EP0437739A2 - Cartridge extractor - Google Patents

Abstract

By interposing an easily disconnectable control flap (11), located on the outside of the monoblock (1), between a control bolt (7) and a cartridge ejector, the reliability of a cartridge-ejection device can be improved. It is advantageous, furthermore, if the cartridge ejector is composed of two parts coupled via a spring (27), namely a cartridge pull-out (4) and a pull-out element (18), because load peaks can thereby be further reduced and the cartridge pull-out can be returned completely even before the barrel is fully closed. …<IMAGE>…

Description

The invention is directed to a barrel-barrel weapon with at least one barrel and a cartridge ejection device in the monoblock, which has a cartridge ejector that is movable in the barrel direction per barrel, which when tilting the barrel via a cam on the cartridge extractor and a corresponding guidance of the cam in the breech box from a retrieved into a pre-selected position is movable and makes a reverse movement when stretching, whereby an ejector spring can also be tensioned when the barrel is stretched, and a control bolt leading through the barrel wall is present per barrel, which after firing a shot causes the cartridge ejector to tip in one when tipped Tension position remains, and the tension position can only be canceled when the barrel is completely tilted.

In addition to hunting, such weapons are mainly used for hunting; due to the high number of shots, they are subjected to very heavy loads. The parts of the cartridge ejection device are particularly affected. For reasons of space in particular, the parts cannot be dimensioned in the way that would be required from the stress. If the cartridge ejection device is controlled by the triggering process, it can happen that - because after the end of a hunt or a competition, the feathers of the striking elements are released by hitting them without cartridges - the ejection device is activated the next time the weapon is opened, which is disadvantageous for the weapon , because the cartridge ejection device does not have to do any energy-consuming work due to the lack of cartridges and therefore high voltage peaks occur.

In EP 103 568 B1, the mechanical control of the ejection device by the trigger mechanism is by a control about the gas pressure that arises when a cartridge is fired in the chamber. With such a weapon, a control pin is embedded in the wall of each barrel, which is moved somewhat outwards by the widening sleeve wall, and this minimal movement of the control pin causes the tip of the control pin to positively engage in the cartridge extractor and hold it in a tensioned position can. By actuating an ejector pawl at the end of the tipping of the barrel, this connection is canceled and the impulse transmitted jerkily from a tensioned spring to the ejection device is used to eject the cartridge case.

The cartridge ejection device described in EP 103 568 B1 has the disadvantage that other disadvantages had to be accepted in the implementation of this idea. The control of the clamping device is housed between the barrel and the cartridge extractor, which is extremely unsatisfactory from a manufacturing point of view. The slight movement of the control pin in the running wall by only a few tenths of a millimeter also has a negative impact on reliability, especially since it is impossible to readjust or rework this structure.

The object of the invention is to alleviate the disadvantages mentioned and to increase the durability and reliability of the weapon.

The invention relates to a barrel-barrel weapon according to the preamble, which is characterized in that there is a control flap attached to the outside of the monoblock with a detent, the control flap is movable about an axis transversely to the direction of travel, the control pin does not act on the cartridge ejector, but after delivery of a Shot raises the control flap so that when the control bolt is extended, the catch on the control flap hits an edge on the cartridge ejector and as a result, the cartridge ejector initially remains in the tensioned position when the barrel is tilted further, whereas the movement of the cartridge extractor is not impeded when the control flap is not deployed.

A crucial point of the invention is that the control pin does not act on the cartridge ejector directly from the barrel side, but that in addition to the control pin there is also a control flap which is easily accessible from the outside and whose switching path can be increased due to the leverage effect on the movement of the control pin, and this control element is much easier to handle in terms of production technology, which increases the reliability of the weapon. The movement of the front edge of the catch on the control flap is in the same direction as the movement of the control pin.

In a particularly preferred embodiment of the invention, the cartridge ejector is constructed from two parts, the term cartridge extractor being used for the part of the cartridge ejector which engages the cartridge edge, and the second part of the cartridge ejector, which takes over the control of the cartridge extractor, being referred to as an extractor element.

This division of the cartridge ejector into two has various advantages. The cartridge extractor can be guided in a round hole. There is enough space for such a hole in the monoblock and such a guide does not weaken the monoblock. With a round guide, the cartridge extractor can be of the same design for each barrel, only the extractor elements are different, depending on which side of the barrel they are used for. Protection from twisting the cartridge extractor can be taken over by the extractor element, since the extractor element is secured against twisting by grooves. In advantageous The radial guidance of the cartridge extractor is achieved by means of two mutually facing longitudinal surfaces on the extractor element and on the cartridge extractor, the surfaces allowing the mutual distance between the cartridge extractor and extractor element to change, as will be described later.

According to a special embodiment, the cartridge extractor and extractor element are coupled via a spring, the path of the cartridge extractor being equal to or less than the path of the extractor element which is positively guided by cams. In this way it can be ensured that the cartridge extractor is fully retracted before the closing process is completed and the cartridge can slide into the cartridge chamber through the breech block without pressure.

In addition, the spring reduces the impact load on the cartridge extractor and thus improves the durability and reliability of the weapon. The ejector spring is usually covered by the fore-end. The cartridge ejector is pulled in completely by a control cam via the control cam in the breech box before the barrels are tipped into the breech box. When the barrels are closed, the spring is stretched or compressed between the extractor element and the cartridge extractor, depending on whether it is designed as a tension or compression spring. There are no overloads on the cartridge extractor, which has already been fully retrieved, and on the extractor element which is moved by the cams.

The control pin is secured by steps to prevent it from penetrating too far into the barrel, from falling out and from twisting.

The ejector spring, which is tensioned when the barrels are stretched, should preferably no longer act on the cartridge ejector when the cartridge ejector has traveled 80-90% of its way. Damping elements on the ejector spring should also be preferred acted upon pressure pin or provided on the extractor element to dampen noise. In a preferred embodiment, the movement of the control flap is also damped, preferably by a rubber or plastic ring on the cam of the extractor element.

One embodiment is characterized in that the control flap is guided in a hinge-like manner by tabs and grooves on the monoblock.

A further advantageous embodiment is characterized in that an externally accessible stud screw is provided on the monoblock, by means of which, when it is fully screwed in, movement of the control flap by the control bolt can be prevented. In this way, the automatic ejection can be switched off easily.

Another advantageous development of the device is characterized in that a spring is pressed against the control flap from the monoblock. In this way, the control device can be made "stiff", whereby the reliability can be increased still further, because a lifting of the control flap without a shot being fired can be excluded with certainty.

In an advantageous development of the invention, the cartridge extractors and their guidance in multi-barrel weapons are designed such that a uniform type can be used for each barrel.

Figur 1

Seitenansicht des Monoblocks mit einer Patronenauswurfvorrichtung bei vollständig abgekipptem Lauf;

Figur 2

Seitenansicht des Monoblocks bei nur teilweise abgekippten Lauf in Spannstellung der Patronenauswurfvorrichtung;

Figur 3

Steuerbolzen im Schnitt;

Figur 4

Ansicht der Steuerklappe;

Figur 5

Zwei Schnitte vom Patronenauszieher;

Figur 6

Drei Schnitte vom Auszieherelement;

Figur 7

Schnitt durch die Läufe einer Doppelflinte in Höhe der Steuerbolzen;

Figur 8

Ansicht auf eine Steuerklappe mit einer Einrichtung zum Blockieren der Auswurfautomatik.

Exemplary embodiments of the invention are shown in the drawing and further described below. Show it:

Figure 1

Side view of the monoblock with a cartridge ejection device with the barrel fully tilted;

Figure 2

Side view of the monoblock with the barrel only partially tilted in the cocked position of the cartridge ejection device;

Figure 3

Control pin in section;

Figure 4

View of the control flap;

Figure 5

Two cuts from the cartridge extractor;

Figure 6

Three cuts from the extractor element;

Figure 7

Section through the barrels of a double shotgun at the level of the control bolts;

Figure 8

View of a control flap with a device for blocking the automatic ejection.

The drawing in FIG. 1 shows a monoblock 1 with two barrels 2, 3 in the pre-fetched position of the cartridge extractor 4. This position is always assumed when the barrel is completely bent. If no shot has been fired, the cartridge extractor 4 holding the cartridge sleeve 4 gradually moves into this position during tilting due to the ejector spring 5 designed as a compression spring. When a shot has been fired, the cartridge extractor 4 engages in a clamping position, as shown in FIG. 2. The blockage of the cartridge extractor movement is only lifted when the barrel is completely tilted. This is done in that the control flap is pressed inwards by an extension in the area of the hinge of the lock box and thus the catch 17 releases the cam 6. The empty cartridge case is ejected by the pulse transmitted by the ejector spring 5.

The movement of the cartridge extractor 4 takes place via a cam 6 which is positively guided in the lock box in such a way that the cartridge extractor is guided from the retrieved to the retrieved position when tilted or from the retrieved to the retrieved position when closing. With a double shotgun, such cams are attached to both sides of the barrels.

A control pin 7 is embedded in the wall of the barrel 2, the control pin is shown in section in FIG. 3. It has a shoulder 8 which abuts a corresponding edge in the running wall. This ensures that the tip 9 of the control bolt 7, which is adapted to the cartridge case, does not protrude too far into the barrel. An edge 10, created by milling on the other side of the control pin 7, enables the control pin 7 to be supported on a control flap 11, thereby protecting it from twisting and falling out.

The control flap 11 is movable about an axis 12. It is shown in Figure 4. It has a longer arm 13. If the control pin 7 pushes the control flap 11 slightly away from the barrel (in the drawing in FIGS. 1 and 2 from the plane of the drawing), the movement thereby caused at the end 14 of the arm 13 leads to a movement opposite the pin increased movement. On the control flap 11 there are connecting flaps 15 which, in conjunction with corresponding grooves 16 (FIG. 8) in the monoblock 1, act as a hinge. The control flap 11 has a catch 17 which corresponds to an edge on the cam 6 of the cartridge ejection device. As will be explained further below, the cartridge ejector is in two parts and the cam 6 is fastened to an ejector element (FIG. 6) which is connected to the cartridge extractor 4 via a spring, but this is of no importance for the function of the catch.

When the barrel is completely closed, the cartridge extractor 4 is pushed a little more than shown in FIG. 2 into the monoblock 1. The ejector spring 5 is under maximum tension in this state.

The ejector spring 5 is guided by a bolt 19, which in turn is held in a spring counter bearing plate 20a by a bushing 20 and is guided axially displaceably in a bore in the monoblock 1; the bolt 19 has a collar 21 towards the monoblock 1 which, like the bushing 20, serves as a spring counter bearing. The position of the collar 21 on the bolt 19 is determined so that in the pre-fetched position of the cartridge extractor 4 there is still some play for the cartridge extractor 4 (5-15% of the total travel). By introducing intermediate rings between the collar 21 and the ejector spring 5, the spring force can be changed and thus the throwing distance of the empty cartridge case can be changed.

FIGS. 5 and 6 show the two parts of the cartridge ejector, the cartridge extractor 4 and the extractor element 18, from which the cartridge ejector is preferably composed. The cartridge extractor 4 has a cylindrical base body 22, which enables circular guides in the monoblock in the area of the current. With such a design, the cartridge extractor 4 for the upper and lower barrel 2, 3 can be the same. The cartridge extractor 4 is secured against rotation by the extractor element 18, which is shown in section in FIG. 6, in which the structure on the right of the piece on the left of the rifle (mirror image) differs.

When the cartridge extractor 4 is assembled with the extractor element 18, two mutually parallel surfaces 23, 24 lie one on top of the other, and this ensures that the extractor element 18, which is guided in the area of the cam 6 anyway, also secures the cartridge extractor 4 against rotation. In the upper part of FIG. 5 there is also a screw 25 which can only engage in a thread 26 in the extractor element 18, but which slides within the cartridge extractor 4. Due to a spring 27 there is a different axial movement of the cartridge extractor 4 and extractor element 18 possible. A reduction in voltage peaks is thereby achieved. However, it is also ensured in a simple manner that when the weapon is closed, the cartridges are drawn in in good time and the cartridges do not touch the breech box. As soon as the cartridge extractor 4 is drawn in before the barrels have completely tilted, the closing movement due to the spring 27 only leads to a movement of the extractor element 18.

A damping element 28 in the form of an O-ring is attached to the cam 6 on the extractor element 18 in a bore, by means of which the impact of the control plate (edge 29 on the cam 6) is braked.

7 shows the interaction of the control pin 7 with the control flap 11. It can be seen in particular that the control of the cartridge extractor 4 by the control flap 11 is on the outside of the monoblock 1 and is therefore easily accessible. It can also be seen that the cartridge extractor 4 can be guided in a round bore 30 in the monoblock 1 without the monoblock 1 being weakened inadmissibly.

The ejector device according to the invention is shown in FIG. 8 with a further special feature. One recognizes the cartridge extractor 4, the extractor element 18 and the control flap 11 driven by the control pin 7, which can be tilted about the axis 12, in this position the catch 17 against the cam 6 on the control flap 11 blocking the movement of the cartridge ejector (clamping position) . In a threaded bore 31 in the monoblock 1 there is an internal head screw 32 which can be screwed in so far that its tip extends into a bore 33 at the end 14 of the longer arm 13 of the control flap 11. This prevents the control flap 11 from tilting about the axis 12 through the control pin 7 into the clamping position. Such a simple switch-off of the automatically operating cartridge ejection device is desirable, which, however, has not hitherto been possible with known rifles for reasons of space alone.

With the screw 32, the mobility of the control device can also be changed. According to EP 103 568 B1, the control pin 7 should be "stiff". Such a condition is difficult to meet or to maintain over a long period of time. In the device according to the invention, the stiffness can also be taken over by the control flap 11 as the element which transmits and reinforces the bolt movement. Specifically, the mobility is changed, for example, by the pressure of a spring 34, which can be pressed more or less strongly by the screw 32 onto the longer arm 13 of the control flap 11.

The triggering of the clamping position in the case of empty cartridge cases towards the end of the tilting process takes place through a projecting surface on the lock box, through which the control flap 11 projecting somewhat from the monoblock 1 is pressed towards the barrel, with the result that the bolt 7 over the catch 17 the control flap 11 can slide away and the ejection spring 5 quickly relaxes.

List of reference symbols

1

 Monoblock

2.3

 Run

4th

 Cartridge extractor

5

 Ejector spring

6

 cam

7

 Control pin

8th

 Heel on the control pin

9

 Tip of the control pin

10th

 Edge on the control pin

11

 Control flap

12

 Axis around which the control flap can be rotated

13

 longer arm of the control flap

14

 End of the longer arm of the control flap

15

 Connection flaps on the control flap

16

 Groove

17th

 Rested

18th

 Extractor element

19th

 bolt

20th

 Rifle

21

 Federation

22

 Basic body

23

 Area on the cartridge extractor

24th

 Area on the extractor element

25th

 screw

26

 Thread in the extractor element

27th

 feather

28

 Damping element

29

 Edge on the cam

30th

 Hole in the monoblock for guiding the cartridge extractor

31

 Hole with thread in the monoblock for receiving a screw 32

32

 screw

33

 Hole in the control flap

34

 feather

Claims (10)

Drop barrel weapon with at least one barrel (2, 3) and a cartridge ejection device in the monoblock (1), which has a cartridge ejector movable in the barrel direction for each barrel (2) which, when the barrel is tilted, has a cam (6) on the cartridge extractor (4) and one Appropriate guidance of the cam (6) in the lock box can be moved from a retrieved position to a retrieved position (Figure 1) and which makes a reverse movement when the barrel (2, 3) is stretched, while an ejector spring (5) can also be tensioned when stretching , and for each barrel (2) there is a control pin (7) leading through the barrel wall, which after firing a shot causes the cartridge ejector to remain in a cocking position when tilted, and the cocking position can only be released when the barrel is completely tilted, characterized in that that there is a control flap (11) with a catch (17) attached to the outside of the monoblock (1), the control flap (11) about an axis (12) transverse to the running direction (2) is movable, the control pin (7) does not attack the cartridge ejector but, after firing a shot, raises the control flap (11) so that when the control pin (7) is extended, the catch (17) on the control flap (11) against an edge (10) comes into contact with the cartridge ejector and as a result the cartridge ejector initially remains in the clamping position (FIG. 2) when the barrel (3) is tilted further, whereas the movement of the cartridge ejector is not impeded when the control flap (11) is not opened. Drop barrel weapon according to claim 1, characterized in that the cartridge ejector is constructed in two parts, from a cartridge extractor (4) and an extractor element (18). Drop barrel weapon according to claim 1 or 2, characterized in that the cartridge extractor (4) and the extractor element (18) are elastically coupled via a spring (27) so that the path of the cartridge extractor (4) is equal to or less than the path of the Can be cams (6) forced extractor element (18). Drop barrel weapon according to one of claims 1 to 3, characterized in that the cartridge extractor (4) has a round guide and it is secured against rotation in that it has a longitudinal surface (23) on a corresponding longitudinal surface (24) of the guided extractor element (18) is present. Drop barrel weapon according to one of Claims 1 to 4, characterized in that the cartridge extractors (4) are designed identically for each barrel. Drop barrel weapon according to one of claims 1 to 5, characterized in that the effect of the ejector spring (5) on the cartridge ejector no longer extends to the last part of the path of the cartridge ejector in the pre-hollow position. Drop barrel weapon according to one of claims 1 to 6, characterized in that the ejector spring (5) is damped. Drop barrel weapon according to one of claims 1 to 7, characterized in that the control flap (11) is guided by connecting flaps (15) in grooves (16) in the monoblock (1). Drop barrel weapon according to one of claims 1 to 8, characterized in that an externally accessible stud screw (32) is provided on the monoblock (1), through which movement of the control flap (11) by the control bolt (7) can be prevented. Drop barrel weapon according to one of claims 1 to 9, characterized in that there is a compression spring (34) which exerts pressure laterally on the control flap (11).

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