KR101383679B1 - A weapons coupling for the fixation of a weapon in a weapons transport and storage device - Google Patents

Abstract

Weapon transport and storage devices In particular, the weapon connector for binding a weapon to a torpedo transport and storage device includes at least one movable bar 16 which is engaged in shape engagement into a loading pin formed on the weapon in a locked position. . This bar 16 forms part of a locking mechanism that is spring-biased in the locking direction and automatically locks.

Description

A weapons coupling for the fixation of a weapon in a weapons transport and storage device}

The present invention relates to an inorganic connector for securing a weapon in a weapon transport and storage device, in particular a torpedo transport and storage device, having the configurations specified in the preamble of claim 1.

Weapon transport and storage or torpedo transport and storage are preferably used for military torpedoes to store torpedoes as well as other weapons such as missiles and mines in submarines and to transport them to the torpedo tubes of the submarine with weapons transport and storage. Applied to

Weapons are stored in so-called weapon troughs in weapons transport and storage. Such inorganic mangers are disclosed for example in DE 10 2009 020 323 A1. The weapons stored in this manger must also be mounted there against the longitudinal movement of the manger. For this purpose, an inorganic connector is provided which is arranged in the weapon transport and storage device immediately after the weapon trough. In order to secure the stored weapons in the weapon trough in the weapon connector, these weapons usually comprise a so-called loading pin disposed on the stern-side end of the weapon on the same axis as the longitudinal axis of the weapon. These loading pins have groove-like peripheral recesses around them.

Known weapon connectors, the fixation of the arms is placed on the two retainer teeth of the weapon connector, which are placed facing each other and abutting into the toothed grooves formed on the loading pins and are therefore arranged to lock the weapon into shape engagement in the weapon connector. Is performed by. The fixation of this weapon is carried out by means of the holding tooth detent, which is manually rotated to the position where the holding tooth debuts into the toothed groove of the loading pin. Thereafter, the retaining tooth detent in this position must likewise be manually fixed against the rotational movement to release the loading pin by means of additional locking means. Therefore, the fixing of weapons and the dismantling of weapon straps in the weapon connector are relatively complicated. Another drawback of known weapon connectors is the fact that only weapons of a certain cross-sectional diameter can be fixed to this weapon connector without additional measures, for arms with slightly smaller or larger cross-sectional diameters. This is because the position no longer matches the position of the holding tooth detent in the weapon connector.

In order to solve the above disadvantages, an object of the present invention is to provide a weapon connector that is simple to operate and can allow the fixing of weapons having different cross-sectional diameters in a simple manner.

The above object is achieved by an inorganic connector having the configurations specified in claim 1. Still other advantageous forms of this inorganic connector can be understood through the detailed description as well as the dependent claims and drawings. Here, according to the invention, the configurations and details detailed in the dependent claims may further form a solution according to the invention and according to claim 1 by each case as well as by a combination thereof.

The weapon connector according to the present invention for binding the weapon to the weapon transport and storage device, in particular torpedo transport and storage device, comprises at least one bar. The bar, which can move from the locked position to the unlocked position and vice versa, is preferably arranged in the receiving space in which the loading pins of the weapon to be formed and fixed on the weapon connector are introduced therein. In the locked position, the bar is engaged by shape engagement into the loading pin, in particular into the edge serrated groove and in this way holds the weapon securely in the weapon connector.

According to the invention, this bar is part of an automatic locking mechanism which is biased in the locking direction and the loading pin is fixed by the bar by a locking procedure achieved by the introduction of the loading pin into the inorganic connector. For this reason, in the weapon connector according to the present invention, there is an advantage that the manual locking activities required for the weapon connectors known to date are already performed.

For automatic locking, the locking mechanism of the weapon connector according to the invention comprises, for example, a holding means for holding the bar in the release position against the spring force acting on the bar, before the introduction of the loading pin into the weapon connector. It can be designed as. Here, the holding means typically interact with the loading pins, ie by means of activation by the loading pins, with the loading pins being introduced into the weapon connector, they automatically move to the locked position with the spring loading of the bar and the loading pins. Release the bar that is joining into it.

Contrary to this, another design locking mechanism according to the invention can be envisaged, where the bar is already in the locked position prior to the introduction of the loading pin into the weapon connector, and the loading pin is introduced into the weapon connector, thereby loading It is first locked out of the locking position past the side of the pin by the pin and then automatically locked into the toothed groove formed on the pin by the spring force acting on it.

In the locking mechanism of the design mentioned later, the contact area between the loading pin and the bar is typically applied to the bar with the loading pin, in order to exert such force against the spring force which is continually acting on the bar. It is arranged at an angle to the direction of introduction into the connector. There is a possibility here, for example, of designing the free end of the loading pin in such a way that it is at least partially inclined with respect to the contact area of the bar. Preferably, however, it can be imagined that the bar is introduced into the inorganic connector to have a contact surface for the vaginal loading pin, which is arranged at an angle in the direction of introduction of the loading pin into the inorganic connector. In view of the contact surface of this design, a force component is exerted on the bar by the loading pin, which basically acts transversely to the direction of movement of the loading pin and against the spring force acting on the bar and thus releases the bar. Move in the direction of.

In particular, in order to ensure a reliable attachment of the loading pins in the weapon connector, the weapon connector comprises two bars arranged to face each other. By this, it is preferable that the loading pins penetrate into the intermediate space between the two bars while being introduced into the inorganic connector, wherein in contact with the loading pins, the bars are first of all against the spring force acting on the bars. In the direction away from it, the edge serrated groove formed on the loading pin moves until it is positioned so that the two bars are engaged in a spring-supported fashion therein.

These two bars may be arranged to move linearly in the weapon connector, similar to the latch of the door lock. In this case, the compression springs may be arranged behind the bars in the locking direction, which presses the bars into the locked position. However, preferably the bars are rotatably arranged. The bars are thus mounted rotatably in the inorganic connector in such a way that they each rotate in the direction of the loading pins by a spring force acting on them for locking of the loading pins, preferably the end portions of the bars into the loading pins. Is bound. The bars can be rotated in the opposite direction away from the loading pins and from each other to release the loading pins.

Advantageously, the bars are rotatable such that these forces are not applied to the bar in the unlocking direction to unlock the loading pin, with the pulling force acting on the loading pin fixed opposite to the direction of introduction of the loading pin into the weapon connector. It is mounted in the weapon connector. This is achieved in particular by the design in which the bars in the locked position are engaged into the loading pins in front of their axes of rotation in the direction of introduction of the loading pins into the arms connector. That is, in the direction in which the loading pin is introduced into the inorganic connector, the areas of the bars that engage the loading pin are rotated relative to the introduction opening formed on the inorganic connector and for introduction of the loading pin into the inorganic connector. Is farther than possible rotational axes. Because, when engaged in the loading pins, the bars are arranged to run at an angle to each other in the direction of introduction of the loading pins into the weapon connector, and the pulling force acting against the direction of introduction into the weapon connector is edged by the loading pins. This is because it is impossible to release the lock because it is a force acting in the locking direction which is pushed onto the bars binding into the shape groove.

The rotatable design of the bars allows for predicting rotatably installed shafts that form the axes of rotation of the bars, where the shafts are movably connected to a pallet deployed deployably on the outside of the weapon connector. These two shafts, which form the axes of rotation of the bars, are typically arranged parallel to each other. For the coupling of the movement of the shafts to the moving carriage, levers are arranged on the two ends of the shaft which lie directly opposite one another transversely to the longitudinal expansion of the shafts, these levers being in a rigidly fixed manner. Connected to the fields. At their ends running away from the shafts, these levers are articulated on the carriage in such a way that they are rotatable.

By engaging the movement of the carriage to the shafts forming the axis of rotation of the bars, the carriage is deployable from a first end position in which the bars are located in the locked position to a second end position in which the bars are in the unlocked position. By this, the carriage automatically moves to the first end position when introducing the loading pin into the weapon connector.

In order to release the loading pins or to rotate the bars to their position to release the loading pins, the carriage may preferably be moved manually to its second end position. For this purpose, a handle, ie at least one working grip, is formed on the pallet, which serves to release the bars or to deploy the pallet to the second end position.

The inorganic connector includes two bars having rotational axes formed by shafts movably connected to the carriage in the manner described above, and the two shafts may be biased in the locking direction of the bars by a spring element, for example a torsion spring. In a more preferred design, the carriage is connected to at least one spring element and preferably two spring elements, wherein the spring force of the spring element acts in the direction of the first end position of the carriage. Thus, only one spring element is needed to hold both bars in their locked position. Compression springs may be used as the spring element, which springs are bound on the carriage in such a way as to press the carriage to its first end position and thus press the bars to their locked position. Here, for the release of the bar, it is necessary to move the carriage to its second end position against the spring force of the compression spring.

The carriage may typically be secured to the second end position by shape engagement to ensure that the carriage remains in its second end position when needed. In order to form such a shape coupling between the stop of the inorganic connector and the carriage arranged in such a way that it is deployable thereon, an opening is preferably formed on the carriage, into which a safety pin is attached. The safety pin is locked into a recess formed on the weapon connector at the second position of the carriage. Openings formed on the pallet and grooves formed on the inorganic connector are generally extending perpendicular to the direction of movement of the pallet. In order to release the release at the second end position of the pallet, the safety pin is manually pulled out of the opening formed on the pallet, thereby no longer binding with the groove formed on the weapon connector, and thus the pallet is transported automatically. It is moved to its first end position by a spring force acting on the stand.

In particular, the weapon connector is designed in two parts, in a plane orthogonal to the direction of introduction of the loading pin into the weapon connector, the first portion of the weapon connector for locking the loading pin is arranged in a stationary weapon transport and storage device. And edge movement on the second portion of the connected inorganic connector. This design allows other weapons to be bound to the weapon connector according to the present invention within a certain range of cross-sectional size, where the position of the loading pin formed on the weapon stored in the weapons trough is first determined by the bars of the weapon connector. Inconsistent with the arrangement, the stacking pins are radially overlapped at positions in the weapon connector required to secure the stacking pins. In this case, the edge movement between the first and second portions of the weapon connector is such that the position of the loading pin where the first portion of the weapon connector is to be fixed in the arrangement of the bars in the first portion of the weapon connector to secure the loading pin. Allows to move transversely to the loading direction of the loading pins so that

Inorganic connector of the present invention has the effect that can be easily manipulated and allow the fixing of weapons with different cross-sectional diameters in a simple manner.

1 is a side perspective view of a simplified inorganic connector,
2 is an inorganic connector according to FIG. 1 without an outer housing part, and
3 is a longitudinal cross-sectional view of the inorganic connector according to FIG.

Hereinafter, the present invention will be described in detail with reference to one embodiment shown in the drawings.

The illustrated weapon connector includes a first portion 2 which serves to receive a loading pin (not shown) of the weapon to be fixed by the weapon connector. The second part 4 of the inorganic connector is to be fastened so that the inorganic connector does not move on the weapon transport and storage device, not shown, and in the direction of the longitudinal axis A of the weapon connector, 2) connected to the phase.

The first part 2 of the inorganic connector comprises a housing 6 designed basically in the form of a pot. End of the housing 6 with an opening 10 defining a passageway into the receiving space 12 for the loading pin of the weapon to be introduced into the housing 6 away from the second portion 4 of the inorganic connector- It is designed on the side 8.

Two longitudinal grooves 14 extending parallel to the longitudinal axis A of the inorganic connector are formed in the housing 6 starting from the end-side 8. These two longitudinal grooves 14 are arranged to face each other in diameter in the housing 6. Each of the longitudinal grooves 14 is provided with a bar 16 so as to be rotatable about the rotation axis B. As shown in FIG. The shaft 18 to which the bar 16 is fixed is rotatably mounted about the rotation shaft B. As shown in FIG. This shaft 18 is rotatably mounted in the holes 20 and completely penetrates the housing 6 into the region of the two longitudinal grooves 14 which are usually formed in the longitudinal axis A of the weapon connector. do.

The region 22 of the outer circumferential surface is formed on the housing 6 in a planar flat manner. On this area 22 a carriage 24 is mounted and can be deployed in the direction of the longitudinal axis A of the weapon connector. Two protrusions 26 protruding parallel to the longitudinal axis A of the inorganic connector are formed at the end of the carriage 24 facing the end-side 8 of the housing 6. Each angle of these protrusions 26 is provided with a slot 28 extending parallel to the longitudinal axis A.

In each case the lever 30 is articulated in the slot 28 of the protrusions 26. These levers 30 are planarly flat on the outer circumferential surface of the housing 6 at the two ends of the shafts 18 projecting out of the housing 6 in such a way as to lie directly opposite one another. To the side of the region 22 formed in such a way that it is connected to the shafts 18 in a fixed manner. The installation of the lever 30 in the slots 28 of the protrusions 26 is carried out via connecting pins 32 which are joined into the holes 34 formed on the protrusions 26. These connecting pins 32 are rotatably movable in the long holes 34 and are guided deployably in the longitudinal direction of the long holes 34.

As can be seen from FIG. 2, a spring element 35 in the form of a compression spring abuts the carriage 24 at the rear side of the carriage 24 facing the second portion 4, which spring The carriage 24 is pressed into the end position in the direction of the end-side 8 of the housing 6. Thereby, the bars 16, due to their movement coupled to the carriage 24 via the levers 30 and the shafts 18, allow them to be introduced in the direction of introduction of the loading pin into the inorganic connector. It is pressed to a position protruding obliquely into the storage space 12 (FIG. 2). With this position of the bars 16, the loading pins of the weapons introduced into the receiving space 12 into the toothed grooves where the ends of the bars 18 located in the receiving space 12 are formed on the loading pins. Fixed by engagement.

In order to release the loading pin fixed in the receiving space 12, the carriage 24 is manually deployed in the direction of escape from the end-side 8 of the housing 6 to the second end position, The bars 16 are rotated in such a way that they are no longer engaged in the receiving space 12 of the housing 6. To this end, the carriage 24 comprises a handle in the form of two handles 36 which project on the carriage 24 in two opposite directions transversely to the longitudinal axis A of the weapon connector. . Upon reaching the second end position of the pallet 24, a safety pin 40 guided to move freely in the opening 38, which is typically arranged along the longitudinal axis A of the weapon connector, is not shown in the drawings. It abuts into a recess formed on the housing 6, by which means the carriage 24 is held in shape engagement at its second end position. As soon as the safety pin 40 is pulled out of the recess formed on the housing 6, the carriage 24 is directed toward the end-side 8 of the housing 6 due to the spring element 35 abutting thereon. Moving back to its first end position, the bar 16 moves to its locking position.

As can be seen in FIG. 3, the end of the housing 6 away from the end-side 8 is slanted like a bottle neck. Threaded holes 44 in which some screws 46 are screwed are formed on this end-side 42 of the housing 6. A radially protruding collar 48 is formed on the end of some of the screws 46 protruding out of the threaded holes 44. This collar 48 serves to tie the first part 2 of the weapon connector onto its second part 4.

The second part 4 of the inorganic connector comprises a tubular base 50. This base 50 is coupled on a stationary portion of a weapon delivery and storage device, not shown. The collar 52 projects radially outward on one end of the base body 50 and extends over the entire outer circumference of the base body 50. On the side of the collar 52 away from the base 50, a ring 54 is formed on the peripheral outer end of the collar 52 and at its end-side away from the collar 52. This ring 54 includes an inwardly facing shoulder 56.

The space surrounded by the ring 54 forms part of the receiving space for the collar 48 disposed on the first portion 2 of the inorganic connector. This inner space is closed by a cover 58. The cover 58 includes a central opening 60 and a projection 62 projecting like an annular shaft. The outer diameter of this protrusion 62 corresponds to the outer diameter of the ring 54. An annular projection 64 protruding like another axis whose dimensions coincide with the dimensions of the shoulder 56 formed on the ring 54 is formed on the annular projection 62 of the lid 58.

The lid 58 has a bottle-neck-like incline in the housing 6 before the screw 46 is screwed into a threaded hole 44 formed on the housing 6. It is arrange | positioned in the manner guided through the opening 60 formed in the image. After some of the screws 46 have been screwed into the threaded holes 44, the collar 48 formed on some of the screws 46 bears on the cover 58 on a flat surface facing the collar 52. do. In this condition, the collar 52 is connected to the lid 58, wherein the protrusion 62 formed on the lid 58 is supported on the ring 54 formed on the collar 52. Fastening of the cover 58 on the collar 52 is performed by screws 66.

After fastening the cover 58 on the collar 52, the collar 48 formed on some screws 46 is located in the intermediate space between the collar 52 and the cover 58. The intermediate space between the collar 52 and the lid 58 has a significantly larger diameter than the collar 48 of some screws 46, and the opening 60 formed on the lid 58 has a housing 6. Since the diameter of the weapon connector is significantly larger than the outer diameter of the bottleneck-like part, the first part 2 of the weapon connector can be deployed to a certain extent in any direction orthogonal to the longitudinal axis A of the weapon connector. With respect to its second part 4, this means that the position of the stacking pins allows for the fixation of the weapon with the weapon connector, taking into account the different cross-sectional diameters of the weapons within a predetermined range, for example a predetermined range. To allow.

The operation of the illustrated weapon connector is as follows.

First, the bars 16 are located in a locked position, in which the ends of the bars 16 protrude into the receiving space 12 formed in the housing 6. In order to fasten the weapon to the weapon connector, a loading pin formed on the weapon is introduced into the receiving space (12). Thereby, the loading pin is in contact with the inner surfaces of the bars 16 arranged inclined in the introduction direction of the loading pin. These bars 16 are thereby rotated outwards from each other and bear on the outside of the loading pins. As soon as the groove-like peripheral serrated groove formed on the loading pin is arranged in front of the end regions of the bars 16, the bars 16 rotate into the serrated groove by the spring force acting on the carriage 24. . By this, the carriage 24 on the flat planar area of the housing 6 moves in the direction of the end-side 8 of the housing 6. The weapon is secured in shape coupling to the weapon connector and is secured against axial movement as the bars 16 are engaged into the peripheral recess of the loading pin of the weapon.

To disengage the inorganic engagement in the weapon connector, the carriage 24 is deployed from the end-side 8 of the housing 6 to its second end position by actuating the handles 36. By this, the two bars 16 are rotated away from each other so that they no longer engage with the serrated grooves formed on the loading pins. At this second end position of the pallet 24, the safety pin 40 guided into the opening 38 of the pallet 24 is locked into a recess formed on the housing 6, by which means the pallet 24 is held in shape engagement with the second end position. The weapon can now move until its loading pin is no longer located within the weapon connector.

2: first part 4: second part
6: housing 8: end-side
10: opening 12: storage space
14: longitudinal groove 16: bar
18: shaft 20: hole
22: zone 24: carrier
26: protrusion 28: slot
30: lever 32: connecting pin
34: long hole 35: spring element
36: handle 38: opening
40: screw pin 42: end-side
44: threaded hole 46: some screws
48: color 50: base body
52: collar 54: ring
56: shoulder 58: cover
60: opening 62: protrusion
64: projection 66: screw
A: longitudinal axis B: axis of rotation

Claims (12)

A weapon connector for binding a weapon to a weapon transport and storage device, the weapon connector comprising: at least one movable bar (16) for engaging in shape engagement into a loading pin formed on the weapon in a locked position; ) Is a weapon connector characterized in that it forms part of a locking mechanism that is spring-biased and automatically locks in the locking direction. The method of claim 1, wherein the bar 16 forms a contact surface for the loading pin to be introduced into the inorganic connector, the contact surface is arranged obliquely in the direction of introduction of the loading pin into the inorganic connector. Weapon connector. 3. Inorganic connector according to claim 1 or 2, characterized in that the inorganic connector comprises two bars (16) arranged to face each other. 3. Inorganic connector according to claim 1 or 2, characterized in that the bars (16) are rotatably designed. 5. Inorganic connector according to claim 4, characterized in that the bars (16) in the locked position are fastened into the loading pin in front of their rotational axes (B) in the direction of introduction of the loading pin into the inorganic connector. 6. The rotatable shafts 18 according to claim 5, wherein the rotatably installed shafts 18 form the axes of rotation B of the bars 16 movably coupled to the pallet 24 deployably disposed on the outer side of the weapon connector. Inorganic connector, characterized in that. 8. The weapon connector according to claim 6, wherein the carriage 24 is deployable from a first end position in which the bars 16 are located in the locked position to a second end position in which the bars 16 are in the unlocked position. . 8. Inorganic connector according to claim 7, characterized in that a handle for releasing the bars (16) is formed on the carriage (24). 7. Inorganic connector according to claim 6, characterized in that the carriage (24) is connected to at least one spring element (35) whose spring force acts in the direction of the first end position of the carriage (24). 8. An inorganic connector according to claim 7, wherein the carriage (24) is fixed in shape engagement in the second end position. 11. An opening according to claim 10, wherein an opening into which the safety pin 40 is engaged is formed on the carriage 24, wherein the safety pin 40 is positioned on the inorganic connector at the second end position of the carriage 24. Inorganic connector characterized in that the locking fixed in the groove formed in the. 3. The weapon connector according to claim 1 or 2, wherein the weapon connector comprises: a second part (4) of the weapon connector in which the first part (2) of the weapon connector for locking the loading pin is fixedly disposed on the weapon transport and storage device. And a two-part design, wherein the loading pin is engaged with edge movement in a plane orthogonal to the direction of introduction of the loading pin into the inorganic connector.

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