The invention relates to a firearm comprising a receiver carrying a fixed barrel, a magazine with cartridges that can be inserted into a seat of the receiver, and a slide movable relative to the receiver in the longitudinal direction of the barrel in order to transfer cartridges from the magazine into a chamber in the receiver and to move cartridge casings from the chamber to an ejection port.
The most common action used today in self-loading firearms is the Browning system. To accomplish the self-loading process, gas pressure built up when a shot is fired is used to accelerate the slide to the rear and thereby eject the cartridge casing and reload a new cartridge from a magazine. The gas pressure when a shot is fired is initially very high and must be absorbed by appropriate mechanisms in the action before the remaining energy can be used for the movement of the slide. In the Browning system, the slide and the barrel are one subassembly when a shot is fired and are accelerated backward together by the gas pressure. The slide is usually embodied as a movable carriage atop the receiver. Together with the barrel, this subassembly consequently has a very high mass inertia so that it can effectively reduce the initially high gas pressure. After a first segment of motion during the returning of the barrel/slide subassembly, the barrel is pivoted downward toward the receiver as a result of appropriate control guides and/or connecting members and thereby decoupled from the slide, whereupon the slide continues rearward alone and carries out the reloading process.
One disadvantage of this model is that the barrel is not firmly seated in the receiver, which leads to reduced precision and greater susceptibility to malfunction. For this reason, numerous efforts have been devoted to the creation of a self-loading action that eliminates the above-described disadvantages and allows a self-loading firearm with a fixed barrel to be constructed. One example of such a system is the blowback action. In that system, the slide is formed by two masses that engage in the receiver by roller bearings. When a shot is fired, both masses of the slide are moved rearward, and the roller bearings are pressed inward from their respective seats in the receiver and drive the two masses of the slide apart. This results in unequal acceleration of the two masses of the slide, whereby the initially high gas pressure is likewise made available for driving the cartridge before the residual energy is used up for the movement of the slide and the reloading process. One disadvantage of this system is that the construction is very complicated and requires a great number of parts, which substantially increases the susceptibility to malfunction.
It is the object of the present invention to provide a firearm having an action for a self-loading process that eliminates the above-described disadvantages of previous actions and can be manufactured inexpensively with few parts, thereby also reducing its susceptibility to malfunctions. At the same time, the firearm is to have a fixed barrel, and the action is to have such a compact construction that it can be implemented so as to fit completely inside the weapon, which provides advantages in terms of functional reliability, since contaminants from the outside are largely ruled out.
This object is achieved according to the invention in that the slide is supported inside the receiver over its entire movement path, and that a drive clip supported inside the receiver is coupled with the slide and is biased by a recoil spring toward a front closed position, and that a latch block supported inside the receiver is also coupled with the slide when the slide is in the front closed position, the latch block being biased by a latch spring toward this position, and, upon firing of a shot under compression of the latch spring, the latch block being displaceable together with and by the slide only for a portion of the movement path of the slide until a decoupled position is reached. In the closed, ready-to-fire position, the slide, latch block, and drive clip form a subassembly moved rearward when a shot is fired. The initially high gas pressure consequently acts against the applied spring force as well as against the masses of the three components, which keeps the breech closed long enough to fire the cartridge. The subassembly is then moved rearward until the latch block reaches the decoupled position. At this point the latch block is decoupled from the slide, and the slide and the drive clip alone continue moving rearward. In order to enable all of the parts to be accommodated inside the receiver, the slide, latch block, and drive clip must be made correspondingly small, which means that they have a low mass inertia. In order to ensure that adequate counterforces for the initially high gas pressure can be applied nonetheless, the spring forces are selected appropriately in order to compensate for the lack of mass inertia.
It is another advantageous feature that the latch spring has a higher spring constant than the recoil spring. The latch spring, together with the inertia of the latch block, must keep the breech closed long enough in the initial phase of the firing of a shot that the cartridge can exit the barrel. These parts are then intended to reduce the forces accordingly, so that the remaining energy from the decoupled position is sufficient for the reloading process, which reloading process is carried out by the slide, drive clip, and recoil spring.
According to another advantageous feature, the slide has lateral projections that extend normal to its direction of movement and engage with corresponding stop faces on the latch block on movement from the front closed position to the decoupled position, and vice versa. The latch block can, for example, have stop faces in the form of lateral hooks that hook onto the lateral projections on the slide and bias them toward the closed front position by the force of the latch spring. During the rearward movement, the latch block can, for example, be pivoted downward at the decoupled position, as a result of which the hooks disengage from the projections.
An advantageous embodiment of the invention is that the latch block has bearing pins that extend normal to the longitudinal direction of the barrel and are guided in slide tracks in the receiver, each of the slide tracks having a rear end portion that deviates from the direction of movement of the slide at an angle thus enabling the latch block to move into the decoupled position upon entry of the bearing pins into these end portions. Pivoting of the latch block into the decoupled position can thus be achieved very easily by an appropriate guide groove in the receiver. As will readily be understood by those with average skill in the art, the bolt can also be on the receiver and the slotted guide on the latch block depending on the design of the firearm.
It is also an advantageous feature of the present invention that the drive clip has securing projections that, on reaching the decoupled position, engage in corresponding recesses in the latch block during the rearward movement of the slide after a shot is fired and secure the latch block for the continuing movement path of the drive clip in the setting of the decoupled position. These securing projections can, for example, be embodied as ribs that extend in the longitudinal direction of the barrel and, once the decoupled position is reached, plunge into corresponding longitudinal grooves in the latch block as soon as the drive clip travels further to the rear. The drive clip thus secures the latch block in this pivoted-out position until it passes the decoupled position on the way back toward the front closed position and releases the latch block again. The latch block then pivots up again and engages with the stop faces on the projections on the slide and thus pulls it back into the closed front position with the aid of the latch spring.
Finally, it is another advantageous feature that the recoil spring is supported between a bearing portion of the drive clip and a bearing portion of the latch block. As a result, the latch spring alone is compressed in the first segment of motion between the front closed position and the decoupled position, and the recoil spring is compressed only once the decoupled position is reached. Depending on the application, the spring forces can thus be defined very precisely in every position of the motion sequence.
The invention will now be described in greater detail with reference to an embodiment and the accompanying drawings, wherein
Furthermore, a latch block 8 is inside the receiver 1 and mounted in the receiver by lateral bearing pins 12 in respective slide tracks 13. A bearing portion 18 is located at the front end of the latch block 8, and a latch spring 9 is braced between the receiver 1 and the bearing portion 18. On the other hand, the recoil spring 7 is supported between the bearing portion 17 of the drive clip 6 and the bearing portion 18 of the latch block 8. Abutment surfaces 11 are present at the rear end of the latch block 8 in the form of upwardly open hooks that cooperate with corresponding lateral projections 10 on the slide 3 and bias it toward the front closed position.
During this rearward movement, lateral securing projections 15, here in the form of lateral ribs on both sides of the drive clip 6, slide into corresponding grooves 16 (see
After reaching the rearmost end position (see
Number | Date | Country | Kind |
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A50662/2017 | Aug 2017 | AT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AT2018/060180 | 8/7/2018 | WO | 00 |