claimed invention allows us to solve the task of developing a simple, compact and reliable design of the cluster warhead, providing initially reliable fixation, and then reliable separation into trajectories of all components of the ammunition.

The invention can be used in the development of multiple rocket projectiles with cluster warheads and, first of all, in the creation of new and modernization of existing designs of warheads with large submunitions for multiple rocket launchers, which reduces the time and cost of testing the developed samples.

The indicated positive effect is confirmed by the results of bench and flight tests of prototypes of cluster warheads made in accordance with the invention.

Claims (1)

Cassette warhead with striking elements, containing a fairing and a shell with a bottom, in which striking elements with fuses, cocking devices and detachable brackets are placed, a piston with a forcing assembly, as well as an accumulating and separating cavity equipped with energy sources, characterized in that it the accumulating cavity is gas-dynamically connected to the cocking cavities by means of peripheral channels formed between detachable brackets of the U-shaped profile, fastening the striking elements due to the radial protrusions included in the reciprocal grooves made on the adjacent radial surfaces of the fairing, the striking elements and the piston, while between the striking elements , forming cocking cavities by means of axial stops, additional energy sources are placed with receiving conical bushings oriented in mutually opposite directions, and the piston is equipped with a V-shaped seal directed by sealing surfaces towards the fairing, and a central ignition channel oriented from the input conical side to the screen gas-powder mixture and thinning in the body of the separating energy source from the output side of the channel.

Images