DE102016203548B3 - Compressed air weapon with pulse compensation - Google Patents

Abstract

The invention relates to a compressed air weapon (10) for sport shooting, in particular a compressed air pistol, comprising: - a weapon housing (12) with a barrel (14) and a projectile bearing (28) for receiving a projectile (30), - one on the weapon housing ( 12) fixed handle (18) for holding the compressed air weapon (10); - A pressure vessel (24) with a precompressed gas, by means of which when dispensing a shot in the projectile bearing (28) arranged projectile (30) in the direction of the barrel axis (16) from the barrel (14) of the compressed air weapon (10) is expelled, and - a recoil compensation device (36) with a compensation part (68) which is displaceably guided in or on a guide device (40) and which can be driven in a direction deviating from the direction of movement of the projectile when the weft is dispensed, so that a compensation element (68) is provided on the handle (18). due to the movement of the projectile (30) acting recoil is reduced. According to the invention, the guide device (40) is arranged at least in sections to the running axis 16 at an acute angle α with 5 ° ≤ α ≤ 25 ° inclined.

Description

The invention relates to a compressed air weapon, as this is used primarily in the field of sport shooting. With such airguns different types are distinguished. For example, there are spring-driven compressed air guns, which must be tightened by the shooter before the delivery of a shot. In addition, so-called Vorkomprimierer are known in which the shooter generates the required to deliver the shot compressed air by actuating a lever before triggering a shot. In addition, compressed air weapons have been established with a pressure vessel in the meantime, in which a compressed gas or compressed air reservoir is stored, which is usually sufficient for a variety of shots. The pressure vessel is an integral part of the weapon housing or designed as a removable cartridge. In the latter case, in principle, air, nitrogen or CO ₂ can be used as compressed gas. The air guns available on the market usually have a weapon housing with a barrel and a handle attached to the weapon housing to hold the compressed air force. In the case of compressed air weapons, when a shot is fired, a projectile arranged in the projectile bearing of the barrel is driven out of the barrel of the weapon by means of the pressurized gas used in the direction of the barrel axis. The bullets used usually have a so-called diaboloform.

Last but not least, in the case of compressed air guns, due to the fact that they do not constitute a grounded system with a grounding lock, a recoil effect resembling a recoil due to the shooter holding with one hand (pistol) or with two hands (rifle) interferes Compressed air weapon experiences a Rückstaßimpuls in the reverse direction, which is equal to the pulse law exactly the impulse, which experiences the bullet in the barrel in the forward direction. As a result, the target safety can be influenced, in particular in the case of hand-held air pistols, because the mouth of the compressed air weapon can move upwards as a result of this impulse during the firing. Airsoft guns have therefore become established on the market, which are equipped with a pulse compensation device for such unwanted recoil impulses. From the EP 0 785 405 B1 is a compressed air weapon is known in which upon delivery of a shot, a compensation part is accelerated in a direction opposite to the direction of movement. Such air guns are used in particular in competitions, for example in Olympic disciplines, where it depends on a consistently high accuracy.

In shooting practice, however, it has been shown that a complete or almost complete compensation of the recoil pulse is at the same time difficult to achieve with a compact design of the compressed air weapons.

The invention is therefore an object of the invention to provide a compressed air weapon, in which the described undesirable recoil pulse acting on the hand holding the air force weapon or hands holding the air force weapon, can be efficiently compensated for a more compact design of the compressed air weapon.

This object is achieved according to the invention by a compressed air weapon having the features specified in claim 1. In the compressed air weapon according to the invention, the pulse compensation device in a conventional manner a displaceably guided in or on a guide device compensating part which is drivable when dispensing the shot in a deviating from the direction of movement of the projectile direction, such that one on the handle due to the movement the projectile recoil pulse is reduced.

According to the invention, the guide means to the longitudinal axis or a horizontal plane of the compressed air weapon comprising the barrel axis at least in sections at an acute angle α with 3 ° ≤ α ≤ 45 °, preferably with 5 ° ≤ α ≤ 30 °, most preferably with 5 ° ≤ α ≤ 25th °, arranged obliquely. As a result, a counter-pulse with two directional or pulse components can be generated when firing the compressed air weapon. One of the pulse components is directed in the direction of the barrel axis, thus opposing the recoil pulse generated by the fired diabolo bullet. In addition, the counter-pulse on a pulse component, which is aligned vertically in the aligned horizontally aligned with the barrel compressed air force, ie in a direction orthogonal to the barrel axis. As a result, the pulse compensation device or the compressed air weapon can be made particularly compact and at the same time efficient pulse compensation can be achieved when the compressed air weapon is fired. Due to the vertically running pulse component of the counter-pulse, the guide device can be made shorter overall. In addition, when compressed air weapons between the handle and the sight (rear sight) is usually sufficient space available, in which the compensation part can be moved in the delivery of a shot. If necessary, the compensation part can also be made longer than previously possible in order to be able to optimally adjust the mass of the compensation part to the desired pulse compensation. This, without widening the gun housing or even need to extend to the rear. In the compressed air weapon according to the invention Moreover, in the case of an incomplete compensation of the recoil pulse by the first pulse component of the counter-pulse generated by the acceleration of the compensation part, a "high-altitude wandering" feared by the shooter can be effectively counteracted during the firing. The path traveled by the compensation part until the projectile leaves the barrel is basically the smaller, the greater the mass of the compensation part. Therefore, it is advantageous to choose the mass of the compensation part by a multiple (usually about one hundred times) larger than the bullet weight (a diabolo bullet of caliber 4.5 mm is known to weigh about 0.5 g). At the same time, it should be noted that the compensation part has to be reliably moved with respect to the barrel during the delivery of a shot in order to be able to generate a counter-pulse. For this reason, the mass of the compensation part must not be too large. It is understood that the compensation part when dispensing a shot can basically be driven by the force of a spring element, by magnetic force, by the precompressed gas (compressed gas) or in another suitable manner. It should also be noted that the compressed air weapon according to the invention is not a lafettiertes system with ground closure. According to a particularly preferred embodiment of the invention, the guide means of the pulse compensation device intersects the barrel axis or a horizontal plane of the pneumatic weapon with its longitudinal axis preferably at an intersection point which is arranged along the barrel axis in a direction away from the mouth of the barrel direction behind the bullet bearing. In this case, the guide device thus has a longitudinal axis inclined downwards in the direction of the mouth of the barrel.

With regard to an effective pulse compensation, it is advantageous if the pulse compensation device is arranged in or on a vertical plane of the compressed air weapon comprising the barrel axis. The compensation device does not extend laterally of the barrel in this case. An alternative embodiment of the invention, in which a compensating part is provided on diametrically opposite sides of the barrel axis, is conceivable.

In one embodiment of the invention it is provided that a connection channel leads to the compensation device from a gas channel which leads the gas pressure into the region behind the projectile store (in which a projectile is located in the firing position). It is advantageous that the gas pressure for moving the compensation part is effective as soon as the shot valve has been opened when pressing the trigger of the weapon. For the sufficient effect of the momentum compensation, it is important that the cross section of the connection channel leading to the compensation part has a sufficiently large free cross section. In this design, the compensation part is therefore at least partially drivable directly by the precompressed gas.

The compressed air weapon can have a pressure vessel or a (replaceable) cartridge for a precompressed gas, by means of which, when a shot is fired, the projectile arranged in the projectile store can be expelled in the direction of the running axis. It is understood that the compressed air weapon can basically also be designed as a spring-driven system or as a compressed air force with pre-compression.

The guide device according to the invention preferably has a rectilinear or a substantially straight course. However, it is also conceivable that the guide device has at least partially a curved course. As a result, the effect of the generated counter-impulse upon delivery of a shot can, if necessary, be matched to different firing phases.

The guide device is preferably designed as a cylinder or gas cylinder, in which the compensation part is guided displaceably. As a result, the compensation part can be guided extremely precisely. Moreover, in the last-mentioned case, the compensation part can be released directly or indirectly by the compressed gas from an axial position fixing explained below into its starting position and / or driven along the guide device. According to another embodiment, the guide device may be a linear guide with at least one rail, a guide rod, a guide tube, or the like, on which the compensating part is displaceably mounted.

From a constructional point of view, the guide device according to the invention is preferably at least partially formed by a closure part of the weapon housing, which is mounted in the direction of the barrel axis, preferably by hand, between a closed position and an open position translationally adjustable on the weapon housing. As a result, the number of components of the compressed air weapon can be minimized.

The closure member can serve for the compensation part at the same time as a return device to return this before firing in its operative position. Thus, the displacement of the compensation part in its initial position in a particularly simple Way done by a fixed stop on the weapon by the compensation part is moved together with the shutter in the direction of the stop, the stop thereby comes to rest on the compensation part and the further movement of the housing of the compensation device, the compensation part in the interior of the housing relative to this shifts. During the final forward movement of the closure part together with the housing then the compensation part due to frictional forces does not change its position relative to the closure part. Of course, other types of entrainment means may be provided in order to be able to return the compensation part to the closure part in a motion-coupled manner in its starting position. It is conceivable in this regard, for example, a pawl or locking system or a movement coupling of the two components by magnetic force.

The shooter can therefore after loading a projectile alone by closing the shutter to transfer the compressed air weapon in its ready-shot state and the pulse compensation device in its functional state ready.

Prior to the delivery of a shot, in the case of the ready-to-shoot (charged) compressed-air weapon, unintentional slippage of the compensation part from its starting position, for example when the barrel is oriented vertically upward, must be avoided. Otherwise, the complete functionality of the pulse compensation device would not be guaranteed. For the aforementioned reasons, the compensation part is preferably held axially fixed in position in its initial position relative to the guide device. This can be done for example by magnetic force or by a purely mechanically or by the precompressed gas operable catch or latch.

The pulse compensation device may, according to an alternative embodiment of the invention, also have a friction brake, by means of which the compensation part is held in its initial position axially fixed in position. In this regard, the friction brake may, for example, have a sealing element, for example a radial sealing element which surrounds the compensation part in an annular manner and bears against the inside of the guide device or the gas cylinder. However, the friction brake particularly preferably has a friction element arranged in a recess or bore of the compensation part, which is biased against the guide device (in the radial direction) by means of a spring element or a rubber-elastically deformable elastomer.

When dispensing a shot, a release of the axial positional fixation of the compensation element arranged in the starting position can in principle be effected directly or indirectly by the precompressed gas, purely mechanically or else by magnetic force.

The invention will be explained below with reference to an embodiment shown in the drawing.

Show it:

1 a compressed air gun with a weapon housing with a barrel and with a handle attached to the weapon housing, in a side view;

2 the compressed air gun according to 1 in ready to fire state with representation of a pulse compensation device with arranged in the initial position compensation part, in a fragmentary sectional view;

3 the compressed air gun according to 1 immediately after delivery of a shot and with compensating part activated, in a partial longitudinal section; and

4 the compressed air gun according to 1 after completion of the shooting process, in a partial longitudinal section.

In 1 is a compressed air weapon 10 , here an air pistol, shown for the shooting sport. The compressed air weapon 10 is designed as a so-called single loader for diabolo projectiles and especially suitable for competition use. The compressed air weapon 10 can in principle be designed as a so-called spring-driven compressed air weapon (spring storage system), a compressed air weapon with precompressed gas or as a CO2 / compressed air compressed air weapon.

The compressed air weapon has a pistol or weapon housing 12 with a run 14 and with a barrel axis 16 on. One on the weapon case 12 attached handle 18 serves to hold the compressed air weapon 10 with only one hand. The barrel has at its rear in the direction of the barrel axis a bullet bearing into which the bullet to be fired is manually inserted. A repeating lever 20 serves to a in 1 only partially shown movably mounted closure part 22 from the closed position shown to the rear (right in 1 ) to move in an open position to make the floor storage accessible from the outside.

The weapon housing here is a pressure vessel 24 connected, in which precompressed gas is stored. The gas may be air or another common cold propellant, such as nitrogen or carbon dioxide. The in the pressure vessel 24 stored gas supply is sufficient for the delivery of a variety of shots. Will be a deduction 26 the compressed air weapon 10 actuated, thus a predetermined volume of the compressed gas is released from the pressure vessel and fed to the projectile store to the projectile from the barrel 14 the compressed air weapon 12 expel.

2 shows the weapon case 12 the compressed air weapon 10 according to 1 in a schematic fragmentary longitudinal section. The run 14 the compressed air weapon 10 closes with his bullet bearing 28 in which here is a diabolo bullet 30 is introduced, to a gas outlet opening 32 a gas channel 34 at which the highly pressurized gas exits during the firing. The gas channel 34 is fluidly connected to the compressed gas reservoir. The closure part 22 is easy to recognize.

The compressed air weapon 10 is with a pulse compensation device 36 provided here in the direction of the barrel axis 16 behind the projectile camp 28 is arranged. The pulse compensation device 36 is via a connection channel 38 with the projectile camp 28 fluidly connected. Via the connection channel 36 During the delivery of a shot, the gas of the pulse compensation device serving as propellant flows 36 to. The impulse balancing device 36 has a guide device designed as a cylinder or gas cylinder 40 on, in which a compensation part 42 is slidably mounted. The guide device can in the structurally simplest case by the closure part 22 be formed. The compensation part 42 is present in its front end position, ie in its initial position, shown in the compensation part 42 at a front stop 44 of the weapon case 12 is applied. For the purpose of a compact construction of the pulse compensation device 36 is the compensation part 42 preferably many times heavier than the diabolo projectile 30 , The Diabolo bullet 30 usually has a weight of about 0.5 grams. The compensation part 42 can thus consist of metal, for example.

The management device 40 is with its longitudinal axis 46 , along which the compensation part 42 is slidably mounted to the barrel axis 16 arranged obliquely. The gas cylinder thus extends obliquely to the barrel axis 16 , The longitudinal axis 46 the management facility 40 is common with the barrel axis 16 in one with 48 designated vertical plane 48 the compressed air weapon 19 arranged. According to 3 cuts the longitudinal axis 46 the management facility 40 the barrel axis 16 or one the barrel axis 16 comprehensive horizontal plane 50 , which is aligned orthogonally to the vertical plane, in one with 52 designated intersection. The point of intersection 52 is regarding the basement camp 28 along the barrel axis 16 in one of the estuary 54 of the barrel 14 pioneering direction arranged axially offset backwards. The longitudinal axis 46 the management facility 40 closes with the barrel axis 16 or the horizontal plane 50 an acute angle α from here about 7 °. The angle α is preferably between 3 ° and 45 °, more preferably between 5 ° and 30 °, most preferably between 5 ° and 25 °.

The compensation part 42 is preferably with a friction brake 56 Mistake. The friction brake comprises a friction element 58 This one in a hole 60 of the compensation part 42 is arranged. The friction element 58 lies by a spring element 62 on the inner wall 64 biased in the radial direction of the gas cylinder. It is understood that the bias of the friction element 56 against the inner wall 62 of the gas cylinder and thus the friction between the compensation part 42 and the guide device 40 is preferably adjustable. Through the friction brake 56 the compensation part is arranged axially fixed in position in its initial position. The friction brake 56 is designed such that the compensation part 42 even with a vertical upright barrel 14 in its initial position relative to the guide device, ie its front end position, remains.

3 shows the compressed air weapon 10 immediately after delivery of a shot. The compressed gas or precompressed gas was in the projectile stock 28 initiates and accelerates the diabolo projectile 30 along the barrel axis 16 in the direction of the estuary 54 of the barrel 14 , One by the acceleration of the projectile 30 generated recoil pulse 66 is coaxial with the barrel axis 16 directed backwards. At the same time the compensation part becomes 42 the front side with the precompressed gas and directly by the gas from its axial positional fixation in its initial position ( 2 ) and beyond in the direction of the longitudinal axis 46 the management facility 40 driven to the rear, ie accelerated. After an unspecified in the drawing embodiment, the arranged in the starting position compensation part 42 be kept axially fixed in position in the starting position relative to the guide device in another way, for example by a catch or by magnetic force. The catch can for example be solved by the precompressed gas or purely mechanically, for example by pressing the trigger. Also, when dispensing a shot, the compensation part 42 in another way, eg. B. by a spring force or by a magnetic force, along the guide device can be driven.

Due to the simultaneous acceleration of the compensation part 42 results in the firing with a 68 designated compensation or counter-pulse. The counterpulse 68 has coaxial with the longitudinal axis 46 the management facility 40 forward. The counterpulse 68 has a first pulse component 68a on that the recoil impulse 66 of the diabolo projectile is counterbalanced and this approximately. One to the barrel axis 16 orthogonally aligned second pulse component of the counter-pulse 68 is with 68b designated. This second momentum component 68b acts on the handle 18 ( 1 ) or the hand of the shooter in the sense of an angular momentum, by the unwanted "high migration" of the barrel even with an incomplete compensation of the recoil pulse 36 through the first pulse component 68a reliably counteracted during the firing. The to the barrel axis 16 obliquely aligned pulse compensation device 36 can be realized with a more compact construction in the running direction, which is particularly favorable for compressed air pistols.

In 4 is the compressed air weapon 10 shown immediately after completion of the shooting. The Diabolo bullet 30 has the run 14 over its mouth 54 leave. The compensation part 42 has reached its rear end position. In this rear end position, the compensation part, the closure part in the direction of the barrel axis 16 tower over to the rear.

For the delivery of another shot is the closure part 22 the compressed air weapon 10 by pivoting the in 1 shown repeating lever 20 axially in the direction of the barrel axis 16 moved backwards. The compensation part 42 is due to a through the friction brake 56 generated friction between the closure part 22 and the compensation part 42 through the closure part 22 in the direction of the barrel axis 16 to the rear against a rear stop 70 of the weapon case 12 guided. At the same time, the bullet bearing 28 thus accessible from outside, leaving another diabolo bullet in the projectile camp 28 can be used.

Will the closure part 22 again forward to its closed position ( 2 ), the compensation part becomes 42 together with the closure part 22 friction mediated - in his in 2 Transferred home position. The compressed air weapon 10 is then ready to fire again.

Claims (9)

Compressed Air Force ( 10 ) for competitive shooting, in particular pneumatic pistol, comprising: - a weapon housing ( 12 ) with a run ( 14 ) and with a bullet bearing ( 28 ) for receiving a projectile ( 30 ), - one on the weapon housing ( 12 ) attached handle ( 18 ) for holding the compressed air weapon ( 10 ); - a pressure vessel ( 24 ) for a pre-compressed gas, by means of which, in the course of delivering a shot, that in the projectile store ( 28 ) projectile ( 30 ) in the direction of the barrel axis ( 16 ) from the barrel ( 14 ) of the compressed air weapon ( 10 ) is expelled; and - a pulse compensation device ( 36 ) with an in or on a guide device ( 40 ) relative to the barrel ( 14 ) displaceably guided compensation part ( 68 ), which, when discharging the shot from its initial position relative to the guide device ( 40 ) in one of the direction of movement of the projectile ( 30 ) deviating direction is drivable, such that one on the handle ( 18 ) as a result of the movement of the projectile ( 30 ) is reduced, characterized in that the guide means ( 40 ) at least in sections to the axis ( 16 ) at an acute angle α with 3 ° ≤ α ≤ 45 °, preferably 5 ° ≤ α ≤ 30 °, is arranged obliquely. Compressed air weapon according to claim 1, characterized in that the guide device ( 40 ) has a rectilinear or substantially rectilinear course. Compressed air weapon according to claim 1 or 2, characterized in that the guide device ( 40 ) with its longitudinal axis ( 46 ) the barrel axis ( 16 ) or one the barrel axis ( 16 ) comprehensive horizontal plane of the compressed air force ( 10 ) in an intersection ( 50 ), which is in one of the mouth of the barrel ( 14 ) pioneering direction of the barrel axis ( 16 ) behind the projectile camp ( 28 ) is arranged. Compressed air weapon according to one of the preceding claims, characterized in that the guide device ( 40 ) is designed as a cylinder, in particular gas cylinder, in which the compensation part ( 42 ) is guided displaceably. Compressed air weapon according to one of the preceding claims, characterized in that the guide device ( 40 ) at least partially by a closure part ( 22 ) of the weapon housing ( 12 ) formed in the direction of the barrel axis ( 16 ), preferably by hand, between a closed position and an open position translationally adjustable on the weapon housing ( 12 ) is stored. Compressed air weapon according to one of the preceding claims, characterized in that the compensation part ( 42 ) before delivery of a shot in its initial position relative to the guide device ( 40 ) Is held axially fixed in position. Compressed air weapon according to one of the preceding claims, characterized in that the compensation part ( 42 ) by means of a friction brake ( 56 ) Is held axially fixed in position in its initial position. Compressed air weapon according to claim 6 or 7, characterized in that when dispensing a shot, a release of the axial positional fixation of the arranged in the initial position compensation part ( 42 ) is effected directly or indirectly by the precompressed gas. Compressed air weapon according to one of the preceding claims, characterized in that the compensation part ( 42 ) is at least partially drivable directly by the precompressed gas.

Images