RU2156941C1 - Ship-borne missile storage and launching pack - Google Patents

Abstract

FIELD: ship-borne missile launchers. SUBSTANCE: the pack has a sealed body with guides inside it, front destructible and rear covers. The body accommodates brackets, break-off missile fixing members and an electrical connector to the ship control system. The brackets carry a detachable lip with a bevel cut of the free end made for enveloping and fixing of the missile nozzles. Near the front end the pack body accommodates an obturator in the form of an intermittent or perforated, or intermittently perforated annular support for missile, and the rear cover is made detachable with a tight seal. EFFECT: provision of missile launching both from the surface and submerged positions at different launcher erection angles. 6 cl, 5 dwg

Description

 The invention relates to ship containers for storing and launching missiles and can be used in launchers of surface ships and submarines.

 A known container for storing and launching a rocket according to French patent N 2127109, IPC F 41 F 3/00 // F 41 F 9/00, 1972. The known container has a square or rectangular cross section and is made of multilayer polyurethane foam panels providing sufficient rigidity . The container has two guides on which the projectile is held by sliders consisting of polyurethane foam blocks. The combination of a missile, guides, rear and central sliders is a system that, after assembly and inspection, is placed in a container. The bottoms of the container are made of plastic. The front bottom opens like a window under pressure from the front sliders.

 A disadvantage of the known container is that with a vertical launch of a missile from the container, the possibility of a missile falling onto the carrier is not excluded, for example, if the missile is malfunctioning, which reduces the safety of the carrier.

 The closest in combination of features with the claimed invention is a ship container for storing and launching a rocket according to US patent N 3769876, IPC F 41 P 3/04, 1973, which is chosen as the closest analogue of the prototype. Known ship container contains a sealed hull, which has the shape of a rectangular parallelepiped, inside which a rocket is placed. Front and rear, the container body is closed by covers made of brittle material (polystyrene), which are destroyed when the rocket starts. Two half-cylinders are attached to the side walls of the container body, along which the folded aerodynamic surfaces of the rocket slide during its movement after launch. A guide is attached to the upper wall of the container body from the inside, having a groove in the cross section, which includes the rocker arms. For additional fixation of the rocket during its transportation and storage, a U-shaped bracket is provided in the container, the inner surface (pillow) of which is filled with foam. The curvature of the pillow corresponds to the curvature of the rocket body. The pillow moves with the rocket; after exiting the container, it separates. The container has a safety device and a delay device. The latter consists of a rotary bar, which at one end abuts against the front yoke of the rocket. The bar is fixed with a tear-off element (with a shear finger) and in the initial position prevents the movement of the yoke. When the traction force reaches a predetermined value, the finger is cut off, the bar under the pressure of the yoke reclines, and the rocket is released from fixation. A safety device is necessary in case of unintentional starting of the engine. In the initial position, the rear yoke is fixed by two stops connected to the power cylinder, in which the charge and igniter are located. When an electric signal is supplied through the electrical connector from the ship’s launch control system, the charge ignites, the gas pressure lifts the cylinder, and the stops rising with it release the rear yoke from fixing. By the "Start" command, the safety device is first triggered, after which the engine starts. When the delay device is triggered by the force of traction and removes the fixation of the front yoke, the rocket, moving forward, destroys the foam cover and leaves the container.

 One of the ways to ensure the safety of the carrier in the event of a missile malfunction or in the event of an emergency on the carrier, for example, in case of fire, is to release the rocket by accidentally ejecting it from the carrier. In this case, the rocket trajectory should exclude the possibility of a rocket colliding with the superstructure of the carrier and should ensure that the rocket is moved to a safe distance.

 A disadvantage of the known ship’s container is that in case of an emergency release of a rocket it involves the use of an onboard missile control system. In addition, the known container has a limited scope, because involves providing missile launch only from deck installations of surface ships.

 The problem solved by the invention is the creation of a ship container for storing and launching the rocket, ensuring regular launch of the rocket from the surface or underwater position, and also allowing the rocket to be moved away from the carrier during emergency release of the rocket, for example, in the event of an emergency on the media.

 This problem is solved due to the fact that the ship’s container for storing and launching a rocket, containing a sealed enclosure with guides inside, a front destructible and a back cover, brackets and tear-off elements for fixing and holding the rocket, an electrical connector for electrical communication with the ship’s missile launch control system, according to the invention is equipped with a detachable shell secured to brackets and connected by tear-off elements to the tail of the rocket with an oblique cut of the free end made with the ability to capture and fix rocket nozzles. In this case, the container body at the front end is made inside with a shutter in the form of an intermittent or perforated or intermittent perforated annular support for the rocket, and the back cover of the container is removable with an airtight seal.

 Along with this, the guides are made in one piece with the container body and are located evenly around its circumference.

 In addition, the shutter is made in one piece with the container body.

 The shell is mounted on brackets with pyro bolts.

 Tear-off elements are made in the form of explosive bolts.

 The container is equipped with a second electrical connector for electrical communication of the ship’s missile launch control system in an emergency.

 The technical result of the use of the invention lies in the fact that it allows you to create a ship container for storing and launching the rocket, providing launching of the rocket both from the surface and from the underwater position at various angles of inclination of the launcher and allowing rockets to be pulled to the side without the use of the rocket control system from the carrier in case of emergency release of the latter, for example, in case of fire on board the carrier, which excludes the possibility of a rocket falling onto the carrier in case of an emergency.

 In FIG. 1 schematically shows a ship container for storing and launching a rocket, general view, longitudinal section; in FIG. 2 - a shutter in an embodiment in the form of an intermittent annular support, section AA in FIG. 1; in FIG. 3 - the location of the guides in the container body, section BB in FIG. 1; in FIG. 4 - brackets for fixing the rocket and electrical connectors for electrical communication of the ship control system and the rocket, section BB in FIG. 1, rotated; in FIG. 5 - rocket mounts in the container body, element G in FIG. 1.

 In an embodiment of the invention, the container is used in a submarine launcher.

 The ship’s container for storing and launching a rocket comprises a sealed housing 1, inside of which guides 2, 3 are made. In an embodiment of the invention, the container body is made of composite material. The guides are evenly spaced around the circumference of the container body and are a single unit with the latter. The guide 2 in cross section has a groove for the yoke 4 of the rocket 5. On the front, the housing 1 is closed by a destructible cover 6, and on the back by a removable cover 7 with a hermetic seal 8. The destructible cover 6 is made, for example, of spherical plastic and is able to withstand external pressure corresponding to the maximum depth diving submarine. At the same time, the lid is capable of breaking under slight excess pressure inside the container. An obturator 9 is made at the front of the housing. In an embodiment of the invention, the obturator is made in the form of an intermittent annular support for the rocket and is integral with the housing 1. In other embodiments (not shown), the obturator can be made in the form of a perforated annular support or intermittent perforated annular support.

 Brackets 10 are mounted in the rear (bottom) part of the container, on which the shell 11 is detachably fixed by means of pyro-bolts 12. The shell 11 is made with the possibility of covering and fixing the rotary nozzles 13 of the rocket 5 and with the possibility of connection with the tail of the rocket by means of bursting bolts 14. The free end of the shell made with an oblique cut "D". In the bottom part of the container body (on the side of the removable lid 7), electrical connectors 15, 16 are installed for electrical communication of the ship’s launch control system (not shown in the drawing) and rockets. In an embodiment, electrical connector 15 is used to provide a regular launch of the rocket, and electrical connector 16 - if necessary, emergency release of the latter. It is possible to carry out a container with one electrical connector if it allows providing an autonomous electric line for launching a rocket in case of emergency release of the latter.

 A ship container for storing and launching a rocket operates as follows.

 Before loading into the body of the container of the rocket on the tail of the latter set the shell 11 by means of bursting bolts 14. In this case, the oblique cut of the free end of the shell 11 give the desired orientation. As a result of the installation of the shell, the rotary nozzles 13 of the rocket (in a particular embodiment, the rocket may have one rotary nozzle) are fixed in the initial position. After that, the rocket is loaded into the container body by moving along the guides 2 and 3. Then the rocket is secured to the brackets 10 using the shell 11 using pyro bolts 12, after which the electrical connectors 15, 16 are connected to the rocket, and the container body with the mounted rocket is closed with a destructible lid 6 and a removable lid 7. The predetermined position of the rocket in the container in the cross section of the latter is provided by the said guides and the obturator 9, as well as the yoke 4, located in the groove of the guide 2. Moreover, from moving along the longitudinal axis of the container, the rocket is held by brackets 10 through pyro bolts and 12, the shell 11 and the burst bolts 14. In this form, the ship’s container with the rocket can be transported by any means of transport, and is also located in launchers of various carriers (including surface ships), no maintenance required.

 When a missile is launched on a regular basis by a signal from a ship’s launch control system, for example, a submarine, in accordance with the missile launch sequence, a signal is sent to turn on the rocket’s autonomous power sources through electrical connector 15 and the starting engine is started from the onboard control system. The products of combustion of engine fuel from the sub-rocket volume through the gap between the container body and the rocket enter the axillary volume. In this case, the guides 2 and 3 perform the function of a device providing the necessary clearance for the passage of the generated gases. When the pressure inside the container exceeds the external (outboard) pressure, the cover 6 breaks down. Under the influence of pressure in the sub-rocket volume and the thrust of the starting engine, the bolts 14 break and the rotary nozzles 13 of the rocket are released from the shell 11. The rocket becomes controllable and starts moving along guides 2 and 3 container cases. In this case, the yoke 4 of the rocket slides along the groove of the guide 2, keeping the rocket from turning relative to the longitudinal axis, thereby reducing perturbations acting on the rocket. If the overpressure inside the container was insufficient to destroy the cover 6, it is destroyed by the head of the rocket during the movement of the latter. Leaving the container, the rocket is always in a gas bubble, which is formed due to the products of combustion of fuel passing through the obturator 9, made, for example, in the form of an intermittent annular support. This eliminates the possibility of a water hammer when the rocket leaves the container. At the same time, the obturator allows you to reduce the load acting on the rocket, for example, during its inclined launch or when the carrier is rocking due to the load distribution along the obturator width.

 If emergency rocket release is necessary in the event of an emergency, a separate command from the ship’s launch control system via electrical connector 16, regardless of the onboard systems of the rocket, gives a signal to fire pyro bolts 12, which through the shell 11 hold the rocket on the brackets 10, and to start the starting engine. Pyro bolts 12 are torn. Under the influence of pressure in the sub-rocket volume and the thrust of the starting engine, the rocket begins to move along the guides of the container body. In this case, the enveloping nozzle 13 of the rocket, the shell 11 is held on the tail of the rocket by means of explosive bolts 14, and the fuel combustion products completely pass through the shell 11. The rocket exits the container during an emergency release in the same way as during regular launch. After the rocket leaves the container, due to the deflecting component of the thrust of the starting engine due to the presence of an oblique cut of the free end of the shell 11, the rocket is rotated relative to its center of mass and pulled away from the carrier.

 Thus, due to the particular design of the ship’s container for storing and launching the rocket, the invention allows the creation of a ship’s container that allows the rocket to be launched both from the surface and underwater position at various angles of the installation and allows the rocket to be moved away from the carrier without the use of the rocket control system in case of emergency release of the latter, for example, in case of fire on board the carrier, which excludes the possibility of a rocket falling onto the carrier in case of emergency situations, th about it is important from the point of view of fire and explosion safety of the latter.

Claims (6)

 1. A ship container for storing and launching a rocket, comprising a sealed enclosure with guides inside, a front destructible and a back cover, brackets and detachable elements for securing and holding the rocket placed in the housing, an electrical connector for electrical communication with the ship’s missile launch control system, characterized in that it equipped with a detachable shell secured to brackets and connected by tear-off elements to the tail of the rocket with an oblique cut of the free end made with the possibility of covering and fixing the nozzle chum salmon, the container body at the front end is made inside with a shutter in the form of an intermittent, or perforated, or intermittent perforated annular support for the rocket, and the back cover of the container is removable with an airtight seal.  2. The shipping container according to claim 1, characterized in that the guides are made in one piece with the container body and are evenly spaced around its circumference.  3. The ship container according to claim 1 or 2, characterized in that the obturator is made in one piece with the container body.  4. A shipping container according to any one of claims 1 to 3, characterized in that the shell is attached to the brackets with pyro bolts.  5. A shipping container according to any one of claims 1 to 4, characterized in that the tear-off elements are made in the form of explosive bolts.  6. A ship container according to any one of claims 1 to 5, characterized in that it is equipped with a second electrical connector for electrical communication with the ship’s missile launch control system in an emergency.

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