SE502027C2 - Firing mechanism - Google Patents

Abstract

The present invention relates to an improved type of firing mechanism for barrel weapons, in the first place mortars (1), of the type which comprises a striker pin (9) which is mounted in the rear piece (2) of the gun and is provided with a separate return function (10) for bringing back to the non-firing position and which can, by means of a striker hammer (13) likewise mounted in the rear piece of the gun and displaceable towards the striker pin (9) under the action of a striker spring (14), be acted on in the direction of the firing position. It is characteristic of the arrangement according to the invention that the return function (10) of the striker pin (9) is coupled together with the movements of the striker hammer (13) in such a manner that the striker pin can only reach the firing position in association with it being struck by the striker hammer, subsequently to be brought back to a position in wich no initiation of a shell which has been guided down into the barrel of the weapon can take place.

Description

502 027 Z - fired immediately when they reach the bottom of the barrel completely in accordance with the function of the light grenade launcher. The fact that such an involuntary firing has taken place despite the fact that the hammer has been blocked by a separate securing function has meant an additional uncertainty factor. This weakness of previous firing mechanisms has in peacetime entailed a security risk and could in the event of a war involve even greater risks in that the piece then reveals its position prematurely. The return function in question in its simplest and probably most common form consisted of a disc spring, which in the normal state held the striker back from the firing position but at the same time allowed it to strike this position when it was hit by the hammer during its return stroke.

In accordance with the present invention, this problem has now been solved in that the striking pin, the hammer and the striking spring in firing mechanisms of the present general type are surrounded by a displaceable tubular sleeve, which can be switched from a first position, corresponding to everything except the firing position, to a second position corresponding to this firing position and wherein the sleeve comprises at least one locking lug, designed to cooperate with at least one corresponding lug on the percussion pin and said lugs in the first position of the sleeve force back the percussion pin from the firing position, while the percussion pin with the sleeve in its second position is free initiating the propellant igniter as soon as it is reached by the hammer and the position of the sleeve being determined by a member whose movement is coordinated with the eccentric used to bias the spring by the eccentric forcing back the hammer connected to the spring and releasing it in the turning position of the hammer, and wherein this coordination is so carried out that the sleeve assumes its second position only immediately before the percussion hammer reaches its prestressing / turning position where the eccentric will lose its grip on / in the percussion hammer.

The tubular sleeve characteristic of the firing mechanism according to the invention can advantageously be formed with a centered cavity formed in its front part facing the firearm base of the weapon, which provides space for the main part of the front part of the percussion pin, and an abutting abutment edge between the firearm base and an annular abutment edge. clamped return spring while the sleeve in its rear part said from the barrel bottom has a rear centered cavity, which provides space for a percussion hammer extending in the longitudinal direction of the sleeve and a percussion spring and at least partially surrounding it, a channel running between these two cavities provides space for the rear part of the percussion pin and the return lugs of this and the sleeve.

According to a further development of the firing mechanism according to the invention, its percussion hammer is designed in such a way that when it is thrown by the percussion spring against the percussion pin, it first affects this and is immediately forced back to a position where it has no direct contact with the percussion pin. This function is achieved by providing the hammer with a front stop edge abutting the guide spring via a guide washer, the guide washer being further than the front part of the hammer and with the impact spring in unloaded condition abutting against a corresponding stop edge in the sleeve, which the front of the hammer part in turn is free to pass at its abutment against the rear part of the percussion pin, while the percussion hammer at its other end has a stop edge facing in the direction of the percussion pin against which a second guide washer abuts, the outer dimension of which is adapted to the outer dimension of the strut spring and a stop edge in the sleeve is also turned in the direction of the percussion pin and the percussion spring is clamped between these two washers. With this design on the various details, a percussion hammer is obtained, which when forced back by the previously mentioned eccentric biases the percussion spring clamped between the first and the second guide washer at the same time as the second guide washer abuts against the rear stop edge of the sleeve. When the eccentric during its firing stroke loses its grip on the hammer, it is driven by the strut spring forward in the direction of the striking pin and its front part passes the stop edge at the front guide washer and reaches the striking pin. Immediately before that, however, the rear stop edge of the percussion hammer has reached the rear guide washer and thereby, as a result of its own kinetic energy, has begun to compress the percussion spring from behind.

This compression will, as soon as the percussion hammer has relieved its kinetic energy to the percussion pin, lead to the percussion hammer being forced back from its contact with the percussion pin.

The invention further comprises that the tubular movable sleeve, after being in its second position when the percussion hammer reaches the percussion pin, must be returned to its first position as soon as the percussion pin has had time to initiate the propellant igniter on the grenade. This can advantageously be solved in such a way that the movements of the sleeve are interconnected with the movements of the eccentric in such a way that the sleeve is advanced to its second position immediately before the eccentric under the tension of the spring springs reaches the position where it releases its grip on the hammer. In the same way, the sleeve is forced back to its first position, as soon as the eccentric starts its, '' I 5 Ü 2 Û 2 7 'return stroke to the original position, and the lugs of the sleeve pull the stroke pin back to its securing position. This control of the movements of the sleeve can advantageously be arranged so as to place fl your eccentrics on the same axis, one of which controls the prestressing and firing of the percussion hammer while the other controls the movements of the sleeve.

The firing device according to the invention is defined in the following claims and it will now be described somewhat further in connection with the appended figures. Of these, Figs. 1 generally a grenade launcher with a barrel.

FIG. 2 - 4 a cross section through the back piece of grenade launchers according to Fig. 1 with the firing mechanism according to the invention in three different operating positions and Figs. 5 and 6 oblique projections of the firing knob with associated eccentrics.

The one in Fig. The grenade launcher shown in 1 consists of a barrel 1 with associated back piece 2, support plate 3, a two-legged support 4 and height and side direction devices 5 and 6, respectively. There are also vehicle-mounted grenade launchers and those with several barrels and extremely heavy grenade launchers that can be folded for charging. from behind, but the basic principle of barrels, which are fired very steeply upwards during firing, as well as the use of fin-guided projectiles that themselves contain the required fuel, is found in all these cases.

Figures 2-4 now show the back piece 2 in cross section. This comprises the main part 2a of the rear piece which is threaded into the rear part of the barrel by means of the threads 2b. Furthermore, a hood 7 included in the front part of the rear piece 2a is included partly in this hood and partly in the main part 2a of the rear piece in a cavity 2c adapted thereto. displaceable tubular sleeve 8 consisting of a front part 8a and a rear part 8b. In a recess 8a 'in the front part 8a of the sleeve, a percussion pin 9 is displaceably arranged. The front igniter 9a of the percussion pin 9 has a free passage into the barrel via an opening 7a in the upper part of the hood 7 and reaches in its front position the place where the propellant lighter on a grenade lowered into the barrel will be located. Furthermore, the percussion pin 9 comprises an upwardly extending stop edge 9b facing upwards towards the barrel and a return spring 10 clamped between it and the inside 7b of the hood 7. In its rear part 9c the percussion pin 9 is provided with a return lug 11.

A return lug 12 in the front part 8a of the sleeve 8 corresponds to this. In the rear part 8b of the sleeve 8 a percussion hammer 13 is slidably arranged. This is surrounded by S 502 027 a coil spring type of a coil spring type 14. In the rest position the strut spring 14 is clamped between an upper guide washer 15 and a lower guide washer 16. The upper guide washer 15 in turn abuts against a stop edge 8c facing away from the barrel in the upper sleeve part 8a while the lower guide washer 16 in turn abuts against a stop edge 8d facing the fire tube formed in the lower sleeve part 8b.

In its front part, the percussion hammer 13 has a hammer head 13a which in the rest position by means of a separate stop edge 13b abuts against the upper guide washer 15 but itself does not have a larger diameter than it can pass the stop edge 8c.

The hammer head 13a has in itself the same diameter as the free diameter inside the return lug 11. The percussion hammer 13 further has in its part facing away from the barrel 1 a stop edge 13 :: which in the rest position abuts against the outside of the lower guide washer 16.

In the lower part of the percussion hammer outside the part surrounded by the percussion spring 14 and beyond the stop edge 13c, a clamping lug 17 of a per se known type is movably mounted about an axis 18. This clamping lug is in turn spring-loaded so that its free upper end 17a strives to move out towards the sleeve 8. At the height of the upper edge 17a of the clamping lug 17 when everything is in the rest position, a multi-disc eccentric 19 is rotatably mounted in the main part 2a of the back piece.

As can be seen from Figures 5-6, this eccentric actually comprises three eccentric discs arranged on the same shaft 20, of which the nose 19a passes through an opening 8e in the sleeve 8 and at the rotation of the eccentrics 19ac is first brought into abutment with its clamping edge 19a '. 17 upper edge 17a and thereafter the clamping lug 17 and percussion hammer 13 force backwards downwards under prestressing of the percussion spring 14. At the same time, the two other eccentrics 19b and 19c shift the sleeve 8 from the rear first position shown in Figure 2 to the front second position shown in Figures 3 and 4. This means that the stop edges 11 and 12 no longer abut each other and the percussion pin 9 is free to move forward provided that the force from the return spring 10 can be bridged. The eccentrics 19a and 19b also pass in through the opening 8e and act directly against its upwardly and downwardly delimiting edge sides 8e 'and 8e ", respectively, and thus control the displacement of the sleeve by lifting and pushing it back, respectively. 5 0 2 0 2 7 ° Then the eccentric 19a has reached its lowest position shown in Fig. 3, its clamping edge 19a 'slides off from the upper edge 17a of the clamping lug 17 and the latter comes into abutment instead against the curved part 19a "of the eccentric 19 from which it will slide off when the clamping lug 17 one's own spring is forced to the side. The percussion hammer 13 is released and this is driven by percussion spring 14 in the direction of the percussion pin 9. The percussion head 13a passes the stop edge 8c and drives the percussion pin 9 at the same time as the guide washer 15 is caught by the stop edge 8c and some of the percussion hammer's kinetic energy is used. striking spring this time from the rear starting from the guide washer 16 which in turn is forced forward by the stop lug 13c. As soon as the percussion hammer 13 has relieved its kinetic energy to the percussion pin 9, this limited bias produced from behind will retract the percussion hammer from its direct contact with the percussion pin.

The eccentrics 19a, b and c are suitably connected in a known manner to a return spring which, however, is not drawn in the figures. When the eccentrics begin their return stroke, the eccentrics 19a pass past the clamping lug 17 which springs away while the eccentrics 19b and c, by abutment against the edge 8e ", shift the tubular sleeve 8 characteristic of the invention back to its first position.

In this case, the stop edge 12, by abutment against the stop edge 11, forces the percussion pin 9 back to the position shown in Figures 2 and 3. Normally, the return spring 10 handles this on its own, but the displaceable tubular sleeve characteristic of the invention is a complete guarantee that as soon as the knob 21 with which the eccentrics are operated has returned to the original position, there is no longer any possibility for the percussion pin to remain in its front firing position. The figures also show the minor details 22 which are a stop screw for the eccentric rotation and 23 which mark a pressure relief channel. The reference numeral 24 in turn marks the lever with which the eccentrics are operated.

Claims (6)

7 502 027 Eatsntkrax A firing mechanism for barrel firearms, primarily grenade launchers, of the type comprising a striking pin (10) stored in the back of the piece (2) for the return to non-firing position (9), which is also stored in the back of the piece under the action of an impact spring (14) against the impact pin (9) displaceable impact hammer (13) can be actuated in the direction of the firing position, the impact hammer (13) in turn being actuated by an lever rotatable eccentric (19) against the action of the impact spring (14) can be displaced to a biasing position where the eccentric (19) loses its grip in the percussion hammer (13) and this is driven by the percussion spring (14) towards the percussion pin (9) characterized by the percussion pin (9), the percussion hammer (13) and the percussion spring ( 14) is surrounded by a slidable sleeve (8) which can be switched from a first position, corresponding to everything except the firing position, to a second position corresponding to this firing position and wherein said sleeve (8) comprises at least one locking lug (1 2) designed to cooperate with at least one corresponding lug on the striker pin (11) and wherein said lugs (11 ropes 12) in the first position of the sleeve (8) force the striker pin (9) back from the firing position while it with the sleeve (8) in its second position is free to initiate the propellant igniter of the grenade as soon as it is reached by the hammer (13) and the position of the sleeve (8) is determined by a member (19b and c) whose movement is coordinated with the movements of said eccentric (19a) in such a way that the sleeve (8 ) first enters its second position immediately before the percussion hammer (13) reaches the bias position where the eccentric (19a) loses its grip on the same. A firing mechanism according to claim 1, characterized in that the sleeve (8) in its front part facing the electric tube bottom of the weapon has a centered front cavity (8a ') which provides space for the front part of the percussion pin (9) and one between the gun barrel bottom and a annular abutment edge (9b) on the striking pin clamped return spring (10) of the coil spring type while the sleeve (8) in its rear part (8b) facing away from said barrel bottom has a rear centered cavity which provides space for a hammer (13) extending in the longitudinal direction of the sleeve and a percussion spring (14) surrounding it, a channel running between these two cavities which provides space for the rear part of the percussion pin (9) and its return lugs (12 and 11, respectively). 5 Û 2 0 2 7 ' Firing mechanism according to claim 1 or 2, characterized in that the percussion hammer (13) has a front stop edge (13b) abutting against the percussion spring via a guide washer (15), the guide washer being further than the front part (13a) of the percussion hammer and with the percussion spring in relieved condition abuts against a corresponding stop edge in the sleeve (8c) which the front part (13a) of the hammer of hammer is free to pass at its abutment against the rear part of the percussion pin (9). A firing mechanism according to any one of claims 1-3, characterized in that it comprises a first eccentric disc (19) mounted in the rear piece (2) of the piece around the shaft (18) of the piece with a clamping edge (19a ') arranged in the rear of the piece. the rotation of the eccentric is brought into abutment against the free end of a clamping lug (17) mounted in the rear part of the hammer (13) around a transverse shaft (18) which is pressed by a spring in direction towards the eccentric (19a), and at least one second eccentric disc (19b and c) whose movements are coordinated with the first eccentric disk (19a) and whose movements control the movements of the movable sleeve (8) in the manner indicated. Firing mechanism according to either of Claims 1 to 4, characterized in that the first (19a) and the second eccentric (19b and c) sit on the same shaft (20). A firing device according to any one of claims 1-5, characterized in that it comprises a securing knob stored separately in the back of the piece with which the movable sleeve can be locked in its first position.