EP2354751A2 - Container for a jet propelled missile - Google Patents

Abstract

The container (1) has a beam baffle (5) provided with a beam entry port (23) and beam suction (25), which are connected over a flow channel (27). A deflection device (29) is installed in the flow channel. The beam entry port is arranged on the sides of the beam baffle, and the flow channel is partially curved or bent around 10 to 30 degrees, where the deflection device is formed of a part of the wall surface of the flow channel. Wedge surface is formed on the flow channel for partially deflecting propulsion beam of a jet-powered missile (3).

Description

The invention relates to a container for jet-propelled missiles. Such containers are usually used for the transport, protection and launch of jet-propelled missiles, in particular of vertically launched missiles.

Jet-propelled missiles, such as rockets, are launched in different ways. For example, the launch takes place aboard a ship or on land from the ground. Since a propulsion jet of a jet-propelled missile usually has large impulses and high temperatures, it is often necessary to redirect the propulsion jet such that neither the starting missile is impaired in its function nor undesirable damage to the environment of the starting missile occurs. If, for example, the propulsion jet of a missile starting vertically is not deflected, it strikes the ground at high pressure and spreads there in all directions. Loose parts, such as stones, are thrown uncontrollably through the area and can damage the missile itself or other objects. In addition, due to the hot exhaust gases of the drive jet, too high a temperature load can occur. Furthermore, the environment is contaminated by chemically aggressive residues of the drive jet.

Since missiles are often fired from a launching device containing more than one container with a missile disposed therein, there is also the danger that the surrounding containers are adversely affected by uncontrolled thrown by the area objects, the effect of heat or chemical residues of the drive beam at the start of a missile ,

Against the background of the circumstances described above, a jet deflector has hitherto been attached to the starting device, often referred to as the launch platform, which as a rule consists of a steel plate. The beam deflector is aligned in this way the propulsion jets from missiles fired from the launching device strike the beam deflector without being deflected beforehand, deflected by the latter and thus guided away from the starting device. The beam deflector is obviously designed to withstand the pulses and heat loads of missile launchers. This requires a construction with a comparatively large weight, which is expensive to position. Even if starting device and beam deflector, as exemplified in FIG. 1 represented, are integrated in a truck, the repositioning of the starting device is therefore cumbersome.

In addition, the beam deflector is usually used multiple times, resulting in contamination and damage, so that a regular repair of the beam deflector is required.

The present invention is therefore based on the object to provide a low-cost option for deflecting the drive beam of the missile available.

This object is achieved by a container for a jet-propelled missile, which has a Strahlumlenkvorrichtung with a jet inlet opening and a jet outlet opening, wherein the jet inlet opening and the jet outlet opening are connected to each other via a flow channel and in the flow channel at least one deflection device is arranged.

Since the Strahlumlenkvorrichtung with the container for the jet-propelled missile, which is often referred to as a canister, a unit forms, it is disposed of as well as the container after the launch of the missile. The beam deflection device can thus be designed in its strength for a single use, in contrast to the beam deflector described above. This allows a lightweight construction of the beam deflecting device. In addition, no time-consuming cleaning of contaminated components or repair of components is required. In addition, starting devices with containers or missiles arranged therein can be more easily positioned or repositioned. The handling is further facilitated by a reduction of the space, which enables the container according to the invention over a system with the beam deflector described above.

With regard to mobile systems, it has been found that the invention enables increased reliability compared to a mobile system with beam deflector, since a hydraulically or mechanically driven complex facial expressions can be dispensed with for the beam deflector to be folded away for transport.

The respective Strahlumlenkvorrichtung can be easily adapted in the container according to the invention to the arranged in the container missile. A missile of a different type is already arranged in the course of production in a container with another, for this missile optimized Strahlumlenkvorrichtung. As a result, when using the container according to the invention different types of missile can be easily launched with the same starting device without a Strahlabweiser or the like must be adjusted.

An embodiment variant of the invention provides that the jet inlet opening and the jet outlet opening are arranged on different sides of the beam deflecting device, preferably on opposite sides. As a result, the mechanical load on the beam deflecting device can be reduced, thereby reducing its mass.

A variant embodiment of the invention provides that the flow channel is at least partially curved or angled and the at least one deflection device is formed from at least part of the wall surface of the flow channel. In practice, it has a curvature or bending of the flow channel by 10 ° to 30 °, preferably by 15 ° to 25 °, proven.

A development of the invention provides a wedge surface arranged in the flow channel for the at least partial deflection of a drive jet of the missile. The wedge surface engages at a defined angle over a predetermined length and up to a predetermined position, which is referred to as engagement, in the output beam and changed in this way, inter alia, the direction of the drive beam. The engagement can be partially or completely within the drive beam or even extend beyond. If the intervention is only partially within the drive beam, only a part of the drive beam is deflected by the partial surface. In this way, a larger expansion of the drive jet can be achieved, which in turn has a reduced interaction with the environment result, so that, for example, with unconsolidated ground looser soil or loose stones are thrown to a lesser extent. The Geometry of the wedge surface and the guidance of the drive jet caused by it can be optimized so that the load, in particular the pressure load and reaction forces, is minimized on the container. In practice, a wedge surface has proven to form a cutting angle of 10 ° to 50 ° with a longitudinal axis of the container. A wedge surface has proven to be advantageous, which extends in the longitudinal direction of the container measured over a length of 20 cm to 50 cm, preferably over a length of 30 cm to 35 cm.

In a preferred embodiment variant, two side surfaces spaced apart from one another and adjacent to the wedge surface are provided, which form a cutting angle of 0 ° to 20 ° with the longitudinal axis of the container, wherein preferably a cutting angle of 0 ° is provided. If, on the other hand, a cutting angle different from 0 ° is provided, the side surfaces are aligned such that their distance from the longitudinal axis increases in the direction of the jet outlet opening. Since the deflection of the drive jet is based on an interaction of all boundary surfaces of the flow channel, an overpressure area and a negative pressure area in the beam deflecting device can be generated by means of the side surfaces and the deflection effect can be improved by combining the overpressure area with the negative pressure area. To form the negative pressure region, it can be provided that the side surfaces open into a widening space, which has an enlarged cross-section compared with a space delimited by the side surfaces.

In practice, side surfaces have proven to be substantially perpendicular to the wedge surface.

Expediently, plug connections for contacting the container, a pressure relief valve, a moisture indicator or a crank access known per se may be provided on the beam deflecting device, and there preferably on the side of the jet outlet opening.

In an advantageous embodiment of the invention, the Strahlumlenkvorrichtung is hermetically sealed from the environment of the container.

It has been shown that starting operations of missiles arranged in the container can be realized with the container or canister according to the invention, in which very small reaction forces are exerted on the starting device.

The materials used for the beam deflecting device are obviously to be chosen so that they withstand the prevailing at the start of a missile temperatures. At least the deflection devices, for example wedge surfaces or wall surfaces of the flow channel, are preferably made of a refractory material. Should a malfunction occur, such as a hangfire where a missile remains in the vessel, the use of refractory material is particularly well-suited to prevent major damage

Fig. 1

Lastkraftwagenbasierte Startvorrichtung mit einem Strahlabweiser gemäß dem Stand der Technik.

Fig. 2

Teildarstellung eines ersten Ausführungsbeispiels des erfindungsgemäßen Behälters in schematischer Darstellung.

Fig. 3

Schematische Teilschnittdarstellung durch das Ausführungsführungsbeispiel der Fig. 2.

Fig. 4

Schematische Schnittdarstellung durch ein zweites Ausführungsbeispiel des erfindungsgemäßen Behälters.

Fig. 5

Perspektivische Detaildarstellung der Strahlumlenkvorrichtung des Behälters aus Fig. 4.

Fig. 6

Schematische Schnittdarstellung durch die Strahlumlenkvorrichtung aus Fig. 5 entlang A-A.

In the following the invention will be explained in more detail with reference to figures. Where appropriate, elements having the same effect are provided with the same reference numbers. Show it:

Fig. 1

Truck-based launching device with a jet deflector according to the prior art.

Fig. 2

Partial view of a first embodiment of the container according to the invention in a schematic representation.

Fig. 3

Schematic partial sectional view through the exemplary embodiment of the Fig. 2 ,

Fig. 4

Schematic sectional view through a second embodiment of the container according to the invention.

Fig. 5

Perspective detail of the Strahlumlenkvorrichtung the container Fig. 4 ,

Fig. 6

Schematic sectional view through the Strahlumlenkvorrichtung Fig. 5 along AA.

Fig. 1 shows a schematic representation of a arranged on a truck launch device 70 for jet-propelled missile according to the prior art. The starting device 70 is designed for a vertical launch of arranged in conventional containers 72a, 72b, jet-propelled missiles. At the start of a missile arranged in a container 72a, 72b, the drive jet exits at the bottom the container 72a, 72b and impinges on a Strahlabweiser 74, which deflects the drive jet to the rear and in this way reduces deterioration of the containers 72a, 72b by spin-on objects, heat or chemical contamination in the manner described above.

The FIGS. 2 and 3 show in a schematic partial perspective view, or a schematic partial section, a first embodiment of the container according to the invention 1. At these a beam deflecting device 5 is flanged. The beam deflection device 5 has a jet entry opening 23 which, as in FIG Fig. 3 can be seen, a nozzle of a arranged in the container 1 missile 3 faces. A jet outlet opening 25 is arranged on a side of the beam deflecting device 5 opposite the jet inlet opening 23.

The jet inlet opening 23 and the jet outlet opening 25 are connected to one another via a flow channel 27. As Fig. 3 can be removed, the flow channel 27 is curved, so that a wall surface 29 of the flow channel forms a deflection device for a drive jet of the missile 3. In the case of a starting operation of the missile 3 thus the drive beam through the wall surface 29 of the flow channel 27 in the representation of Fig. 3 be deflected upwards. The wall surface 29 of the flow channel 27 is formed in the present example of a refractory material.

The jet outlet opening 25 is provided with a cover 13, which has predetermined breaking points 15. At a start of the missile 3 thus the lid 13 is opened by the drive beam, so that it can escape. As a safety measure, a pressure relief valve is provided on the beam deflection device 5.

For the assembly of the container 1 to a starting device centering pins 19 and a locking pin 21 are provided in the present embodiment. Appropriately, a moisture indicator 7 and a known crank 9 is arranged on the side of the beam exit opening 25. In this way, the moisture indicator and the crank access remain accessible or visible during assembly of the container 1 in a starting device.

Fig. 4 shows a further embodiment of the container according to the invention in a schematic representation. For illustration purposes, a missile 3 is again arranged in the illustrated container 51. As the schematic sectional view of the Fig. 4 can be removed, is flanged to the right end of the container turn a Strahlumlenkvorrichtung 50.

Fig. 5 schematically shows an enlarged projection view of this Strahlumlenkvorrichtung 50 Fig. 4 , A schematic sectional view through this Strahlumlenkvorrichtung 50 along the line AA Fig. 5 is in Fig. 6 played. Like that FIGS. 5 and 6 can be seen, a wedge surface 52 is disposed in the flow channel 27 of the Strahlumlenkvorrichtung 50, which forms with a longitudinal axis 60 of the container 51 has a cutting angle a, which is preferably in the range of 10 ° to 50 °. At the left edge of the picture is in Fig. 6 a nozzle of the missile 3 indicated. The wedge surface 52 thus protrudes into a drive beam emitted by the missile 3, namely by a so-called engagement 55. In the present exemplary embodiment, this engagement only partially engages the drive beam. In principle, however, it is also conceivable that this engagement extends beyond the drive beam.

When the missile 3 is started, the propulsion jet passes through a jet inlet opening 56 into the flow channel 27, where it is partially deflected by the wedge surface 52 and emerges from the beam deflecting device 50 through the jet outlet opening 58.

The partial engagement of the wedge surface 52 in the drive beam causes in this case a strong expansion of the drive beam, which has a reduced interaction of the drive beam with the environment result. In particular, loose ground is thrown up less like stones. The risk of damaging the container 51 or other surrounding objects is thus reduced.

As Fig. 5 shows, the Strahlumlenkvorrichtung 50 two spaced apart side surfaces 54, which in the present case extend parallel to the longitudinal axis 60 of the container 51. Furthermore, the side surfaces 54 in the present embodiment extend perpendicular to the wedge surface 52. The side surfaces 54 open into a widening space 53, which has an enlarged cross section with respect to the space bounded by the side surfaces. If the drive jet flows through the flow channel 27, this results in a combination of an overpressure area with a negative pressure area, whereby the deflection effect is improved. In addition, can be effected with the described embodiment of the Strahlumlenkvorrichtung that the drive jet emerges from the Strahlumlenkvorrichtung with a maximum outflow cross section.

When using the Strahlumlenkvorrichtung 50 according to the representations of 4 to 6 In addition, due to the selected positioning and geometry of the beam deflecting device 50, a protective secondary air vortex is induced, which protects the starting device from the effects of heat and chemical contamination.

In analogy to Strahlenumlenkvorrichtung 5 from the FIGS. 2 and 3 For example, the beam deflection device 50 of the embodiment of FIG 4 to 6 be provided at the beam exit opening 58 with a predetermined breaking points having lid. Furthermore, plug connections, a pressure relief valve, a humidity indicator or a crank access can be provided in an analogous manner. Furthermore, the container 51 can be provided with suitable centering pins and / or locking pins.

Like the embodiments of the Fig. 2 to 6 show the Strahlumlenkvorrichtung 5, 50 can be performed with a comparatively low overall height, so that the handling of the container is not affected by the provision of the Strahlumlenkvorrichtung.

If a reduction of forces acting on the container is desired, this can be achieved by providing a bearing surface or holder in the starting device for the beam deflection device, or a part of it.

LIST OF REFERENCE NUMBERS

1

container

3

missile

5

beam bending

7

humidity display

9

crank access

11

Pressure relief valve

13

Cover on jet outlet

15

Breaking point

17

connector

19

centering

21

locking pin

23

Beam entrance opening

25

Blast opening

27

flow channel

29

Wall surface flow channel

50

beam bending

51

container

52

wedge surface

53

expansion space

54

side surface

55

intervention

56

Beam entrance opening

58

Blast opening

60

Longitudinal axis container

70

Star device on truck

72a

container

72b

container

74

Strahlabweiser

α

cutting angle

Claims (10)

Container (1; 51) for a jet-propelled missile (3)
marked by
a jet deflecting device (5; 50) having a jet inlet opening (23; 56) and a jet outlet opening (25; 58) which are connected to one another via a flow channel (27), wherein at least one deflection device (29; 52) is provided in the flow channel (27) is arranged. Container (1:51) according to claim 1,
characterized,
in that the jet inlet opening (23; 56) and the jet outlet opening (25; 58) are arranged on different sides of the beam deflecting device (5; 50), preferably on opposite sides. Container (1) according to one of the preceding claims,
characterized,
is that the flow channel (27) at least partially curved or angled, and the at least one deflector (29) is formed of at least a portion of a wall surface (29) of the flow channel (27). Container (1) according to claim 3,
characterized in that the flow channel (27) is curved or angled by 10 ° to 30 °, preferably by 15 ° to 25 °. Container (51) according to one of claims 1 to 2,
marked by
a wedge surface (52) arranged in the flow channel (27) for the at least partial deflection of a drive jet of the missile (3). Container (51) according to claim 5,
characterized,
the wedge surface (52) forms a cutting angle (α) of 10 ° to 50 ° with a longitudinal axis (60) of the container (51). Container (51) according to one of claims 5 to 6,
characterized,
that the wedge surface (52) extending in the longitudinal direction of the container (51) measured over a length of 20 cm to 50 cm, especially from 30 cm to 35 cm, extending across. Container (51) according to one of claims 5 to 7,
marked by
two spaced-apart and adjacent to the wedge surface (52) side surfaces (54) which form with the longitudinal axis (60) has a cutting angle of 0 ° to 20 °, preferably a cutting angle of 0 °. Container (51) according to claim 8,
characterized,
in that the two side surfaces (54) extend substantially perpendicular to the wedge surface (52). Container (51) according to claim 8,
characterized,
in that the side surfaces (54) open into an expansion space (53), which has an enlarged cross-section with respect to a space bounded by the side surfaces (54).

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