DE102005003751B3 - Shell catching device for belt-memberless ammunition has ammunition feeder of weapon which has weapon-side extractor, ejection pipe and shell damper which is functionally connected to ejection pipe - Google Patents

Abstract

Shell catching device has conveyor (1) for conveying ammunition and ammunition feeder (7) of weapon, which has weapon-side extractor (4), ejection pipe (6) and shell dampener (8) which is functionally connected to ejection pipe. The shell (2) or ammunition ejected with high speed through ejection pipe to shell catching spring (21) which is arranged in between the ejection pipe and shell dampener. During the impingement of shell or ammunition on shell catching spring, the shell or ammunition acts upon the shell dampener and the catching energy is reduced. An independent claim is also included for the cartridge holder.

Description

The The invention relates to a sleeve catcher for unbendable Ammunition for a machine gun, in particular in aircraft and anti-aircraft systems.

at Today's installation systems of machine guns in aircraft and anti-aircraft systems are great Importance of a low installation volume, a low weight, a good handling as well as possible short setup times. All this is also from the point of view of low costs and to check the logistics.

Well known are ammunition feeders in strapped and unbegurted (unbelted) form. The unbranched Ammunition is characterized by the fact that the installation volume in the ammunition magazine usually smaller than strapped ammunition.

So that beats DE 195 01 706 A1 a beltless ammunition feeder system for a medium caliber firearm. The ammunition feed system has a fixed spiral ramp for conveying the ammunition from the ammunition box to the loading and firing system. Each ammunition comes through its sleeve in abutment against the spiral ramp. Between the ammunition box and the system for loading and firing the weapon a conveyor is connected. A chain used here consists of a sequence of elastically designated and deformable chain links. These are each connected in pairs by web waves articulated. On these are stored recordings for the ammunition. Furthermore, the system includes two elastic side edges. During the recoil movement of the weapon, the ammunition box remains fixed: The deformable parallelogram allows the gun-side section of the conveyor to move laterally. The conveyor has an upper clamping member and a lower clamping member to dampen the vibrations of the chain. A return of the sleeves, for example, in the ammunition box is not provided.

Another ammunition supply for a beltless ammunition describes the DE 36 44 513 C2 , In addition to the ammunition container in this case a tear-resistant transport chain is examined in detail tet. A transfer unit between the transport chain and a supply chain of the weapon realizes the transfer of ammunition from the transport chain to the weapon. On the underside of the gear train of this transfer unit are identical to the ammunition transfer on the upper side of a guide wheel and slide rails mounted over which the empties of the cannon can be transferred to the ammunition system. Further details are not provided.

Also the EP 1 024 339 B1 describes an ammunition magazine for a beltless guided ammunition. The transfer of cartridges from ammunition magazine to the weapon via an ammunition feeder. The aim is that in particular when accelerating the ammunition leadership chain no lots arise. It is proposed, as a chain tensioning means, to incorporate a means for influencing the spring constants of the chain tensioning means as a function of the tensioning device and the speed of the tensioning movement. The ammunition feeder itself has an ammunition supply chain which is guided in an endless loop around two pulleys. In the vicinity of the second pulley, a self-loading weapon is provided, which takes over the cartridges, shoots and in turn passes the empty cartridge case to the ammunition supply chain. The way of this return will not be described further. The ammunition supply chain of the ammunition supply device is elastic in a certain way and causes by corresponding restoring forces a reciprocating rotary movement of the transfer device or the non-driven deflection unit and the ammunition guide chain. The ammunition supply chain consists of several successive bowl-shaped receptacles.

The DE 102 07 233 A1 describes a large caliber weapon with a sleeve catcher. This is provided with a sleeve case having a resiliently mounted bottom, so that upon contact of the sleeve with the corresponding forward and backward portions of the weapon, the bottom of the sleeve case is pushed against the pressure of the spring through the sleeve.

The The invention has the object, a return of the sleeves or a Zündversagers one show unbelted ammunition. This should be achieved especially the shot down sleeves through the system again sorted into the ammunition container (Magazine) attributed, so that no additional White space is necessary. Furthermore, it should be easy to handle the loading and unloading time can be reduced.

Is solved the object by the features of claim 1.

The invention is based on the idea for the return of the sleeves (empties) in the ammunition container on the ammunition feeder a preferably weapon-side sleeve guide or sleeve derivation (ejector) to integrate and the Transport the ammunition used chain or conveyor in conjunction with this ejector tube so that the sleeves come to rest in the chain links of the conveyor. The proposed ejector works with catch springs together, which are between throwing tube and sleeve damper, and has the task of defining the ejected at very high speed pods of fused ammunition in the ammunition chain to steer. In this case, the sleeve is directed to a preferably mounted in the housing of a Munitionszuführers sleeve damper. The ammunition feeder is usually part of the weapon and is driven by a drum of the weapon on the drum axis. The sleeve damper dampens the ejected at very high speed pods so strong that they can be caught in the sleeve catching feathers. The sleeve catching feathers, for their part, have the task of preventing the sleeves from rebounding. This is preferably done by a latching in a Ausziehrille the sleeve. As a result, these sleeves are defined guided in the sleeve section of the ammunition chain. The sleeve damper may preferably be equipped as a hydraulic, mass or spring damping system.

Around a trouble-free To ensure functional sequence is in progress provided the invention, the sleeve damper after bring each shot to its original position.

For the proposed solution furthermore offers a conveyor, which held in itself flexible is made up of two sprocket pairs with bearings, a frame, U-shaped Connecting rods connected double chains and guide rails for the ammunition or sleeves consists. The sprockets and the frame is used to transport and guide the ammunition chain. The Bearings of sprockets should movable in the frame for example slots be connected, so that a longitudinal compensation possible with every weapon movement becomes. The chain links are also due to their example U-shaped Shaping preferably designed as spring elements. The chain links are designed as elastic elements, in particular the material properties is exploited and the elasticity of the chain length change results. The ammunition as well as the returned sleeves are in guide rails and captively guided in the ammunition chain on the Ausziehrand the sleeve held axially.

The Armaturseitig housed transmission drives via drum axis on the Conveyor axis on the ammunition chain. The drum axis and the conveyor axis are preferably designed as a coupling element between the weapon and ammunition feeder, so that by axially moving the axes of the weapon and ammunition chain from the ammunition feeder can be separated. This process is usually and Endladevorgang the weapon system desired.

A intermittent feed the ammunition in the actual shot position to be taken after handover to the weapon has the advantage that the feeder does not have the entire and return the weapon for the reloading must go along.

In practice has shown that for the return of the sleeve in the ammunition chain the Sleeve in Cartridge bearing the weapon should have a Mindestliderung, so the ejector can build a minimum voltage. During the ejection process is used the relaxation energy and accordingly when loosening the sleeve from the camp translated into speed. This is preferably in the chamber introduced a defined groove the weapon drum. The position the groove in the chamber is on the geometry and texture the cartridges or ammunition / sleeve Voted. When shot, the gas pressure in the ammunition sleeve this deformed so that they are characterized by permanent deformation in the groove invests. When attaching the ejector, that is, when pulling out of the sleeve of the Ejector so much force or tension apply that in the Groove deformed sleeve over the deformation path is pulled out of the groove and thus the cartridge chamber. This Construction guaranteed thus a cartridge chamber with a defined sleeve extraction and is independent of one Lubrication and the surface the cartridge warehouse.

application finds the solution et al in high-firearm weapons with a beltless ammunition transport system. Here are the shot or a drum cartridge bearing ejected pods over one Buffer damped trapped in a chain system, accurately positioned and placed in a munitions box transported. By the defined pull-out voltage is the otherwise Known error that occurs in such systems avoided. It prevents the sleeve slowed down on their way to the catch position or not with a minimum speed is ejected because in such cases the ammunition transport system over which Weapon controlled, the next shot already rotates before the sleeve has reached its target position.

Based an embodiment with drawing, the invention will be explained in more detail.

It shows

1 in a sectional view, the return of a sleeve in an ammunition chain,

2 in a sectional view the ammunition transfer and the sleeve takeover between ammunition chain and weapon drum,

3 the ammunition chain with ammunition and pods,

4 a chamber in a sectional view without sleeve,

4a a detail view A from 4 .

5 the chamber with sleeve,

5a a detail view A 'from 5 ,

In 1 the principle of the sleeve return is shown, with only the parts essential to the invention have been identified.

With 1 a here shown excerpt conveyor is marked, which in this illustration pods 2 a lost ammunition 3 (not visible here) transported away. The pods 2 be through an arms-side extractor 4 in an ejection position 5 ( 2 ) in one with 6 transferred ejector tube. This ejector tube 6 is preferably in the housing of a Munitionszuführers 7 , which is usually part of a weapon, not shown, involved. With this ejector tube 6 in functional harmony, is one with 8th characterized sleeve damper, which ejected at very high speed sleeves 2 dampens. For a trouble-free operation of the sleeve damper 8th brought to its starting position after each shot. Is the sleeve damper 8th a spring damping system, this can be forcibly guided by its own spring force in the starting position. This forced control is also possible via a cam wheel with control cam (not shown in detail), which itself in the transmission 9 of the ammunition feeder 7 can be integrated.

2 shows in a view the interaction ammunition transport and sleeve removal.

In a known manner drives the transmission 9 by means of the drum axis 10 the weapon over the conveyor axis 11 the ammunition chain 1' for the ammunition feed and tube discharge.

The ammunition chain 1' promotes cartridges from an ammunition container, not shown 3 in the ammunition feeder 7 the weapon. The cartridges or ammunition 3 is in the chain links 12 held and in the area of the sprocket 14 of the conveyor 1 guided. The ammunition 3 will then be in the range of the sprocket 14 weapon side a rotor 15 of the ammunition feeder 7 and in this position by the rotor 15 an arms-side feed star 16 to hand over. This feed star 16 Here, due to the number of drums, there are five notches and five positions for the ammunition 3 on. Other positions are the actual shot position 17 and the ejection position 5 the sleeve 2 ,

With this ejection position 5 standing in functionality, as already described, the ejector tube 6 that the sleeves 2 in a sleeve catching position 18 along a tube lead 19 leads. A sensor 20 serves among other things for functional testing.

After firing the ammunition 3 from the firing position 17 Turn the drum of the weapon and the sleeve 2 is ejected, what the extractor 4 to the edge 22 the sleeve 2 attacks. The ejected at high speed sleeve 2 gets over the ejector tube 6 to sleeve catching feathers 21 directed. Upon impact of the sleeve 2 on the sleeve catching feathers 21 becomes the sleeve buffer or sleeve damper 8th with the sleeve 2 applied. The sleeve damper 8th , here a spring system, springs in and reduces the collection energy of the sleeve 2 , The stroke of the sleeve damper 8th is designed so that the sleeve 2 through the sleeve catching feathers 21 on the extraction area 22 the sleeve 2 be caught. The sleeve 2 is thereby defined in the ammunition chain 1' , The next shot, the system continues to rotate and the sleeve 2 over the ammunition chain 1' returned to the ammunition container. Resetting the sleeve damper 8th is realized in this embodiment preferably by the energy in their own springs.

To reduce the recoil and advance forces that occur during the shot, ie, the weapon with the ammunition feeder 7 makes up to about 40 mm return and forward movements, the weapon is stored in a returning system (not shown) damped. Since the ammunition container is usually rigidly mounted, the transfer of ammunition takes place 3 via a flexible design of the conveyor 1 ,

An in 3 indicated conveyor 1 consists essentially of the sprocket 15 ( 2 ), from guided tours 23 , Bridges 24 , Feeder bridges 25 , Side walls 26 and a magazine-side sprocket 27 , The bridges 24 . 25 as well as the side walls 26 serve to stabilize the conveyor 1 and form the frame of the conveyor 1 , By storing the bearings of the sprockets 14 . 27 about, for example, slots in the context of the conveyor 1 this one gets additional flexibility.

In 4 is a cartridge warehouse 30 of the ammunition feeder 7 or are parts of the warehouse in one Sectional view shown. In the chamber 30 is a defined groove 31 brought in. The position and shape of the groove 31 in the chamber 30 is on the geometry and nature of the cartridge not shown here 3 or her sleeve 2 Voted. With 32 is the bearing housing of the cartridge chamber 30 characterized. 4a shows an enlarged section A of 1 for clear representation of the groove 31 ,

In 5 is the cartridge chamber 30 with the here indicated cartridge 3 with sleeve 2 shown. To the bottom of the sleeve 2 the extractor attacks 4 with the help of which the sleeve 2 from the chamber 30 is transported.

5a shows an enlarged section A 'of 5 which in principle works with the geometric cutout A 4 is identical. When shot is due to the gas pressure in the cartridge case 2 these on the housing 33 deformed so that they are deformed by permanent deformation 34 in the groove 31 invests. When attaching the ejector or extractor 4 this applies so much force or tension that in the grooves 31 deformed housing 33 the sleeve 2 via the deformation path X from the groove 31 or the cartridge chamber 30 is pulled out. This build-up of tension guarantees a higher, predefinable voltage level with a significantly reduced bandwidth.

The constant application of force also realizes a good interaction between the extract of the sleeve 2 from the chamber 30 and catching the same in the chain 1' ,

1

ammunition chain

2

shell

3

ammunition

4

extractor

5

ejection position

6

ejector pipe

7

Munitionszuführer

8th

case damper

9

transmission

10

drum axis

11

Conveyorachse

12

chain links

14

Sprocket

15

rotor

16

feed star

17

firing position

18

Sleeve tuck position

19

sleeve derivation

20

sensor

21

Sleeve catcher

22

Ausziehrand

23

guides

24

bridges

25

Zuführbrücken

26

side walls

27

magazine sided Sprocket

30

Chamber

31

groove

32

bearing housing

33

deformation

Claims (10)

Sleeve catcher for a beltless ammunition ( 3 ), which by means of a conveyor ( 1 ) and an ammunition feeder ( 7 ) is supplied to a weapon, having an arms-side extractor ( 4 ) and an ejector tube ( 6 ) and a sleeve damper ( 8th ) connected to the ejector tube ( 6 ) is operatively associated with a high velocity ejected sleeve ( 2 ) or ammunition ( 3 ) over the ejector tube ( 6 ) to sleeve catching springs ( 21 ) located between the ejector tube ( 6 ) and the sleeve damper ( 8th ), so that upon impact of the sleeve ( 2 ) or ammunition ( 3 ) on the sleeve catch springs ( 21 ) the sleeve damper ( 8th ) with the sleeve ( 2 ) or ammunition ( 3 ) is applied and the collection energy is reduced. Sleeve catcher according to claim 1, characterized in that the sleeve damper ( 8th ) is a hydraulic, mass or spring damping system. Sleeve catcher according to claim 1 or 2, characterized in that the stroke of the sleeve damper ( 8th ) is designed so that the sleeve ( 2 ) or ammunition ( 3 ) by the sleeve catch springs ( 21 ) on a pull-out edge ( 22 ) of the sleeve ( 2 ) and thereby defined in the ammunition chain ( 1 ) comes to rest. Sleeve catcher according to one of claims 1 to 3, characterized in that the conveyor ( 1 ) an ammunition chain ( 1' ), which consists of several chain links ( 12 ), which are connected by connecting rods and for receiving the ammunition ( 3 ) and / or the sleeves ( 2 ) serve. Sleeve catcher according to one of the preceding claims, characterized in that the conveyor ( 1 ) an armside sprocket ( 14 ) as well as a magazine-side sprocket ( 27 ), the bearings of the sprockets ( 14 . 27 ) in the context of the conveyor ( 1 ), which consists of bridges ( 24 . 25 ) and side walls ( 26 ) is formed, are held movable, for example, slots. Sleeve catcher according to one of the preceding claims, characterized in that a defined groove ( 31 ) in a chamber ( 30 ) is introduced, wherein the position and the shape of the groove ( 31 ) on the geometry and nature of the sleeve ( 2 ) is tuned. Cartridge bearing according to claim 6, characterized in that during the firing of ammunition ( 3 ) the sleeve ( 2 ) is deformed so that the sleeve ( 2 ) by permanent deformations ( 34 ) in the groove ( 31 ) applies. Cartridge bearing according to claim 6 or 7, characterized in that when attaching the extractor ( 4 ) this applies so much force or tension that the sleeve ( 2 ) via a deformation path (X) from the groove ( 31 ) of the cartridge chamber ( 30 ) is pulled out. Cartridge bearing according to one of claims 6 to 8, characterized in that the groove ( 31 ) in the entire inner circumference of the cartridge chamber ( 30 ) is involved. Cartridge bearing according to one of claims 6 to 8, characterized in that the groove ( 31 ) and thereby partially in the inner circumference of the cartridge chamber ( 30 ) is introduced.