DE3731044A1 - Compressed-gas-operated shooting weapon, especially a recreational weapon which is operated using CO2 gas - Google Patents

Abstract

A shooting weapon which is operated using CO2 gas has a pressure chamber in which the gas is stored for firing. The shot is fired by opening the valve which seals the pressure chamber from the weapon barrel. In order to compensate for pressure changes in the CO2 gas resulting from temperature fluctuations, a piston is mounted displaceably in the pressure chamber, which piston acts on the valve spring or the firing spring. In the event of a reduction in pressure, the valve spring or the firing spring is relieved of stress by the piston movement, as a result of which the valve opening time and hence the gas quantity required for firing are increased. This automatic regulation of the valve opening time as a function of the gas pressure ensures a constant projectile muzzle velocity and hence constant firing precision.

Description

The invention relates to a compressed gas-operated firearm, ins special sports weapon powered by CO 2 gas, in which the gas stored in a pressure chamber closed by a valve and the valve briefly by pulling the trigger is opened so that a certain amount of gas from the pressure chamber flow to the barrel bore and drive the projectile out of the barrel can.

In the known firearms of this type, the CO 2 gas for the propulsion of the projectile from the firearm exchangeable arranged pressure gas container removed and in stored in a pressure room. The pressure room is over a Ka nal connected to the gun barrel and through this a valve sealed. In doing so, a spring-loaded valve plate pressed onto the valve seat. One with the valve plate connected valve tappet interacts with an impact piece, that is tensioned against the force of a spring and by actuation the trigger is triggered. The hit hits briefly before the end of its stroke movement on the valve plate, so that the valve plate is lifted briefly and through the Valve spring is closed again. During the opening hours of the valve a certain amount of the compressed gas flows from Pressure chamber to the barrel bore and drives the projectile out of the barrel. The initial velocity of the projectile, which is used for the shot performance of the sporting weapon is of great importance depends on the gas pressure prevailing in the pressure chamber and the amount of gas, which flows through the valve during the opening time. The  The opening time of the valve depends on the energy of the Impact piece or by the spring force with which the tension spring acts on the hammer and also on the closing force of the Valve spring. If the opening time of the Valve, for example by reducing the valve lock force of the valve spring or by increasing the tension spring force of the striking piece, that is due to the open valve flowing gas volume increases and thereby the initial bullet speed increased.

A disadvantage of the known CO 2 firearms of this type the temperature dependence of the CO 2 gas with the resulting resulting pressure change in the pressure chamber. This pressure change tion also changes the initial floor speed due to the impact energy required to open the valve as well as the valve spring necessary to close the valve force have remained constant and therefore the valve is below different gas pressures always have the same opening time. The same amount of CO 2 gas therefore flows at the same time through the valve but with different pressure so that the acceleration to the floor as well as the result bullet initial velocity large deviations exhibit. For example, a tempe occurs in the area rature increase, so the pressure of the CO 2 gas in the pressure chamber enlarged and the floor initial speed intensity increased. The result of this are different hangouts point positions and a reduced shot precision. Because CO 2 shot weapons increasingly to sports and competition equipment the requirements of the practice on the con punch the bullet initial speed.

DE-OS 35 11 379 already regulates pressure device for a firearm operated with CO 2 gas knows. The CO 2 gas enters from a gas reservoir Valve in a pressure chamber in which the gas for launch  is saved. The gas flowing into the pressure chamber moves a spring loaded in the pressure chamber th piston in a closed position in which the valve ge is closed and no more gas in the pressure chamber can occur. The spring force acting on the piston becomes manually set to a certain value. Once the Gas pressure in the pressure chamber has reached this value the piston moved and the valve closed. After this The piston is fired back into its opening by the spring Opened position and the pressure chamber with CO 2 gas filled until the pressure in the pressure chamber again has reached the set value. This is supposed to be for every shot same pressure in the pressure chamber and a constant floor Initial speed can be guaranteed.

The disadvantage of this known pressure regulating device is that the pressure can only be kept at the same value if the gas pressure in the pressure chamber is smaller than in the gas reservoir. This means that the spring force of the piston must be set to a value which corresponds to the lowest gas pressure or the lowest temperature occurring when using the weapon according to the vapor pressure curve of liquid CO 2 . If one shoots at a gas pressure or temperature lower than that set via the pressure regulating device, the initial velocity of the projectile is no longer compensated for by the pressure regulating device. The consequence of this is a lower projectile initial speed and thus a low shot. In order to avoid this, the lowest pressure corresponding to the lowest temperature must always be used. The disadvantage is that the acceleration of the projectile is not maximum.

The invention is therefore based on the object Avoid disadvantages and always carry the weapon with that  to operate the maximum possible gas pressure to the storey-on catch speed as high as possible and the muzzle pressure to keep it as low as possible.

This object is achieved according to the invention in that the Opening time of the valve depending on that in the pressure chamber prevailing gas pressure is automatically adjustable.

According to a further feature of the invention is in the pressure room a piston loaded with gas against the force of a spring axially displaceable, the piston rod indirect or directly on a valve spring that holds the valve shut acts.

An advantageous connection between the piston and valve spring is achieved in that the piston rod of the piston Rack that rotates with a gear a stored, axially immovable spindle is engaged, wherein the spindle through a spindle nut of a pressure piece sets, which serves as a counter bearing for the valve spring.

In another embodiment of the invention, the ver bond between piston and valve spring that the piston rod of the piston with one arm of a win lever is articulated, the other arm on the is articulated on the valve spring pressure piece.

Another embodiment of the invention for influencing The opening time of the valve is characterized in that the piston rod directly or indirectly on the blow acts spring of an impact piece, which by pressing the Trigger is triggered, hits the valve lifter and the valve opens.

To adjust the control behavior of the pressure compensation  According to a further feature of the invention, the direction is Force of the spring, which acts on the piston, adjustable.

To increase the sensitivity of the controller, Ver reducing the piston friction instead of the piston a membrane be provided for pressure transmission.

The advantages achieved with the invention are in particular in that the projectile initial velocity is independent of any pressure fluctuations due to temperature changes con is kept constant. It can always be with the maximum possible gas pressure to be worked so that the floor-to catch speed as high as possible and the muzzle pressure is as low as possible.

The invention is in the following description and the drawing tion, which represents several embodiments, he closer purifies. Show it

Fig. 1 shows a longitudinal section through the inventive valve,

Fig. 2 shows a section according to line II-II through the valve of Fig. 1,

Fig. 3 shows a longitudinal section through another embodiment of the valve and

Fig. 4 shows a longitudinal section through another Ausfüh approximate shape of the valve.

A valve 2 is arranged in a valve housing 1 of a CO 2 weapon, not shown. The valve 2 consists of a stationary valve seat 3 , onto which a valve plate 4 is pressed by means of a compression spring 5 . The valve plate 4 has a valve tappet 6 , on which a striking piece (not shown) hits when the trigger is actuated and the valve 2 opens. Through channels 7 and 8 , the CO 2 gas in a pressure chamber 9 can flow with the valve 2 open to a barrel bore (not shown) of the firearm in order to drive the projectile out of the barrel.

As a counter bearing for the compression spring 5 , a pressure piece 10 is seen before, which engages with an upper and a lower web 11 in the longitudinal guides 12 of the valve housing 1 and is displaceable in the axial direction of the valve 2 . The pressure piece 10 has a spindle nut 13 , coaxial with the longitudinal center axis of the valve tappet 6 , in which a spindle 14 engages. The spindle 14 is rotatably mounted in the valve housing 1 and axially non-slidably. With the spindle 14 , a gear 15 is fixedly connected, which is in engagement with a vertically arranged rack 16 . The rack 16 is fixedly connected to a piston 17 which is axially displaceably mounted in a cylinder 18 of the valve housing 1 against the force of a spring 19 . A counter screw for the spring 19 is a set screw 20 which is rotatably arranged in a threaded bore 21 of the valve housing 1 for setting the spring force. The movement of the piston 17 in the effective direction of the spring 19 is limited by a stop 22 .

The valve housing 1 has a connecting pin 23 with a thread 24 for the connection of a CO 2 cartridge (not shown). At the front end of the connecting pin 23 , a pin 25 for opening the valve of the CO 2 cartridge is arranged. A channel 26 is provided in the connection pin 23 for the passage of the CO 2 gas into the pressure chamber 9 of the valve housing 1 .

When screwing the CO 2 cartridge onto the connecting pin 23 of the valve housing 1 , the valve of the CO 2 cartridge is opened automatically. The emerging from the CO 2 cartridge CO 2 gas flows through the channel 26 into the pressure chamber 9 of the valve housing 1 , which is limited by the piston 17 down.

If pressure changes occur in the pressure chamber 9 as a result of temperature fluctuations, these are transmitted to the piston 17. For example, if the gas pressure in the pressure chamber 9 decreases as a result of falling outside temperatures, which occurs very frequently, the spring 19 of the piston 17 is relieved of the because is moved up by. About the rack 16 and the gear 15 there is a rotation of the spindle 14 clockwise sense, so that the pressure piece 10 is shifted to the left and the compression spring 5 is relieved. Due to the lower preload of the compression spring 5 , when the valve disk 4 is fired, it is pressed deeper into the pressure chamber 9 by the striker striking the valve tappet 6 and thus kept open longer. As a result of the extended valve opening time, a larger amount of CO 2 gas can flow to the barrel bore, thereby compensating for the reduced gas pressure and thus keeping the projectile initial speed constant.

In the event of a pressure increase in the pressure chamber 9 as a result of rising outside temperatures, the piston 17 is moved downward against the force of the spring 19 and the toothed wheel 15 of the spindle 14 is rotated counterclockwise via the toothed rack 16 . Characterized the pressure piece 10 is moved in the direction of the valve plate 4 and he increases the force of the compression spring 5 , which also increases the valve closing force. As a result of the increased valve closing force, the opening time of the valve is reduced when the impact piece hits the valve lifter 6 . The result of this is that a smaller amount of gas flows to the barrel bore, so that an increase in the projectile initial speed due to the higher gas pressure is avoided. This results in an automatic control of the valve opening time, which results in a constant floor initial speed.

In the gas pressure diagram for compressed gas weapons, the floor is at the beginning speed proportional to the area under the gas pressure curve ve that is recorded over the floor path. Owing to  Fluctuations in temperature can thus be gas pressure curves different pressures, all of which have the same Generate initial speed. With constant storey on catch speed and lower gas pressure results in a Extension of the gas pressure curve combined with an increase the muzzle pressure. A high muzzle pressure is one good shot performance detrimental. It must therefore be aimed at to work with the maximum possible gas pressure, around the initial acceleration of the bullet as high as possible and keep the muzzle pressure as low as possible. This is possible with the invention according to the application, since for Keeping the initial velocity of the projectile constant Limiting the gas pressure upwards is not necessary.

Another embodiment of the invention is shown in Fig. 3 Darge. Instead of the gear rack drive, an angle lever 27 is pivotally mounted in the valve housing 1 about an axis 28 lying transversely to the longitudinal axis of the valve tappet 6 . One arm 29 of the angle lever 27 is articulated on a piston rod 30 of the piston 17 . The other arm 31 of the angle lever 27 is directed to the back of a pressure piece 32 , which serves as a counter bearing for the valve spring 5 . The pressure changes occurring in the pressure chamber 9 of the valve housing 1 as a result of temperature fluctuations in the CO 2 gas are transmitted to the piston 17 . For example, if the pressure in the pressure chamber 9 increases , the piston 17 is moved downward. About the angle lever 27 and the pressure piece 32 , the valve spring 5 is compressed and the Ventilzu holding force is increased. This results in a shorter valve opening time, so that the pressure increase is balanced and the projectile initial speed is kept constant. If there is a drop in pressure in the pressure chamber 9 , there is an opposite mode of action.

In Fig. 4 another embodiment of the invention is provided. The piston 17 is slidably mounted in a cylinder space 33 of the valve housing 1 . The cylinder chamber 33 is connected via a bore 34 to the pressure chamber 9 of the Ventilge housing 1 . When the CO 2 gas enters through the channel 26 into the pressure chamber 9 , a pressure builds up, which continues into the cylinder chamber 33 and acts on the piston 17 . The piston 17 is connected to a piston rod 35 which has at its free end an upwardly directed holder 36 which serves as a counter bearing for a striking spring 37 . The other end of the striking spring 37 acts on an impact piece 38 which will hold ge in the tensioned position by a pawl 39 . The holding pawl 39 is connected via a trigger rod 40 to a trigger, not shown, of the firearm. For example, increases the pressure of the CO 2 gas in the pressure chamber 9 , the piston 17 is displaced with the piston rod 35 and the holder 36 to the right. As a result, the shock spring 37 is somewhat relaxed, so that the spring force acting on the striker 38 is reduced. When the trigger is actuated, the striker 38 is released by the holding pawl 39 and hits the valve plunger 6 of the valve 2 with reduced energy. The valve opening time is shortened by so that a smaller amount of CO 2 gas can flow through the channels 7 and 8 to the barrel bore. The increased drive energy for the projectile due to the pressure increase in the pressure chamber 9 is reduced again by the shorter valve opening time, so that there is a constant projectile initial speed with pressure changes.

For the regulation of the impact spring force of the striking piece 38 , the construction principle shown in FIG. 1 is also suitable.

In the embodiment according to FIG. 3, the pressure force on the piston 17 must be greater than the force of the valve spring 5, otherwise a return action of the valve spring 5 is made difficult on the piston 17, the control.

Instead of the piston 17 , a membrane can also be used for the pressure transmission. The piston friction caused by the sealing ring of the piston is avoided, so that the regulator responds to even the smallest pressure changes.

Claims (7)

1. Compressed gas-operated firearm, in particular sports weapon operated with CO 2 gas, in which the gas is stored in a pressure chamber closed by a valve and the valve is briefly opened by actuating the trigger, so that a certain amount of gas flows from the pressure chamber to the bore and can drive the projectile out of the barrel, characterized in that the opening time of the valve ( 2 ) is automatically adjustable depending on the gas pressure prevailing in the pressure chamber ( 9 ). 2. Pressurized gas-operated firearm according to claim 1, characterized in that in the pressure chamber ( 9 ) a gas-loaded piston ( 17 ) against the force of a spring ( 19 ) is axially slidably mounted, the piston rod indirectly or directly on a valve ( 2 ) locking valve spring ( 5 ) acts. 3. Gas-operated firearm according to claim 1 or 2, characterized in that the piston rod of the piston ( 17 ) has a rack ( 16 ) which is in engagement with a gear ( 15 ) of a rotatably mounted, axially immovable spindle ( 14 ), wherein the spindle ( 14 ) passes through a spindle nut ( 13 ) of a pressure piece ( 10 ) which serves as a counter bearing for the valve spring ( 5 ). 4. Pressurized gas-operated firearm according to claim 1 or 2, characterized in that the piston rod ( 30 ) of the piston ( 17 ) with one arm ( 29 ) of a rotatably mounted angle lever ( 27 ) is articulated, the other arm ( 31 ) on the on the valve spring ( 5 ) acting pressure piece ( 32 ) is steered. 5. Pressurized gas-operated firearm according to claim 1, characterized in that the piston rod ( 35 ) of the piston ( 17 ) acts directly or indirectly on the striking spring ( 37 ) of an impact piece ( 38 ), which is triggered by actuating the trigger, on the valve tappet ( 6 ) hits and the valve ( 2 ) opens. 6. Pressurized gas-operated firearm according to one of claims 1 to 5, characterized in that the force of the spring ( 19 ) which acts on the piston ( 17 ) is adjustable. 7. Pressurized gas-operated firearm according to one of claims 1 to 6, characterized in that a membrane for pressure transmission is provided instead of the piston ( 17 ).