RU2280837C1 - Cluster nose cone - Google Patents

Abstract

FIELD: armament.

SUBSTANCE: the cluster nose cone of a jet projectile ha a shell with bottoms that accommodates large-sized fighting components with blasting devices, igniters, lead and bursting powder charges, and a piston with a fixing assembly. The separating components of the construction one rigidly fastened to one another by means of detachable piston semi-rings. The piston is fixed in the shell by means of an axial stop and the fixing assembly made in the form of explosive bolts tightening the separating components of the construction and the nose cone bottoms into a single cluster. The lead power charges with through gas vents made in them are positioned in the peripheral zones of the fighting components with a uniform shift relative to one another, and a channel for provision of gas-dynamic coupling of the behind piston and behind bottom working cavities.

EFFECT: enhanced stability of projectile movement in the trajectory, reduced power loads on the separating components of the construction.

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Description

The invention relates to the field of military equipment, namely to cluster warheads (KGCH) for various purposes, which are separated in the process of movement along the trajectory.

One of the most important requirements for structures of this type is the rational placement and reliable fixation of warheads (EBs) in the warhead (MS), which ensure its reliable functioning during launch, movement along the trajectory and separation. Moreover, the greatest difficulties in developing the constructive design of the warhead arise when it is necessary to place large-sized combat elements in it, occupying an almost completely cross-section of the product, which naturally reduces the designer’s capabilities when choosing the most advantageous layout solution. These difficulties increase significantly when developing warheads for multiple launch rockets, rotating in the process of movement along the trajectory.

To some extent, the above issues are resolved in the technical proposals set out in the ISM. So, for example, according to international application No. 88/05523 of July 28, 88, class. F 42 In 13/38 (ISM No. 3, issue 105, 1989), the design of a separable projectile comprising a head with a parachute compartment, a separation unit with a separation charge and forcing elements in the form of cut radial bolts is known. This design of a separable projectile allows the separation of the head from the carrier and the launch of the parachute. But it does not solve issues related to the placement and fixation of combat elements in the body of the head of the shell.

Thus, the objective of this technical solution was to ensure the separation of the head part from the carrier by means of a compartment unit with a compartment charge and forcing elements made in the form of sheared radial bolts.

Common features of the known technical solution with the design of the detachable head part proposed by the authors is the presence of the head part with a charge of the compartment and the forcing unit in the form of bolts.

Also known is the design of a projectile with a parachute stabilization system according to US patent No. 5386781 A dated 12.11.92, class. F 42 B 4/28 (ISM No. 3, issue 081, 1996), comprising a head part, a parachute compartment in the form of a casing with a bottom, a compartment charge, an opening mechanism with a pusher and an opening opening, a safety-actuating mechanism, the first and second connecting elements, actuators, forcing units and rocket engine.

This design allows for the separation of the head from the rocket engine, changing its trajectory to prevent collision with the head and putting the parachute system into operation.

The reasons that impede the achievement of the technical result indicated below when using the known warhead include the fact that it, like in the previous case, does not consider constructive approaches associated with the deployment of large-sized combat elements in warheads. In addition, the required reliability of the functioning of the executive bodies of the munition in conditions of unstabilized and high-speed movement of the warhead is not provided.

Thus, the objective of this technical solution was to develop a separable missile projectile (RRS), which ensures separation of the warhead from the rocket engine, changes in its trajectory to prevent a collision with the warhead, and the launch of the parachute stabilization system.

Common features with the design of the KGCH proposed by the authors is the presence of a warhead with an autopsy charge and a forcing unit.

According to the application of Germany №083506889, class. F 42 In 13/50, 1987, a missile design is known containing a command device and a housing in which submunitions (warheads) are located in the longitudinal direction along the axis. The missile body is equipped with a removable bottom, which relies on combat elements leaving the body after removing the bottom. To eject elements from the hull, the rocket is equipped with a knot for breeding combat elements, which is a knockout charge. The elements are ejected from the housing with the help of a knockout charge, followed by their dispersion by the incoming air flow.

The well-known constructive solution adopted by the authors for the prototype provides for the sequential placement of submunitions in the hull, but does not offer a technical solution that can reliably fix the BE in the hull and prevent the effects of axial, radial and angular movements during the operation of the rocket.

Thus, the objective of the considered structural solution was the development of an inseparable warhead of the cluster type without presenting serious requirements to it to limit shock and vibration overloads on warheads during the operation of the rocket.

Common features with the proposed design of KGCH is the presence of a hull (shell) with a bottom, in which the combat elements are placed along the axis, and a knockout charge, which ensures the release of BE from the hull at a given point on the trajectory.

In contrast to the prototype, in the proposed structural solution, the separable structural elements are rigidly fastened together by means of detachable piston half rings provided with lateral grips interacting with reciprocal ring stops made on adjacent end surfaces of the shared elements. Moreover, the outer diameter of the piston half rings corresponds to the inner diameter of the shell.

The piston of the warhead is fixed in the shell by means of an axial stop made on the inner diameter of the shell and the forcing unit made in the form of explosive bolts that pull together the structural elements and the bottom of the warhead fixed in the shell by means of radial stops.

In this case, the transfer of powder charges placed in the peripheral zones of the combat elements and equipped with through gas ducts are uniformly offset relative to each other by an angle determined by the number of combat elements n (α = 360 / n). And in the bottom of the head part a channel is made that provides an effective gas-dynamic connection between the piston and the posterior working cavities.

These distinctive features, to which the requested amount of legal protection applies, are substantial and sufficient to achieve a new technical result.

The objective of the invention is to develop the design of the head of the cassette type, which provides reliable fixation of combat elements in the shell, eliminating axial, radial and angular movements, as well as their eccentricity during the operation of the projectile (launch, trajectory movement and separation). At the same time, the possibility of reducing power loads acting on shared structural elements during the opening of the projectile is being considered.

The specified technical result is achieved due to the fact that in the known design of the warhead, which includes a shell with bottoms, in which large-sized combat elements with explosive devices are placed, igniter, transfer and expelling powder charges, as well as a piston with a forcing unit, a new the totality of structural units and elements, their relative positions and connections are changed.

In particular, the introduction of piston semirings into the design, equipped with lateral grips interacting with mating ring stops made on adjacent end surfaces of the shared elements (front bottom, combat elements and piston), makes it possible to connect the separating structural elements of the KCH in a rigid block. Wherein:

- the implementation of the outer diameter of the half rings equal to the inner diameter of the shell eliminates the radial displacement of the fastened block during the action of flight loads and separation forces;

- the detachability of the piston rings located in the accumulating cavities formed by the end surfaces of the shared elements and the inner surfaces of the rings and equipped with powder charges allows at the moment of separation of the separated elements beyond the end of the shell to ensure the shooting of the piston half rings in the radial direction, and the separated elements in the axial, which in as a result, it eliminates catch-up, mutual collision and destruction of shared fragments of the warhead.

At the same time, fixing the piston of the head part in the shell by means of an axial stop made on the inner diameter of the shell and the forcing unit made in the form of explosive bolts that pull together the structural elements and the bottom of the warhead to prevent axial displacements of the cartridge during start and separation. Moreover, fixing the front and rear bottoms of the head part in the shell by means of radial stops eliminates the rotation of the cassette under the action of angular overloads arising from the interaction of the lead pin with the launcher guide, as well as the unwinding of the projectile on the trajectory due to skewed plumage.

Uniform displacement of the transfer of powder charges placed in the peripheral zones of the warheads and equipped with through gas ducts relative to each other by an angle determined by the number of EBs in the head makes it possible to reduce the eccentricity and increase projectile stability during movement along the trajectory. At the same time, the implementation of the channel at the bottom of the head of the channel, which provides effective gas-dynamic communication of the piston and posterior cavities (i.e., practical equalization of the pressure in them), allows to maximize the volume of the separation zones and thereby reduce the loading parameters and axial overloads acting in the process of separation .

Thus, the listed design features of the separable warhead allow, due to the proposed variant of fixation units for the separable elements, to develop the warhead with the required stiffness and slight eccentricity necessary for the stable operation of the projectile in all parts of the trajectory. Reducing the level of power loads on the shared elements of the design of the projectile due to a more complete use of the free cavities, namely, connecting to the piston zone (separation zone) of the bottom cavity of the projectile, reduces the passive mass of the developed sample.

The essence of the invention is illustrated by drawings, where in Fig.1 shows a General view of the KCH, in Fig.2-4 - longitudinal and transverse sections of the head part.

The separable warhead of the cluster type incorporates an electronic temporary device 1, a shell 8 with bottoms 3, in which large-sized combat elements 9 with explosive devices (WU) 7, igniter 4, transfer 5 and expelling 11 powder charges, as well as a piston 10 are placed with boost assembly 12.

In the head of the projectile, the separable structural elements are rigidly bonded to each other by means of detachable piston half rings 14 provided with side grips 15 interacting with mating ring stops 16 made on adjacent end surfaces of the separable elements. Moreover, the outer diameter of the piston half rings corresponds to the inner diameter of the shell.

The piston of the warhead is fixed in the shell by means of an axial stop 17 made on the inner diameter of the shell and the forcing unit made in the form of explosive bolts that pull together the structural elements and the bottom of the warhead fixed in the shell by means of radial stops 2.

In this case, the transfer of powder charges placed in the peripheral zones of the combat elements and equipped with through gas ducts 6 are uniformly offset from each other by an angle determined by the number of combat elements. And in the bottom of the head part the channel F _{k is made} , which provides an effective gas-dynamic connection between the piston and the posterior working cavities.

Cassette head works as follows.

At the estimated time, the electronic temporary device 1 gives off an initiating impulse to the ignition charge 4. The products of charge combustion create the pressure and temperature in the front bottom cavity 3 necessary to remove the stage of protection of the explosive device 7 and ignite the transfer charge 5. At the same time, the combustion products of the transfer charge move through the through gas duct 6 of the combat element 9, fill the inter-element cavity W _me and provide the removal of the stage of protection of the WU and the actuation of the transfer charge trace warring element. Ultimately, the products of combustion of the charges enter the pre-piston accumulation zone, and then through the ignition channel in the piston 10 provide the operation of the expelling charge 11.

The combustion products of the expelling charge fill the piston cavity W _zp and simultaneously pass through the channel F _{to the} back cavity W _rear , which during the filling process reduces the level of working pressure in the expulsion zone, and during the discharge process it feeds the reciprocating zone and thereby provides a bottom separation speed at lower values of the maximum loads on the shared elements of the projectile.

When the value of pressure necessary for breaking the burst bolts of the forcing unit 12 is reached in the piston volume W _cp , the separation of the separated elements from the shell 8 begins. When they reach the cut of the shell due to the presence of internal pressure in the accumulating cavities of the warhead, the piston half rings 14 are shot in the radial direction, and shared elements - in the direction of fire. In the future, under the influence of the aerodynamic forces of the incoming air flow, separation of the separating elements, continuing their movement along autonomous trajectories, and their distribution on the affected area is ensured. This implements the gas-dynamic method of separation of the warhead with control of the moment of opening the projectile at a given height, characteristic of multiple-launch rocket shells. In this case, the separation of the trajectories of the movement of combat elements and passive elements of the head and missile part 13 is carried out by rotating the ammunition on the trajectory, the initial power pulse in the separation process and the subsequent aerodynamic impact on the shared elements of the projectile.

Thus, the implementation of the above structural differences in the claimed invention allows us to develop a rational design of KGCH, providing initially reliable fixation, and then reliable opening on the trajectory of all components of the warhead while reducing shock power loads on the shared structural elements.

The stated positive effect is confirmed by the numerous results of the bench and flight tests of prototypes of KGCH equipped with large-sized damaging elements.

Claims (1)

A cluster head of a missile containing a shell with bottoms, in which large-sized warheads with explosive devices are placed, igniter, transfer and blow-out powder charges, as well as a piston with a forcing unit, characterized in that the separating structural elements are rigidly bonded to each other by means of detachable piston half rings equipped with lateral grippers interacting with mating annular stops made on adjacent end surfaces of the shared elem ntov, while the outer diameter of the piston half rings corresponds to the inner diameter of the shell, the piston is fixed in the shell by means of an axial stop and a forcing unit made in the form of bursting bolts that pull together the structural elements and the bottom of the head fixed in the shell by means of radial stops, this transfer of powder charges made through them through gas ducts are placed in the peripheral zones of the combat elements with a uniform displacement relative to each other, in the bottom of the head portion is configured to provide a gas-dynamic channel communication zaporshnevoy Zadonye and work chambers.

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