WO2002079710A1 - Compressed gas-driven gun device and compressed gas supply device for such a gun device - Google Patents

Abstract

A pressure supply device for a compressed gas-driven gun device, comprising at least one reservoir (8) for a propellant, existing at least partly in the liquid phase (14) in the at least one reservoir (8), further comprises withdrawing means (16), for withdrawing the propellant through a withdrawing opening (13) in the at least one reservoir (8). The at least one reservoir (8) and the withdrawal means (16) are arranged within the pressure supply device (1), in the in-use position thereof, such that a withdrawal of the liquid phase (14) of the propellant is possible. The invention further relates to a gun device with such a pressure supply device.

Description

 "Pressurized gas powered firing device as well

Pressure supply device for such

Firing device ¹¹

The present invention relates to a pressure supply device for a compressed gas-operated firing device comprising at least one container for a propellant which is at least partially in the liquid phase in the at least one container, and furthermore comprises removal means for removing the propellant from a removal opening of the at least one container. Furthermore, the present invention relates to a compressed gas-operated projectile shooting device comprising a pressure supply device of the aforementioned type and channel means for transferring propellant from the pressure supply device into a firing area in which the propellant can be present in a gaseous phase in such an amount that the gas pressure of the propellant that at least one projectile can be accelerated for leaving the firing device.

A pressure supply device and a pressurized gas firing device of the aforementioned type are known from European patent application EP 0 704 668 AI. The firing device described therein is designed as a firearm, in particular as a gas pressure pistol. The pressure supply device of this gas pressure gun comprises a container for C0 ₂ , which serves as a propellant in this prior art. The container is arranged in the pressure supply device in such a way that its removal opening is arranged at the top of the container. The container is cylindrically shaped, the cylinder axis of this container enclosing only a relatively small angle with the vertical.

As a disadvantage of such

Pressure supply device or in one equipped with such a pressure supply device Firing frequency Projectiles are to be fired from such a firing device, only a relatively short period of time remains for the removal of the propellant. After removal of the propellant from the area of the gaseous phase, for example, if a shot is to be fired two to five seconds later, the same initial pressure that has developed after a longer phase than has not yet been built up again in the container above the liquid phase Will set equilibrium pressure. Furthermore, due to the constantly repeated evaporation of the liquid phase into the gaseous phase at high firing frequency, the blowing agent or the blowing agent container is cooled. At a high firing frequency, temperature compensation will not be possible between the individual shots, so that ultimately, at a high firing frequency, the gaseous phase and the liquid phase of the propellant will cool significantly. However, this cooling also results in a reduction in the pressure of the gas phase.

As can be seen in FIG. 6, which shows a list of the muzzle velocity of a firing device as a function of the number of shots fired, the pressure drop will be so high after approximately ten shots that the muzzle velocity decreases noticeably after approximately ten shots. This has the disadvantage, particularly when the firing device is designed as a firearm, that after firing more than ten shots in a short time interval, for example, reliable aiming is no longer possible, since the muzzle velocity decreases from shot to shot.

The problem on which the present invention is based is the creation of a pressure supply device of the type mentioned at the outset and a firing device of the type mentioned at the beginning, in which at a high firing frequency for as large a number of shots as possible the one removed by the The pressure built up by the propellant is as constant as possible, so that the projectile launched by the firing device has an initial speed that is as constant as possible.

This according to the invention with regard to

Pressure supply device solved by the characterizing part of claim 1 and in terms of the firing device by the characterizing part of claim 13.

According to claim 1 it is provided that the at least one container and the removal means are arranged in the use position of the pressure supply device in such a way that removal of the liquid phase of the propellant is made possible. When the blowing agent is removed from the area of the liquid phase, even with short removal times, a relatively large amount of the blowing agent is removed, so that, regardless of the pressure of the gaseous phase in the container of the blowing agent, even at high firing frequencies and a high number of shots that have already taken place the amount of propellant removed is sufficient to generate a pressure which is sufficiently high for the desired initial or muzzle velocity in the firing area. In the case of a shot device provided with such a pressure supply device, an exit velocity of the projectile which is uniform over a long period at a high shot frequency is thus made possible due to the removal of the liquid phase from the container for propellant. Temporary cooling of the gaseous phase in the at least one container for propellant is also the

Do not influence the exit speed of the projectile, since the amount of liquid phase of the propellant removed will in any case be sufficient to build up the desired pressure.

For this purpose, the

Pressure supply device of the at least one container and the removal means can be arranged such that the removal the liquid phase of the blowing agent is also possible if more than half, preferably more than 80% or 90% of the blowing agent has already been removed. This could be achieved, for example, by arranging the removal opening of the at least one container in the use position of the pressure supply device on the underside of the respective container. In particular in the case of a cylindrical configuration of the container, this can be achieved in that in the position of use of the pressure supply device the cylinder axis of the at least one container encloses an angle of less than 90 ° with the vertical, preferably an angle of less than 45 ° with the vertical, the removal opening being on the underside of the at least one container is arranged or preferably substantially aligned with the cylinder axis. Advantageously, the cylinder axis of the at least one container can be aligned essentially parallel to the vertical. In this case, the propellant is removed from the liquid phase almost until the propellant container is completely emptied, so that sufficient pressure can be built up almost until the propellant container is completely emptied to ensure the desired exit speed of the projectile.

According to a preferred embodiment of the present invention, the pressure supply device comprises at least two containers, which are arranged in substantially the same way in the pressure supply device. The pressure supply device can include a receptacle for the at least two containers, which is provided with a clamping element which, in cooperation with the receptacle, enables the removal openings of the at least two containers to be connected to the removal means at the same time. This ensures that when the container is connected to the removal means, one of the containers is not contacted first and a large amount of the propellant can escape before the second of the containers also contacts the removal means in such a way that one is directed to the outside out tight connection between the two containers and the removal means is achieved.

In this case, the clamping element can be attached to the at least two containers from above and can be moved towards the receptacle by means of a screw element. By providing a screw element, the clamping element can move the two containers onto the receptacle so uniformly that the containers can be brought into contact with the removal means essentially simultaneously. For better usability, a handle can be provided on the screw element.

The pressure supply device can advantageously comprise coupling means for the tight connection of the pressure supply device to the firing device. These coupling means can be connected to removal means via channel means. The coupling means offer the advantage that the containers can be connected to the removal means within the pressure supply device without propellant escaping from the pressure supply device. After being connected to the removal means, the propellant can spread within the pressure supply device, for example in the channel means up to the coupling means. However, only after coupling to a firing device can the propellant leave the pressure supply device and enter, for example, corresponding channel means provided in the firing device.

Here, the coupling means preferably comprise an opening provided with an O-ring and a bolt which is held by means of a spring and which can be transferred from a first position in which it closes the opening against the force of the spring to a second position in which the opening is open for the propellant to pass through. Such a preloaded bolt seal provides a simple one but nevertheless represents a very effective design of a coupling agent.

The firing device can preferably comprise corresponding coupling means for the tight connection to the pressure supply device, wherein the coupling means can comprise a connecting piece provided with a through hole, which can be sealingly inserted into a receptacle of the pressure supply device. Here, when the connector is inserted into the receptacle, the connector can transfer the bolt from the first position to the second position. This ensures that the plug is pushed out of the opening only when the connector is inserted into the receptacle in such a way that the propellant can pass through the opening. For the entry of the propellant into the connecting piece, this can have a transverse groove at its end facing the bolt for the entry of the propellant into the through hole.

The firing device can, for example, be designed as a firearm. In particular, the shooting device is designed as a gas pressure rifle, the

Pressure supply device can be introduced into a recess in the shaft of the firing device designed as a gas pressure rifle. The

Gas pressure supply device can be connected to the butt plate of the shooting device designed as a gas pressure rifle. Such a placement of the pressure supply device in a gas pressure rifle represents a particularly effective placement.

According to an alternative embodiment of the shooting device, nails or clips are provided as projectiles. In this case, the shooting device could be designed, for example, as an upholstery nailing device or the like. According to the invention, there is the possibility of using any pressure supply device according to the invention to shoot projectiles that can be accelerated and fired by gas pressure. Such shooting devices can be used in a wide variety of applications.

Further features and advantages of the present invention will become clear from the following description of preferred exemplary embodiments with reference to the accompanying figures. Show in it

Figure 1 is a detailed perspective view of a shooting device according to the invention with a pressure supply device according to the invention without a container.

FIG. 2 is a partially sectioned perspective detail view of the firing device and the pressure supply device according to FIG. 1 with containers for propellant;

3 shows a sectional view of the pressure supply device according to FIGS. 1 and 2 with coupling and channel means for the continuation of the propellant;

Fig. 4 is a detailed view according to arrow IV in Fig. 3;

5a shows a detailed view according to arrow Va in FIG. 3;

5b shows a view according to FIG. 5a with the coupling means engaged;

6 shows a diagram showing the exit speed of a projectile from a shot device according to the invention or from shot devices according to the prior art as a function of the number of shots;

7 shows a view corresponding to FIG. 3 of a further embodiment of an inventive

Firing device. ! _ 1 and 2 show an embodiment of a pressurized gas-powered firing device according to the invention. In the exemplary embodiment shown, the firing device is designed as a gas pressure-operated firearm, in particular as a gas pressure rifle. The pressure supply device 1 shown in FIG. 1 and FIG. 2 can be introduced into the shaft 2 of the firing device designed as a gas pressure rifle. For this purpose, the shaft 2 has a recess 3 which is open to the rear and into which the pressure supply device 1 can be inserted. The pressure supply device 1 is connected to a butt plate 4, which after the introduction of the

Pressure supply device 1 in the recess 3 closes the shaft 2 to the rear. On the butt plate 4 a clamping lever 5 serving as a closure is attached with a V-shaped closure element 6. When the pressure supply device 1 is pushed into the recess 3, the tensioning lever 5 can be pushed into the butt plate 4 in such a way that the closure element 6 locks the butt plate 4 on the shaft 2. By pressing the V-shaped closure element 6, the closure realized by the tensioning lever 5 can be opened, so that the butt plate 4 can be pulled off to the rear.

As can be seen from FIGS. 1 and 2, the pressure supply device 1 in the exemplary embodiment shown has two receptacles 7, open at the top in the use position, for containers 8 for propellant. The containers 8 can be commercial C0 ₂ cartridges. However, there is also the possibility of using other blowing agents, provided that they can be at least partially in the liquid phase at room temperature.

1 and FIG. 2, a clamping element 9 can also be removed, which in the position of use can be placed on the container 8 from above and can be moved in the direction of the receptacles 7 by means of a screw element 10, which holds the container 8 firmly in the receptacles 7 are held and on the other hand the removal means described in more detail below are actuated. To rotate the screw element 10, a handle 11 is attached to it. The clamping element 9 also has two openings 12, into which the upper ends of the containers 8 can partially protrude, so that the clamping element 9 can securely grip them.

3 that the container 8 is accommodated in the pressure supply device 1 in the use position of the firing device such that the removal opening 13 is arranged on the underside of the container 8, so that the liquid phase 14 of the propellant can be removed. A distribution between liquid phase 14 and gaseous phase 15 of the propellant in the container 8 is shown as an example in FIG. 3. Depending on the consumption of the propellant, the gaseous phase 15 will occupy a more or less large volume of the interior of the container 8.

The removal means 16 can be removed in detail in FIG. 4. The removal means 16 comprise a receptacle 17 with a circular cross section for the sealing receptacle of the container tip 18, which will usually also have a circular cross section. In the receptacle 17, an O-ring 19 is provided which, when the container tip 18 is pushed into the receptacle 17, lies sealingly on the outside of the container tip 18. By pushing the container 8 into the receptacle 7 from above, and in particular by pushing the container tip 18 into the receptacle 17 of the removal means 16, a piercing tip 20 of the removal means 16 is inserted into the removal opening 13 of the container 8, whereby the removal opening 13 is opened and propellant can enter the piercing tip 20 provided with an axial bore. The axial bore of the piercing tip 20 is connected to a channel 21 which is surrounded by channel means and which is in the position of use Firing device extends substantially horizontally through the pressure supply device 1.

With the above design of the extraction means 16 and the clamping member 9 ensures that upon actuation of the handle 11 and thus with moving down of the clamping member 9, both container 8 located in the receptacles 7 are moved in such a way down simultaneously that substantially at ¹ simultaneous opening of the Removal openings 13 of the two containers 8 takes place. In particular, the central attachment of the screw element 10 to the clamping element 9 ensures an essentially horizontal alignment of the clamping element 9 and thus an essentially simultaneous movement of the containers 8 downwards.

3 and in particular FIGS. 5a and 5b show the further path of the propellant in the firing device. In Fig. 3 further channel means are shown, which are designated by the reference numeral 22. Coupling means are provided between the channel means 22 and the channel 21, which also serves as a channel means, which can establish a connection between the pressure supply device 1 and the further channel means 22. 5a shows the coupling means in a state in which the pressure supply device 1 has not yet been fully inserted into the recess 3 in the shaft 2. 5b shows the completely inserted state of the pressure supply device 1 into the recess 3 of the shaft 2. 5a shows the state in which the coupling means do not yet establish a connection between the channel 21 and the channel means 22, whereas in FIG. 5b a connection is created between the channel 21 and the channel means 22 for the propellant.

The coupling means comprise a connection piece 23 which is connected to the channel means 22 and which is located in Use position of the shooting device has a horizontally extending axial through hole. On its side facing the pressure supply device 1, the connection piece 23 additionally has a transverse groove 24, which enables a lateral penetration of propellant into the axial bore of the connection piece 23. The coupling means further comprise a pin 25 which is included in the pressure supply device 1 and which is held in the pressure supply device 1 against the force of a spring 26. The bolt 25 is essentially cylindrical in shape and has a section 27 with a first smaller diameter and a section 28 with a second larger diameter. The bolt 25 can be moved essentially horizontally against the force of the spring 26 in the use position of the firing device. In the relaxed position of the spring 26 (see FIG. 5a), the bolt 25 is shifted to the left so far that the section 28 of larger diameter lies tightly against an O-ring 29 encompassed by the pressure supply device 1, so that none in the channel 21 Propellant can leave the pressure supply device 1.

An essentially hollow cylindrical receptacle 30 is also provided in the pressure supply device 1 for the introduction of the hollow connecting piece 23. In this hollow cylindrical receptacle 30 there is also an O-ring 31 which, after the hollow connecting piece 23 has been pushed in, can seal it from the outside. 5a or 5b, it pushes the bolt 25 against the restoring force of the spring 26 so far into the pressure supply device 1 that the sealing abutment of the section 28 on the O- Ring 29 is lifted and the section 27 of smaller diameter reaches the area of the O-ring 29. A non-sealing position is thus achieved, which is clearly visible in FIG. 5b. In this position, propellant can flow from the channel 21 between the O-ring 29 and the section 27 of smaller diameter of the bolt 25 pass into the axial bore of the connecting piece 23.

From the connecting piece 23, the propellant can pass further through the channel means 22 into the firing area of the firing device, in which, for example, by actuating a valve means, depending on the actuation of a trigger, a projectile can be pressurized by the propellant, thereby accelerating and projecting the projectile the shooting device can be transported out. In the firing area, the propellant will be present in the gaseous phase at least to such an extent that a sufficiently high pressure can be built up to accelerate the projectile.

7 shows a further embodiment of a shooting device according to the invention, in which the coupling means are arranged somewhat higher than that of the first embodiment shown in FIG. 3. For this purpose, the channel 21 comprises a section 21a which extends essentially vertically upwards and which can transfer the propellant into the region of the coupling means arranged further upward, so that the propellant can reach the channel means 22 via the connecting piece 23, which is shown in FIG The embodiment shown in FIG. 7 is also arranged somewhat higher than in the embodiment shown in FIG.

According to the invention, it is possible to provide other firing devices instead of a firearm. This could be, for example, an upholstery nail device in which projectiles shaped as upholstery nails can be accelerated by the propellant and moved out of the firing device formed in this way. According to the invention, all devices or devices with which nails or staples or projectiles can emerge from the shooting device at a comparatively high speed should be regarded as the shooting device. Such nails or staples or projectiles are called projectiles in the following.

There is of course also the possibility that a firing device designed as a firearm is not a gas pressure rifle but, for example, a gas pressure pistol or the like.

6 shows three different relationships between the exit speed v ₀ in m / s and the number of shots that have already been fired from a firing device. Here a shot was fired approximately every 5 seconds. The solid curve shows the relationship between the exit speed and the number of shots in a shooting device according to the invention shown in FIGS. 1 to 5. It can be seen relatively clearly that the exit speed remains essentially constant for about 60 shots, which suggests that a relatively constant pressure can be generated in the launch area.

The dotted line shows a shot device in which the pressure supply device was arranged in such a way that the containers 8 for propellant were aligned horizontally, so that propellant could only be removed from the liquid phase up to about half the fill level. The result clearly shows that the pressure drops from about 40 shots, so that the exit velocity v ₀ drops.

In the dash-dotted line was

Pressure supply device 1 arranged in the firing device so that the removal opening of the container 8 was on the top thereof. Here, after just ten shots, such a drop in pressure can be clearly observed that the exit speed already decreased after ten shots.

Claims

Claims:

1. Pressure supply device for a compressed gas-operated firing device comprising at least one container (8) for a propellant, which is at least partially in the liquid phase (14) in the at least one container (8), and further comprising removal means (16) for the removal of the propellant a removal opening (13) of the at least one container (8), characterized in that the at least one container (8) and the removal means (16) in the use position of the pressure supply device (1) are arranged in such a way that removal of the liquid phase ( 14) of the blowing agent is made possible.

2. Pressure supply device according to claim 1, characterized in that in the use position of the pressure supply device (1) the at least one container (8) and the removal means (16) are arranged such that the removal of the liquid phase (14) of the propellant is also possible , if more than half, preferably more than 80% or 90% of the blowing agent has already been removed.

3. Pressure supply device according to one of claims 1 or 2, characterized in that the removal opening (13) of the at least one container (8) in

Use position of the pressure supply device (1) is arranged on the underside of the respective container (8).

4. Pressure supply device according to claim 3, characterized in that the at least one container (8) is substantially cylindrical, the cylinder axis of the at least one container (8) enclosing an angle of less than 90 ° with the vertical in the position of use of the pressure supply device (1) , preferably an angle less than 45 °, the The removal opening (13) is arranged on the underside of the at least one container (8) and is preferably essentially aligned with the cylinder axis.

5. Pressure supply device according to claim 4, characterized in that the cylinder axis of the at least one container (8) is aligned substantially parallel to the vertical.

6. Pressure supply device according to one of claims 1 to 5, characterized in that the pressure supply device (1) at least two containers

(8), which are arranged in substantially the same way in the pressure supply device (1).

7. Pressure supply device according to claim 6, characterized in that the pressure supply device (1) comprises a receptacle (7) for the at least two containers (8), which is provided with a clamping element (9) which in cooperation with the receptacle (7) enables the removal openings (13) of the at least two containers (8) to be connected to the removal means (16) at the same time.

8. Pressure supply device according to claim 7, characterized in that the clamping element (7) can be applied to the at least two containers (8) from above and can be moved towards the receptacle (7) by means of a screw element (10).

9. Pressure supply device according to claim 8, characterized in that a handle (11) is provided on the screw element (10).

10. Pressure supply device according to one of claims 1 to 9, characterized in that the pressure supply device (1) coupling means for the tight connection of the pressure supply device (1) to the shooting device.

11. Pressure supply device according to claim 10, characterized in that the coupling means can be connected via channel means to the removal means (16).

12. Pressure supply device according to one of claims 10 or 11, characterized in that the coupling means comprise an opening provided with an O-ring (29) and a bolt (25) held by means of a spring (26), which from a first position, in which closes the opening, can be transferred against the force of the spring (26) into a second position in which the opening for the passage of the propellant is open.

13. Compressed gas-operated projectile shooting device comprising a pressure supply device (1) and channel means (22) for transferring propellant from the pressure supply device into a firing area, in which the propellant can be present in such a quantity in the gaseous phase (15) that the gas pressure of the propellant which can accelerate at least one projectile for leaving the shooting device, characterized by a

Pressure supply device (1) according to one of Claims 1 to 12.

14. Shot device according to claim 13, characterized in that the shot device comprises coupling means for the tight connection to the pressure supply device (1), wherein the coupling means comprise a connection piece (23) provided with a through bore, which seals into a receptacle (30) of the pressure supply device (1) can be introduced. ^-

15. Shot device according to claim 14, characterized in that when the connecting piece (23) is introduced into the receptacle (30), the connecting piece (23) can transfer the bolt (25) from the first position into the second position.

16. Shot device according to claim 15, characterized in that the connecting piece (23) has at its end facing the bolt a transverse groove (24) for the entry of the propellant into the through hole.

17. Firing device according to one of claims 13 to 16, characterized in that the firing device is designed as a firearm.

18. Shot device according to claim 17, characterized in that the shot device is designed as a gas pressure rifle.

19. Shot device according to claim 18, characterized in that the pressure supply device (1) can be introduced into a recess (3) of the shaft (2) of the shot device designed as a gas pressure rifle.

20. Shot device according to claim 19, characterized in that the pressure supply device (1) is connected to the butt plate (4) of the shot device designed as a gas pressure rifle.

21. Shot device according to one of claims 13 to 16, characterized in that nails or clips are provided as projectiles.

22. The shooting device according to claim 21, characterized in that the shooting device is designed as an upholstery nailing device.