RU2231744C1 - Parachute container of cluster ammunition - Google Patents

Abstract

FIELD: cluster ammunitions that can be used in bomb clusters for one application, in units of aircraft containers, rocket warheads, etc, in particular, devices for arrangement and subsequent ejection of the parachute system.

SUBSTANCE: the parachute container has a housing in the form of an axially symmetric thin-walled sleeve with a central hole in the bottom and an inner shell, parachute system in a pack cover placed in the cavity between the thin-walled sleeve and the inner cylindrical shell, ammunition unpacking and actuation device. The open part of the sleeve has a movable joint to the ammunition, and the cylindrical shell is joined on the side of the front end face for fixation by means of sharable members with a bush in the form of a sleeve with a central through stepped hole in the bottom, rigidly joined to the ammunition, on the side of the rear end face - to a bush in the form of a sleeve with a central through hole in the bottom and perforated flange on the open end face rigidly joined to the thin-walled sleeve. The container impacking device is positioned in the cavity of the bush with the perforated flange, and the ammunition actuation device - in the cavity of the central shell with a stop against the bush with the through stepped hole in the bottom.

EFFECT: enhanced reliability of the action and expanded range of combat employment of the parachute container, simplified structure and reduced mass and overall dimensions of it.

5 cl, 2 dwg

Description

The invention relates to cluster munitions, which can be used in single-shot bomb cartridges, in blocks of aircraft containers, in the warheads of missiles, etc., and more particularly, to devices for placing and subsequent ejection of a parachute system.

A known embodiment of a parachute system discharged from an aircraft (US Patent No. 2,448,254 of 08/31/1948).

The parachute system, launched from the aircraft, contains a parachute container, one end of which is open and the other is closed by a fixed lid, to which the parachuted item and parachute cords are attached.

A detachable lid is attached to the open end of the container. In addition, in the system there are elements and means interlocking and fixed on the container and on the product, which are attached to the aircraft and to each of the elements in such a way as to keep these elements in mutual engagement when the parachute system is held on the aircraft, and to disengage them, when the system is dropped from the aircraft.

The disadvantages of this design include:

- design complexity;

- low reliability due to the presence of a large number of elements involved in the separation of the container and the release of the parachute;

- the parachute product is not activated on the flight path, which does not allow its use in munitions with an accelerating engine;

- there is no possibility of separating the parachute on the flight path of the product, which does not allow its use in penetrating ammunition.

A known embodiment of the packaging container for a parachute intended for dropping cargo (German Patent No. 3046816 from 12.12.80). The container includes a body in the form of two coaxially arranged cylinders with flanges, between which a parachute system is placed, with slings connected with the load, a pyrotechnic device, a device for pulling the outer cylinder and a cover. The container body is coaxially placed around the tail of the cargo, while the outer cylinder with its open end is movably connected to the load, and the inner flange is rigidly connected to the lid, and the inner cylinder of the outer flange is rigidly connected to the load and has a slot on the side of the open end to output the parachute lines. The pyrotechnic device is placed in the cavity of the tail of the cargo and is tightened by the lid.

The disadvantages of this design of the packaging container include:

- low value of the specific characteristics of the container (the ratio of the mass of the parachute system to the mass of the container);

- the toroidal shape of the container makes it difficult to assemble and leads to a significant increase in its overall mass characteristics;

- there are no elements protecting the parachute system from the combustion products of the pyrotechnic device, which can lead to a sharp decrease in the reliability of the container;

- not provided for the possibility of separation of the parachute on the flight path of the cargo, which dramatically reduces the range of application of the container.

Closest to the proposed parachute container of a cluster munition is a device (container) for ejecting a smoke marker parachute (US Patent No. 3320885 from 05.23.67, NKI 102-35.6 - prototype).

A container for ejecting a parachute and activating a smoke marker includes a body, an unpacking device, a parachute system and a smoke marker launch device. The housing is made in the form of a cylindrical shell cut along the generatrix along the entire length of the front and rear covers.

The devices for unpacking and activating the smoke marker are located in the center of the container body, while the unpacking device is made in the form of two telescopically located spring-loaded bushings, the outer of which is rigidly connected to the back cover, and the device for starting the smoke marker is placed in the cavity of the inner sleeve of the unpacking device and includes a spring-loaded head , detonator and igniter. In the transport position, the sleeves of the unpacking device are engraved, while the inner sleeve is threaded for connection with a smoke marker. The front cover has openings through which parachute slings connected to the smoke marker are removed.

This design of the container allows you to introduce a parachute system into the air stream and almost simultaneously initiate a smoke marker.

The disadvantages of this design include:

- the inability to separate the parachute system on the flight path of the ammunition (cargo), which sharply reduces the range of application of the container;

- the inability to provide two-stage braking of ammunition (cargo) in the air portion of the trajectory due to the almost instant unpacking of the container when it is introduced into the air stream, which ultimately leads to an increase in the overall mass characteristics of the parachute system and the container as a whole, while the possibility of collisions of detachable elements with a carrier;

- design complexity and reduced reliability due to the presence of a large number of interacting parts and assemblies;

- the possibility of violating the integrity of the elements of the parachute system with asymmetric entry into the air stream (interaction of the elements of the parachute system with sharp edges of the cylindrical shell).

The task of the invention is to increase the effectiveness of the parachute container cluster munition.

The technical result consists in increasing the reliability of the action and expanding the range of combat use of the parachute container while simplifying the design and reducing its overall mass characteristics.

The technical result is achieved by the fact that through the use of a parachute container of cluster munition, containing a body in the form of axisymmetric thin-walled cups with a central hole in the bottom and the inner cylindrical shell, a parachute system in the case placed in the cavity between the thin-walled cup and the inner cylindrical shell, the unpacking device and the use of ammunition, while a thin-walled glass with the open part is movably connected to the ammunition, and a cylindrical shell is connected to the side s of the front end with the possibility of fixing by means of shear elements with a sleeve in the form of a glass with a central through hole in the bottom, rigidly connected to the ammunition, on the side of the rear end - with a sleeve in the form of a glass with a central through hole in the bottom and a perforated flange on the open end, rigidly connected to a thin-walled glass, and the container unpacking device is placed in the sleeve cavity with a perforated flange, and the munition activating device is placed in the cavity of the central shell with an emphasis m into the sleeve with a through a stepped hole in the bottom.

Improving the reliability of the parachute container is achieved by:

- a significant reduction in parts and assemblies involved in its functioning;

- exclusion of the possibility of contact of the parachute slings with the sharp edges of a thin-walled cup, since the cup is initially dropped, and then the parachute is introduced into the air stream;

- reducing the energy spent on unpacking the container, since a thin-walled glass with the open part is movably connected to the ammunition.

Expanding the range of combat use of a parachute container in various types of cluster munitions, including those requiring a parachute to be cut off on the flight path (a cylindrical shell is connected from the front end with the possibility of fixation by means of cut elements with a sleeve in the form of a cup with a central through step hole in the bottom).

Simplification of the design of the parachute container is achieved due to the multifunctionality of individual parts and assemblies (cluster munition as a front cover, parachute container as an initiator of ammunition, a sleeve with a perforated flange as:

- cavities for accommodating the unpacking device;

- gas distribution device - initiation of a device for activating ammunition, discharge of a thin-walled glass, emission of exhaust combustion products;

- connecting node - connects a thin-walled glass with a central cylindrical shell.

The overall dimensional and mass characteristics of the parachute container are reduced due to the possibility of using the prepress of the parachute system in the container body, thereby reducing the volume for its placement (the parachute system in the case is placed in the cavity between the thin-walled continuous glass and the axisymmetric cylindrical shell).

The parachute container can be equipped with a toroidal sleeve mounted on the inner cylindrical shell with fixation of the elements to be cut and securing the parachute slings through the split ring, which allows the parachute slings to be fastened to several points, thereby increasing the stability of ammunition movement with the parachute, reducing the load on the sleeve, which ultimately improves the accuracy of the bombing and the specific efficiency of the parachute container.

The parachute container can be equipped with a shell with an external flange, connected movably with the inner cylindrical shell and rigidly with the bottom of the thin-walled cup, which simplifies the design of the inner cylindrical shell and the sleeve with a perforated flange by eliminating the need to seal the cavity between them at the time of dumping the thin-walled cup and contact of the exhaust combustion products of the expelling charge of the unpacking device with the elements of the parachute system, thereby but to simplify the design of the parachute container and increase the reliability of action.

A sleeve with a perforated flange can be made with an annular groove on the inner surface near the bottom with selected ratios of the thickness of the sleeve in the groove to its width (0.05 ... 0.15) and the perforation area of the flange to the area of the bore formed by the inner surface of the shell with flanging and the outer surface of the sleeve with a perforated flange (0.5 ... 0.7), which allows you to use a sleeve with a perforated flange as an obturator of the combustion products of the expelling charge of the unpacking device when the sleeve moves relative to the inner surface of the cylindrical shell, which, in turn, allows to increase the efficiency of the expelling charge of the unpacking device and to ensure the stability of the ballistic characteristics of the ejection elements of the parachute container.

Significant statistics of experimental work have confirmed the fact that a decrease in the ratio of 0.05 ... 0.15 can lead to premature destruction of the sleeve or the need to increase the overall mass characteristics of the parachute container.

An increase in this ratio can lead to a violation of the obturation of the combustion products of the expulsion charge of the unpacking device.

A decrease in the ratio of 0.5 ... 0.7 leads (to exclude the breakthrough of gases into the cavity of the parachute system) to the need to increase the length of the shell with flanging or increase the thickness of the cylindrical shell, and therefore to increase the overall mass characteristics of the parachute container.

The desire to maximize this ratio leads to an increase in the complexity of manufacturing both a sleeve with a perforated flange (the diameter of the flange increases) and a shell with an external flanging (it must be stepped).

The smaller hole in the bottom of the sleeve rigidly fastened to the ammunition can be blocked by a gasket in the form of a thin-walled metal cup placed in the large hole with the open part in the direction of the munition activating device, which allows the gasket to be used as:

- the sealant of the parachute compartment on the sleeve side;

- additional volume for the formation of a gas stream of the device for engaging ammunition;

- material for the formation of a missile body through an opening of a smaller diameter of the sleeve towards the ignition device of the munition.

The above qualities of the gasket can significantly increase the reliability of the involvement of ammunition.

Figure 1 shows a parachute cartridge cluster munition.

Figure 2 shows a parachute container in section along section AA.

A cluster munition parachute container includes a housing 1, a parachute system 2, an unpacking device 3, an ammunition actuation device 5, a thin-walled glass 6, an inner cylindrical shell 7, cut-off elements 8, a sleeve 9 rigidly attached to the munition, a sleeve with a perforated flange 10, a toroidal sleeve 11, a split ring 12, a casing 13 with a flange, a gasket 14.

Parachute container cluster munition works as follows.

At the moment the cluster munition is ejected from the delivery vehicle, a thermal impulse is supplied to the unpacking device 3 of the parachute container, which engages a pyrotechnic moderator, which, after a predetermined period of time, activates an expelling charge. When the chamber 10 of the sleeve reaches a pressure sufficient to break the sleeve in place of the annular groove, a thin-walled cup 6 of the housing 1, part of the sleeve 10 and the shell 13 move in the guide, which serves as an inner cylindrical shell 7, while the wall of the sleeve 10 in place of the annular groove pressed by gas pressure to the inner surface of the shell 7, thereby providing a gas obturation. When the sleeve 10 comes out of contact with the shell 7, the products of combustion of the expelling charge initially enter the chamber formed by the inner surface of the shell 13 and the outer surface of the sleeve 10, and then flow through the perforation of the flange of the sleeve 10 into the atmosphere. With a complete outflow of gases in the atmosphere, a thin-walled cup 6, part of the sleeve 10 and the shell 7 are separated, while the cover is removed from the parachute. A parachute is introduced into the air stream, orienting the longitudinal axis of the munition along the normal to the obstacle surface. In addition, from the heat pulse of the combustion products of the expelling charge of the unpacking device, a pyrotechnic moderator of the device for activating 4 ammunition is activated. After a period of time sufficient to orient the longitudinal axis of the munition along the normal to the obstacle, the expelling charge of the activation device is activated. The gas jet of the activation device forms a throwable body from the gasket 14 and throws it through the smaller opening of the sleeve 9 towards the ignition device of the munition. Thrown body punches a hole in the housing of the ignition device of the munition through which its initiation takes place. At the same time, the locking elements 8 are connected, connecting the parachute system 2 with the sheath 7. The parachute, together with the sheath and fastening elements, is separated from the ammunition.

The implementation of the proposed technical solutions in the design of the parachute container of the cluster munition, confirmed by the results of experimental work, allows to increase the efficiency of the system by increasing the reliability of the action and expanding the range of use of the parachute container while simplifying the design, reducing its overall mass characteristics.

Claims (5)

1. A parachute container of cluster munition, including a housing, a parachute system and a device for unpacking the container and activating the ammunition, characterized in that the housing is made in the form of an axisymmetric thin-walled cup with a central hole in the bottom, the open part movably connected to the munition, and an inner cylindrical shell, between which housed the parachute system in the case, and the cylindrical shell is connected from the front end with the possibility of fixation by means of shear elements with W a can in the form of a glass with a central through hole in the bottom, rigidly connected to the ammunition, from the rear end side - with a sleeve in the form of a glass with a central through hole in the bottom and a perforated flange on the open end, rigidly connected to a thin-walled glass, while the unpacking device the container is placed in the cavity of the sleeve with a perforated flange, and the device for engaging the ammunition in the cavity of the central shell with emphasis on the sleeve with a through step hole in the bottom. 2. The parachute container according to claim 1, characterized in that it is equipped with a toroidal one mounted on the inner cylindrical shell with fixation of the elements to be cut off, with the sleeve open from the munition side and the sleeve perforated at the end, while the parachute system is fastened with a cover with a thin-walled glass and slings - with a toroidal sleeve by means of a split ring. 3. A parachute container according to any one of claims 1 and 2, characterized in that it is provided with a shell with an outer flange at the rear end mounted movably on the inner cylindrical shell, while the flange of the shell is placed between the bottom of the thin-walled cup and the end face of the perforated sleeve flange. 4. A parachute container according to any one of claims 1 to 3, characterized in that the sleeve with a perforated flange is made with an inner annular groove near the bottom, and the ratio of the thickness of the sleeve at the location of the annular groove to the width of the groove is 0.05-0 , 15, and the ratio of the total area of the perforation of the flange to the area of the annular section formed by the inner surface of the shell with a flanging and the outer surface of the sleeve with a perforated flange is 0.5-0.7. 5. A parachute container according to any one of claims 1 to 4, characterized in that a smaller hole in the bottom of the sleeve rigidly connected to the munition is blocked by a gasket in the form of a thin-walled metal cup, the open part being placed in the larger hole towards the munition activating device.

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