RU2459176C1 - Multifunctional compartment to separate projectiles - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: multifunctional compartment of projectile separation comprises a body, units to join a head part and an engine, fixation mechanisms, a system to stabilise a detached head part, units of separation, opening, initiation and actuation of head part actuators. The system to stabilise a detached head part has a jacket with a bottom. Units of separation, opening, initiation and actuation of actuators of the head part include powder charges, pistons and forcing elements. Fixation mechanisms of the stabilisation system are installed in head and tail parts of the jacket. Fixation mechanisms of the stabilisation system are arranged as adjacent telescopic guides. The separation unit is made as a central pipe fixed in the tail part of the jacket. The opening unit is arranged in the form of a gas-dynamic mechanism of a piston type. The initiation unit is arranged in the form of a double-channel safety-actuation mechanism fixed in the central pipe. The unit of actuation of actuators is arranged in the form of a working chamber placed in the zone of compartment coupling with the head part. The stabilisation system bottom is equipped with a transition shell and is rigidly connected with the head part bottom.

EFFECT: increased functions of a projectile separation compartment.

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Description

The invention relates to the field of rocketry and can be used in the development of rockets (PC) with detachable warheads (warheads).

The reliability of the operation and the effectiveness of the action of such warheads at the target largely depends on the choice of the design and layout scheme that allows for reliable separation and opening of the warhead, as well as the stability of the stabilization system (SS) deployment in conditions of unstable warhead flight at high speeds in the separation point and, in addition, to increase the reliability of the functioning of the executive bodies of the munition by creating the required values of power and heat pulses in the mechanism ytiya.

According to the application of Germany No. 4002355 from 09/13/1990 (RF ISM, issue 81, MKI F42B, No. 7-9, 1991), a warhead is known for dropping from a projectile in the vicinity of the target. The head part is characterized in that it has a parachute to reduce the speed of movement relative to the ground and a sensitive element to search for the target area. In this case, the parachute is equipped with means that ensure the rotation of the parachute in the direction opposite to the direction of rotation of the head part.

From the above it is seen that the objective of the known technical solution was the creation of parachute rotation means that compensate for the rotation of the head in flight and thereby ensure a stable shape of the parachute (without twisting the lines) and the required braking force when lowering the head in the target area. It should also be noted that in the known design, a detailed description of the elements of fixation, separation, stabilization and opening is not given.

A common feature with the design of the separation compartment proposed by the authors is the presence of a parachute stabilization system in the discharged (detachable) head part, which ensures a decrease in the speed of approach to the target.

According to US application No. 5386781A dated 12.11.1992, the design of a projectile with a parachute stabilization system is also known (RFGKM, issue 081, IPC F42B, No. 3, 1996).

The projectile contains a jet engine, a warhead, a deflector, a pusher and connecting elements. The first connecting elements fasten the pusher to the rocket engine, and the second attach the deflector to the pusher. When a rocket engine is fired from the head, the deflector is pushed out, as a result of which radial forces act on the rocket engine, changing the trajectory of its movement.

The head part contains a detachable unit, exhaust and main parachutes with connecting elements. Parachutes are laid in a certain way inside the body of the head and are closed by covers. The detachable unit is connected to the exhaust parachute and, when fired from the head, throws it outward, providing the opening of the exhaust, and then the main parachute, attached to the head.

The work of the considered design of the projectile with a parachute system having fixation, separation and opening units, to some extent, coincides with the work of the design of the separated rocket projectile proposed by the authors. However, given the other purpose, as well as the absence in the application materials of a detailed description of the structural design of these analog units, their use in the proposed design solution is not possible.

Thus, the objective of the indicated technical solution is the development of a separable rocket projectile, which ensures separation of the warhead from the rocket engine, the launch of the parachute system and the descent of the warhead in the target area, changing the trajectory of the rocket engine to prevent collision with the warhead.

Common signs with the design proposed by the authors is the presence of a stabilization system equipped with mechanisms for fixing it with separable elements of the projectile (rocket engine and warhead), as well as blocks for separating the warhead from the rocket engine and opening the parachute system.

According to the materials of the international application No. 88/05523 of July 28, 1988 (RFISM, issue 105, MKI F42B, No. 3, 1989), the design of a projectile with an expandable parachute is known, having two adjacent one to the other, in one of which the parachute is folded up. For a smooth and reliable separation of these parts (with the subsequent opening of the parachute) they are interconnected by radially arranged bolts. Bolts are destroyed under the influence of gases, which are formed when the charge is triggered and provide separation of the separated parts. Ignition of the charge is carried out using an igniter.

Said multiple projectile is characterized by the presence of a separation unit containing a powder charge and forcing elements made in the form of sheared radially located bolts. Given that the destruction force of the boosting elements is assigned from the condition of ensuring the required stiffness of the projectile, the process of separating the warhead from the missile part is accompanied by axial overloads and high-frequency vibrations passing through the shell of the missile at the time of cutting off the radially located bolts. This has a negative impact on the performance of the executive bodies of the warhead and, first of all, on electronic equipment sensitive to high-frequency shock overloads.

T.O. the objective of this technical solution is to develop the design of a rocket that provides separation of the head from the rocket and the launch of the parachute during power overloads, regulated by the conditions for the destruction of radially located bolts holding the parts to be separated.

Common features of the described missile, adopted by the authors as a prototype, with the proposed design of a multifunctional separation compartment, is the stabilization system unit in the form of a parachute fastened to the head and missile parts, and the unit for separating the head from the missile part, including powder charge and boost elements made in the form of radially arranged bolts.

In contrast to the prototype, in the proposed constructive solution, the stabilization system fixing mechanisms in the body are located in the head and tail parts and are made in the form of adjacent telescopic guides, one of which has segment locks with thrust surfaces of cylindrical and conical shape.

The separation unit is made in the form of a central pipe fixed in the rear part of the casing, equipped with a separation charge and gasdynamically connected with the piston zone, located in the docking area of the compartment with the projectile engine.

The tamper block is made in the form of a piston-type gas-dynamic mechanism, is equipped with a tamper-evident charge and is fixed at the bottom of the stabilization system, while the gas-dynamic mechanism cylinder has a damping piston displacement limiter that is stubbornly interacting with the central tube of the casing fastened to the bottom of the stabilization system by means of radial shear screws.

The initiation block is made in the form of a two-channel safety-executive mechanism fixed in the central pipe and gas-dynamically connected by ignition channels with separation and opening charges.

The actuator activation unit is made in the form of a working chamber located in the docking area of the compartment with the head part and is gasdynamically associated with the autopsy charge and the executive bodies.

The piston of the separation unit is made in the form of an elastic membrane with a peripheral ring stubbornly interacting with the inner annular surface of the casing and the cylindrical surface of the segment retainers.

The bottom of the stabilization system, equipped with a transition shell, is rigidly fastened to the bottom of the head part, for example, by a shell with tightening screws, and has radial gas-dynamic channels with movable plugs made under the shank of the casing.

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 a multifunctional compartment for separating missiles, for example multiple launch rocket, which provides for fixing and opening the stabilization system for the warhead, separation and stabilization of the warhead in flight, initiating and activating the executive bodies of the compartment and warhead for functioning and simultaneously fulfilling all requirements missile flight mission.

The specified technical result is achieved due to the fact that in the known design of the rocket separation compartment, comprising a housing with docking units for the head part and the engine, in which the stabilization system of the detachable head part having a casing with a bottom, as well as separation, opening units, is fixed initiation and activation of the executive bodies of the head part, including powder charges, pistons and forcing elements, a new set of structural units and elements has been introduced, and x mutual arrangement and communication. In particular, the placement of stabilization mechanisms of the parachute stabilization system in the head and tail parts of the casing and their implementation in the form of adjacent telescopic guides, in one of which segmented clamps with thrust surfaces of cylindrical and conical shape are embedded, allows to stabilize the stabilization system in the housing using one constructive technique. In this case, the rigid connection of the bottoms of the head part and the parachute stabilization system, for example, by means of a shell with tightening screws, ensures the elimination of axial clearances and reliable fixation of the stabilization system with the required axial force.

The execution of the separation unit in the form of a central pipe fixed in the rear of the casing, equipped with a separation charge and gasdynamically connected with the piston zone, allows the parachute stabilization system to be placed in the casing with high density and to reduce power loads (pressure, temperature, overloads) during separation due to using the volume of the passive piston zone located at the junction of the compartment with the projectile engine.

The implementation of the autopsy unit in the form of a piston-type gas-dynamic mechanism equipped with an autopsy charge and fixed at the bottom of the stabilization system allows, by choosing the mass of the powder charge and the shear force of the radially located shear screws fastening the bottom and the casing, to provide the required opening speed of the parachute stabilization system. In this case, the installation of a gas-dynamic mechanism in the cylinder of the piston displacement limiter, damping its stubborn interaction with the central pipe, reduces shock loads on the structural elements of the parachute stabilization system during the opening of the parachute and, thereby, increases the stability and reliability of the parachute launch.

The implementation of the initiation unit in the form of a safety-executive mechanism fixed in the central tube and gas-dynamically connected by ignition channels with separation and opening charges is dictated by the practical feasibility of placing the safety-actuating mechanism in the free volume of the central pipe, as well as the reliability of the transmission of initiating pulses to the powder charges through the corresponding channels .

The implementation of the activation unit in the form of an accumulating working chamber located in the docking zone of the compartment with the head part and gas-dynamically connected with the tamper and the executive bodies is functionally predetermined by the expediency of using passive docking zones to create ballistic conditions (most of all pressure and temperature) necessary for reliable operation executive bodies of the head part (powder charges, auxiliary devices, pushers) and other similar mechanisms.

The execution of the piston of the separation unit in the form of a retaining membrane with a peripheral ring stubbornly interacting with the inner annular surface of the casing and the cylindrical surface of the segment retainers, allows to solve a number of important practical problems:

- to exclude the loss of segment elements from the zones of fixation during the assembly process and to ensure reliable fixation of the casing in the housing of the separation compartment;

- to provide a sharp decrease in maximum pressure, and consequently, overloads during the separation process due to the developed surface of the membrane and a multiple reduction in the straining force required to destroy traditional designs of forcing units made, for example, using bursting bolts or an annular groove.

At the same time, the presence of radial gas-dynamic channels with movable plugs made under the tail of the casing at the bottom allows gas-dynamic connection of the accumulating working chamber with the atmosphere after shooting of the casing and movable plugs, thereby eliminating the possibility of prolonged force and thermal effects on the bottom of the head part and parachute stabilization system, as well as the possibility of destruction of the docking zone.

Thus, the design features listed above make it possible to solve the problem and develop a separation compartment, which ensures the reliability of the fixation and insertion of the parachute system under conditions of high-speed propulsion of the projectile at the minimum possible power loads acting on the structural elements of the projectile during separation. Moreover, due to the multifunctionality of the proposed design of the compartment, which provides reliable fixation, separation, opening, initiation and activation of the executive bodies of the warhead, the important practical task of unifying the separation compartments for standard and developed samples of missiles is simultaneously realized, which significantly reduces the time and material costs to create new, more advanced weapons.

The essence of the invention is illustrated in the drawing, where figure 1 shows a General view of the compartment separation.

The proposed design of a multifunctional rocket separation compartment comprises a housing 3 with docking units for the head part 1 and the engine 20. In the housing, by means of fixing mechanisms 6, 18, a stabilization system for the detachable head part 12 is fixed, having a casing 13 with a bottom 14, and also separation units 19, opening 24, initiating 25 and engaging the actuators 28 of the warhead, including powder charges 21, 31, pistons 14, 10 and forcing elements 16, 7, 5.

The fixing mechanism of the stabilization system is made in the form of telescopic guides 13, 3, in which segmented clamps 7, 16 are inserted with thrust surfaces of cylindrical and conical shape.

The separation unit is made in the form of a central pipe 11, mounted in the rear of the casing, equipped with a charge of the compartment 21 and gas-dynamically connected with the piston zone A, located in the docking area of the compartment with the projectile engine.

The autopsy unit is equipped with an autopsy charge 31, a cylinder 4 of the gas-dynamic mechanism, and has a damping displacement limiter 9 of the piston 10, which stubbornly interacts with the central tube of the casing.

The initiation block is made in the form of a two-channel safety-actuating mechanism 25 fixed in the central pipe and gas-dynamically connected by ignition channels with charges of the compartment 21 and opening 31.

The actuator activation unit is made in the form of a working chamber B located in the docking area of the compartment with the head part and is gasdynamically associated with the opening charge 31 and the executive bodies 30.

In this case, the forcing unit of the separation unit 16 is made in the form of a membrane 17 with a peripheral ring 15 that is stubbornly interacting with the annular surface of the casing Sк and the cylindrical surface of the segment retainers Sф, and the forcing unit of the opening unit is made in the form of shear screws 5, rigidly connecting the bottom base 8 with the cylindrical part of the casing 6. Moreover, the bottom of the stabilization system is fastened to the bottom of the head part 29, for example, by means of a shell 1 with tightening screws 2, 27, and has radial gas-dynamic channels with movable plugs E 26 placed under the rear housing portion 13.

The work of the separation unit of the rocket projectile begins by activating the ignition channel of the safety-actuating mechanism 23 and initiating the charge of separation 21. The products of combustion of the charge move along the central pipe 11 and fill the free volume of the piston cavity A. At a pressure corresponding to the force of forcing (≈5 kgf / cm ²⁾ under the effect of propellant gases on the surface of the fixing membrane 17 begins its axial movement, followed by displacement of the peripheral ring 15 relative to the support by erhnostey segment retainers Sf. At the moment of the abutment of the support ring from the cylindrical surface of the clamps due to the piston pressure, the axial force of the tightening of the housing 3 of the compartment and the conical shape of the persistently interacting surfaces, the clamps 16 are pushed into the piston volume A and, thereby, release the stabilization system from engagement with the housing 3, a rigidly fastened assembly docking with the rocket part 20. As a result, under the influence of the pressure of the combustion products of the charge of the separation on the surface of the membrane and the bottom of the casing 14, the stabilization system together with the head part of the compartment It is launched from the missile part and makes an unstabilized flight, which is necessary to reduce the speed along the trajectory to the required value.

At the second stage of operation of the separation compartment, the stabilization system is opened, which includes, for example, a soft parachute or a rigid lobed tail as the executive organs. To this end, at the required speed of the unstabilized descent of the warhead, an ignition pulse is applied to the tamper-evident charge 31 through the second initiating channel of the safety-actuating mechanism. Charge combustion products fill the accumulating working chamber B and provide the creation of power and thermal pulses necessary for actuating thermodynamic actuators 30 type (powder charges, moderators, fuses, safety-actuating mechanisms), necessary, in turn, for I further stages of the functioning of the head of the in-flight and on infected areas.

In the process of filling the accumulating cavity, the products of combustion of the tamper-evident charge act on the piston 10, which transfers the axial force through the central pipe 11 to the walls of the casing and the forcing unit 5. At a pressure corresponding to the forcing force of the tamper, the radially mounted screws 5 are cut and the piston 10 moves along the axis of the cylinder 4. In the process of moving the piston stubbornly interacting with the central pipe 11, the shank 6 of the casing 6 is moved and descends from the guide section of the bottom 8, i.e. opening and commissioning of the stabilization system is provided. As a result of the interaction of the executive bodies (in this case, the parachute) with the incoming air flow, braking and stable descent of the warhead in the target area are ensured. At the same time, due to the presence of a limiter 9 of the axial displacements of the piston 10, at the moment of completion of the casing shooting, shock power loads are damped on the interacting structural elements of the opening unit, as well as the volume is sealed with a stabilization system 12, which prevents high-temperature combustion products from entering the actuator placement area and parachute fabric burnout .

Thus, the practical implementation of the combination of the above design differences in the developed ammunition allows you to create a unified multifunctional design of the separation compartment, ensuring the reliable functioning of rockets for various purposes in the process of separation, opening, stabilization, initiation and activation of the executive bodies of ammunition on the active and passive sections of the trajectory.

The invention can be used in the development of separable missiles with detachable warheads and, first of all, when creating new and modernizing existing MLRS designs, which undoubtedly reduces the time and cost of working out the developed samples. The specified positive effect is confirmed by the results of numerous bench and flight tests of prototypes of multiple rockets, made in accordance with the invention.

Claims (1)

A multifunctional rocket separation compartment, comprising a housing with docking units for the head and engine, in which, by means of fixing mechanisms, a stabilization system for the detachable warhead is fixed, which has a casing with a bottom, as well as separation, opening, initiating and actuating units of the warhead, including powder charges, pistons and boost elements, characterized in that in it the mechanisms for fixing the stabilization system in the housing are located in the head and tail parts of the casing and made in the form of adjacent telescopic rails, in one of which segmented clamps with thrust surfaces of cylindrical and conical shapes are embedded, the separation unit is made in the form of a central pipe fixed in the rear part of the casing, equipped with a separation charge and gas-dynamically connected with the piston zone, located in the docking zone compartment with the projectile engine, the autopsy unit is made in the form of a piston-type gas-dynamic mechanism, is equipped with an autopsy charge and is fixed at the bottom of the stabilization system, while The NDR of the gas-dynamic mechanism has a damping limiter for displacement of the piston stubbornly interacting with the central tube of the casing fastened to the bottom of the stabilization system by means of radially located shear screws, the initiation unit is made in the form of a two-channel safety-actuating mechanism fixed in the central pipe and gas-dynamically connected by ignition channels with charges of the compartment and autopsy, the actuator activation unit is designed as a working chamber, placed located in the docking zone of the compartment with the head part and is gas-dynamically associated with the tamper and the actuators, while the piston of the separation unit is made in the form of an elastic membrane with a peripheral ring that stubbornly interacts with the inner annular surface of the casing and the cylindrical surface of the segment retainers, and the bottom of the stabilization system equipped with a transitional shell, rigidly fastened to the bottom of the head part, for example, by means of a shell with tightening screws, and has radial gas-dynamic channels with Vision plugs performed under the shank casing.