NO155513B - Firearms. - Google Patents

Description

The present invention relates to a firearm comprising a housing, a chamber and an activation mechanism, the activation mechanism comprising a breech block which can be displaced longitudinally according to the housing of the weapon and has a front end for contacting and pushing a cartridge forward into the chamber , a firing pin which can be displaced longitudinally relative to the housing and the breech, resilient means which can be stressed by forward movement of the breech relative to the firing pin, a hook device which can be connected to the firing pin to prevent longitudinal movement of the firing pin relative to the housing, and an articulated mechanism comprising a first and second articulated arm and forming at least part of an operative link between a trigger and the breech, the first articulated arm being hinged in a first hinge point with the breech, and the second articulated arm being hinged in a second hinge point with the house, as the first hinge point is located in front of the second hinge point, and the first and second link arms are hinged to each other at a third hinge point and the trigger is operatively connected to the link mechanism so that the first movement of the trigger moves the third hinge point into alignment with the first and second hinge points so that the breech moves forward and the spring means are stressed.

Such a firearm is known from FR-PS 363122. This document describes a firearm in which the breech is moved by means of the trigger, via a firing mechanism. The patent's fig. 1-3 show bolts which are believed to cause locking. To bring the bolts into the detent position, the breech must be moved further forward than to the detent position. This means that the bolts have clearance in relation to their abutments against the breech, and consequently the breech will, when fired, carry out a certain recoil movement before hitting the bolts. This naturally results in unacceptable wear and tear, and the principle does not seem to be usable in practice.

The purpose of the present invention is, in a firearm as stated at the outset, to achieve a positive blocking of the breech, without the possibility of any significant recoil movement.

According to the invention, this is achieved by continuing movement of the trigger, the joint mechanism moves past the straightened position to lock the breech in the forward position and release the catch device.

The breech block is thus blocked without the possibility of any recoil movement, and the harmful effects of such movements are avoided.

According to one embodiment of the invention, the hook device comprises a hook that can be brought into engagement with a recess in the firing pin, and a mechanical connection is operatively arranged between the joint mechanism and the hook to release the hook from the recess after the joint mechanism has been moved past the fully straightened position.

The mechanical connection may comprise a release bolt for the chin, displaceable across the firing pin, so that one end of the bolt can contact the chin and the other end of the bolt can contact the joint mechanism, the length of the bolt being such that when the joint mechanism is moved past the straightened position it pushes the bolt against the chin to release the chin from the recess.

In some cases, cartridges with a relatively small amount of propellant can be used, e.g. when firing warning or scare shots, i.e. such shooting which is not intended to have any physical effect. A reduced amount of gunpowder makes it possible that the cartridge case does not need to be in contact with a chamber wall when firing. This can be exploited by not feeding the cartridge completely into the chamber before firing, which means that the force with which the trigger must be moved can be reduced, as it is movement of the trigger that leads the cartridge into the chamber. When the cartridge is to be inserted completely, the movement of the breech is long. However, the movement of the trigger is short, and consequently a great deal of force must be applied to the trigger. According to one embodiment of the invention, the trigger mechanism is arranged to move the breech forward a length which is sufficient to only introduce a cartridge partially into the sleeve portion of the barrel, so that the cartridge sleeve mainly lacks support during firing. This can thus be carried out with relatively little force against the trigger.

Preferably, the weapon comprises a magazine for supplying cartridges to the chamber as the empty case for fired cartridges is removed from the chamber.

In the following, the invention will be described by means of examples, with reference to the attached drawings, where fig. 1 is a side projection along the line I-1 in fig. 2, of a first embodiment of a weapon according to the invention, fig. 1A, shows a part of fig. 1 on an enlarged scale,

fig. 2 shows a plan projection, partly in section, of a part of the weapon shown in fig. 1,

fig. 3 shows a section along the line III-III in fig. IA,

fig. 4 shows a section along the line IV-IV in fig. 2,

fig. 5 shows a section along the line V-V in fig. 4,

fig. 6 shows a section along the line VI-VI in fig. 3,

fig. 7 shows a section along the line VII-VII in fig. 3,

fig. 8 shows a side projection of a cartridge suitable for use in the weapon of fig. 1 to 7,

fig. 9 shows an end projection of the cartridge shown in fig. 8, fig. 10 shows a side projection of another embodiment of the weapon according to the invention, which is also intended to use cartridges of the type shown in fig. 8 and 9, fig. 10A shows a part of fig. 10 on an enlarged scale,

fig. 11 shows a plan projection, partly in section, of part of the weapon in fig. 10, and

fig. 12 shows a section seen from the underside, of a charging lock which forms part of the weapon in fig. 10.

As shown in fig. 1 to 7, a self-loading weapon comprises a

barrel 1, a rotary magazine assembly 2, a housing 3 containing a breech block and a firing mechanism, a butt assembly 4 and a pistol grip 5. A trigger 6 is hinged at 7 at the bottom of the pistol grip 5, and is actuated for anti-clockwise rotation about the hinge 7 by by means of a double-bladed catch 8 which presses against the back of the pistol grip 5. A trigger guard 9 protects the trigger against accidental use.

The hinge at 10 of the forward, upper part of the trigger is a joint member 11, which projects substantially rearward from the hinge point 10. The hinge to a hinge point 12 on the rear end of the joint member 11 is a rearward extension of a first joint arm 13. The joint arm 13 is in its front end hinged by means of a hinge 14 to an end piece 15 which can be moved longitudinally in the housing 3. The hinge with a hinge 16 to an intermediate point on the first joint arm 13 is another joint arm 17 which projects backwards from the hinge 16, and is hinged to the housing 3 with a hinge 18.

Movable in the longitudinal direction inside a channel 19 in the breech piece 15 is a firing pin 20 which has a hardened front end 20A and a side part 20B which can lie against a pin 21 which is held locked in a transverse bore in the housing 3 (fig.2).

A strong, helical compression spring 22 equipped with an abutment washer 23 is located behind the firing pin 20 in the bore 19, between a locking pin 24 and a shoulder 25 in the bore 19. A relatively weak, helical return spring 26 is also located in the bore 19, between a forward-facing shoulder 27 on the firing pin 20 and a shoulder 28 in the bore 19.

A hook 29 which is hinged to the housing 3 in a hinge 30 is actuated to swing clockwise (as shown in fig.

1) about the hinge 30 by means of a spring 31, to abut against the firing pin 20. The end of the hook 29 can, through a longitudinal slot 32 in the end piece 15, engage with a recess 33 on the firing pin 20, to prevent forward movement of the firing pin. A trigger bolt 34 for the chin of substantially cylindrical shape can be displaced in a transverse bore 35 in the firing pin 20. The bolt 34 has a flat portion 36 formed on its lower portion, but this does not project to the lower end. The width of the bolt 34 in the cross-section of the flat part 36 is such that it is possible for the bolt to be displaced along a longitudinal slot 37 in the end piece 15, with a width that is smaller than the full diameter of the pin 34. The length of the flat part 36 in direction of the bolt's axis is such that a limited transverse displacement along the bore 35 is enabled, but the bolt 34 is prevented from moving completely out by the parts that have a full diameter coming into contact with the edges of the slot 37. During assembly, the bolt is inserted into the slot 37 through an entry hole 38 in the breech piece 19, but during normal use of the weapon the relative movement between the firing pin 20 and the breech piece is limited so that the bolt 34 does not line up with the entry hole 38. The magazine device 2, which does not form any part of the invention, comprises a magazine housing 40 and a spindle 41. The spindle is attached to the weapon's housing 3 by means of a screw 42, and the magazine housing 40 is attached to the spindle by means of a screw 43. A collar 44 on the housing 40 is located inside a corresponding groove in the housing 3, and correct alignment is ensured by means of a guide pin 45 (fig. 2) which is attached to the housing 40 and fits snugly into a corresponding recess in the housing 3. Bearing for rotation on the spindle 41 is a star wheel assembly comprising a front star wheel 46 and a rear star wheel 47 which are connected to rotate together by means of connecting elements. The star wheels 46 and 47 have mutually quite similar cross-sections, as best shown in fig. 3 and 4, each wheel comprising five evenly spaced and radially projecting arms 48, 49 which are designed so that between each pairs of neighboring arms are delimited by recesses 50, 51 which make up slightly less than half circles, the recesses in the two star wheels being axially aligned one after the other. The star wheel device 46, 47 is operated in clockwise rotation, as shown in fig. 3, by means of a pair of helical torsion springs 52, 53 mounted around the spindle 41. At the front end, the springs 52, 53 have protrusions which lie against a transverse pin 54, to prevent rotation around the spindle.

At the rear end, the springs 52, 53 have protrusions which are

led into corresponding holes in the front surface of the star-wheel part 47. Thus, when the star-wheel device 46, 47 is turned anti-clockwise (as shown in Fig. 3), a return torsional force is produced by the springs 52, 53.

one 52, 53 is imparted a certain degree of torsion during assembly, so that they affect the star wheel arrangement for clockwise rotation as shown in fig. 3.

Each arm of the star wheel 47 is equipped with a rearward projecting projection 55 which, when the star wheel rotates, moves freely in an annular recess 56 in the nearest end surface of the housing 3. As shown in fig. 5, a latch 57 which has a slot-shaped swing bearing 58 in the housing 3 is driven forward by the action of a spring-actuated piston

el 59, and the forward movement of the latch is limited by a latch pin 60. The latch 57 has a chin portion 61 arranged to, in the forward position, come into contact with and block an adjacent projection 55. The latch 57 also has a cam surface 62 which can come into contact with the outer end of the pin 21.

A weight arm 63 is arranged which comprises a pair of curved arms 64, 65 which can swing freely on the spindle 41 just in front of the star wheel 46, and on a boss formed on the front part of the star wheel 47. The arms 64, 65 are rigidly connected by a control rod 66 which protrudes in the longitudinal direction.

With particular reference to fig. 3, 6 and 7, a loose pin 68 is inserted into a longitudinal bore in the front curved arm 64, the pin being held locked between the front surface of the star wheel 46 and the rear surface of the housing 40. As shown, the front end of the pin 68 inserted into a curved recess 69 in the front surface of the housing 40, and the rear end of the pin 68 is inserted into an annular groove 70 in the front surface of the star wheel 46. A cross bolt 61 fixed with glue in a radial bore in the star wheel 46 projects across the groove 70, and acts as a stop, to prevent the star wheel device 46, 47 from performing anything significantly more than a simple revolution in relation to the weight arm 63.

The pin 68 has a greater length than the depth of the groove 70 plus the thickness of the front, curved arm 64, so that the pin 68 normally projects into the recess 69 so that the weight arm 63 is kept locked against the housing 40, while the star wheel device can rotate relative to this, the groove 70 provides clearance for the pin 68.

A conical recess 72 is arranged in the bottom of the slot 70, near the transverse pin 71. When the star gear assembly 46, 47 has completed almost a full revolution relative to the housing 40 from the position shown, the end of the pin 68 inside the slot 70 can enter the recess 72, which has sufficient depth so that the other end of the pin 68 can move clear of the recess 69. The weight arm 63 can then move relative to the housing 40 between limits determined by an opening 73 for the introduction of cartridges, and disconnection of the pin is simplified due to the curved shape of the recess 69. During this movement, the star wheel 46 and the weight arm 63 are locked together by the pin 68.

The ammunition for which the firearm is designed is shown in fig. 8 and 9. It comprises a cylindrical sleeve 74 containing a projectile (not shown), such as e.g.

a so-called rubber ball. The cartridge is also equipped with a projecting flange 75 on the rear end, and in the rear surface 76 is arranged a percussion cap 77 with which the cartridges can be fired. The sleeve is designed in such a way that it is mainly self-supporting, that is to say that insertion into a supporting chamber to prevent the sleeve from bursting when the cartridge is fired is unnecessary.

The cartridges can be inserted into the magazine through the opening 73. Insertion of a new cartridge is simplified due to a recess 78 on the front surface of the magazine housing 40, delimited by a beveled part 79. After insertion through the opening, the cartridge is located in a pair of recesses 50, 51 which results in a specific location for the cartridge in the star wheels 46, 47. When the star wheel device rotates, the front end of the sleeve 74 is prevented from moving radially outwards due to a partially circular cam 80 which extends around the entire front surface on the housing 40, with the exception of the part at the opening 73 (see fig. 3). At the rear end, the sleeve is prevented from moving radially outwards due to a curved edge 81. The sleeve is prevented from moving axially around the entire circumference of the housing, with the exception of the portion at the opening 73 and the chamber portion, by a radially inwardly directed lip 82 behind which the flange 75 is located. In the area near the chamber, the cartridge is blocked axially by a lip 39 on the breech piece 15. The concave surfaces of the curved arms 64, 65 of the weight arm 63 are approximately semicircular, for reasons explained later, the radius being approximately equal to the radius of the sleeve 74.

At the chamber end, the barrel 1 is equipped with a very short chamber in the form of a sleeve portion 83, into which the front end of a cartridge can be inserted. The sleeve part 83 has a shoulder 84 that the cartridge cannot pass, and entry into the chamber is simplified by means of a short, chamfered part 85.

When using the firearm, any number of cartridges up to five can be placed in the magazine by successively inserting through the opening 73. When the first cartridge is inserted, the insertion is simplified due to the recess 78 and the chamfered part 79. The weight arm 63 is blocked of the pin 68 in the position shown. The weight arm can thus swing to a position where it prevents the introduction of the cartridge. When the cartridge is pressed in and into place, the arms 64, 65 guide the cartridge so that it moves in a counter-clockwise direction (as shown in Fig. 3), to align with the barrel, that is, towards the chamber position. The sleeve 74 of the cartridge thus rests against the arms 48, 49 of the star wheels 46, 47 and moves the star wheels clockwise (as shown in Fig. 3), against the torsional force of the springs 53, 54, until the cartridge is fully inserted into a pair of recesses 50, 51. When the cartridge reaches the position where it is aligned with the barrel 1, the catch 61 on the detent 57 moves, under the action of the spring-actuated piston 59, into place behind the projection 55 on an arm 49. The star gear device is thus held in this position against the force of the springs 53, 54 due to the detent action of the detent 5 7, with the cartridge in the chamber aligned with the barrel.

A second, third and distant cartridge can be inserted in exactly the same way as described above. When the cartridges move around in the magazine, they are held in the recesses 50, 51 on the star wheels 46, 47 and are blocked against outward movement by the edges 80, 81, while movement in the longitudinal direction of the cartridges is prevented by the lips 39 and 82 which grip the flanges 75.

However, when it is desired to introduce a fifth cartridge, the weight arm blocks the path for the first cartridge. This problem is overcome in the following way. When the fifth cartridge is fed in, the star wheel 46 moves to the position where the recess 72 is aligned with the pin 68. When the first cartridge presses against the weight arm, the pin 68 is driven due to the camming action of the curved surface in the recess 69, so that it moves into the recess 72, so that the weight arm is simultaneously released from the magazine housing 40, and is instead blocked by the star wheel 46. Thus, as the effect of the introduction of the fifth cartridge continues, the first cartridge moves around and into the opening 73. The first cartridge is, however, prevented from escaping through the opening 73 by the weight arm 63 which is a stopper for the star wheel 46, so that the semicircular recesses 50, 51 together with the recesses formed by the arms 64, 65 surround the cartridge over approximately 3/4 of its circumference.

When the trigger 60 is pulled while the magazine 2 is loaded, the following occurs. The joint element 11 moves backwards and is thus forced to swing anti-clockwise (as shown in Fig. 1). The hinge 12 is thus driven upwards so that the joint mechanism comprising the first joint arm 13 and the second joint arm 17 begins to straighten. The breech piece 15 thus moves forward due to the hinge connection 14, and brings with it a cartridge which is positively locked behind the lip 39. As the breech piece moves forward, the cartridge is displaced longitudinally through the recesses 50, 51, to be placed in the sleeve portion 83 in the barrel 1.

When the breech piece moves forward, the firing pin 20 is held by the hook 29, so that the spring 22 is compressed between the firing pin 20 and the locking pin 24. When the joint mechanism 13, 17 comes to the fully straightened position, the cartridge is guided all the way into the sleeve portion 83, and the breech piece is secure blocked against backward movement. A slight further movement of the trigger brings the joint mechanism to a position where it is locked slightly past the fully straightened position, with the upper surface of another joint arm 17 lying against the release bolt 34, so that this is pushed upwards to release the catch 29 from the firing pin 20. The firing pin fires then forwards under the action of the spring 22, until it reaches the position shown in fig. 1, where the abutment disc 23 engages the shoulder 25. The firing pin then continues forward at high speed, due to its own inertia, so that the hardened end 20A strikes the percussion cap 77 to fire the cartridge. It will be seen that the case of the cartridge is almost completely unsupported at the moment of firing.

As the firing pin moves forward, it compresses the return spring 26 between the shoulders 27 and 28. As the firing pin approaches the firing position, the portion 20B contacts the pin 21 and drives it outwards due to a cam action against the side surface of the firing pin 20. The outer end of the pin 21 now protrudes in front of the cam surface 62, but only if the firing pin has moved all the way forward for firing the cartridge.

When the trigger 6 is released, it returns under the action of the leaf spring 8, the link mechanism 13, 17 is pulled down due to the return of the link 11, and the breech block 15 is thus pulled back towards the original position,

and brings with it the firing pin 20 and the spent sleeve held by the lip 39.

During the return movement, the firing pin remains in a forward position relative to the breech (but is pulled back b"'.en the forward face of the breech by the spring 26). The pin 21 is thus held out during the return movement, due to contact with the side of the firing pin. When the breech piece moves back, the pin 21 lies against the surface 62 of the latch 57, to pull the latch backwards and to release the chin part 61 from the adjacent projection

55. The star gear device 46, 47 is thus released from the latch 57, which now moves downwards in the slotted hinge to release the pin 21 and to be moved to the position where it is ready to block the subsequent projection 55. The star gear device 46, 47 is prevented from to rotate due to the action of the springs 52, 53 until the spent sleeve has exited the sleeve portion 83 and the chamfered portion 85, and the breech has exited the star wheel 47. When this stage is reached, the star wheel assembly is released to rotate forward under the action of the springs 52, 53, until the detent 57 comes into contact with the following projection 55. The used sleeve is thus automatically driven through the opening 73, and the next cartridge (if present) in the magazine is automatically turned around to align with the breech piece 15 and the sleeve portion 83 , there. it is ready for firing. However, it should be noted that this sequence can only occur if the firing pin 20 is released and has moved forward to fire a cartridge, so that the possibility of an unused cartridge being accidentally ejected is prevented.

When the breech block is pulled all the way back, the catch moves

29 itself due to the force from the spring 31 again into engagement with the recess 33 on the firing pin.

As long as the magazine contains new cartridges, the sequence can be repeated and all the cartridges in the magazine can thus be fired in rapid succession by repeated use of the trigger.

If it is desired to remove cartridges from the magazine without firing, this can be achieved by manually depressing the end (visible in Figs. 2 and 5) of the latch 57, after which the star wheels 46, 47 are released and the cartridges are automatically ejected one after the other in a similar manner such as the ejection of empty casings. Further rotation of the star wheel device could undo the entire torsional bias in the springs 52, 53 and thus prevent subsequent, correct functioning of the magazine loading. This is prevented by the pin 68, which comes into contact with the cross pin 71 just after the last cartridge has been ejected.

The embodiment of the invention shown in fig. 10 to 12 comprises a housing 101 in one with a barrel 102, a magazine housing 103, a pistol grip 104 and an adjustable butt 105. The magazine housing 103 and the pistol grip 104 are made of pressed steel, and a trigger guard 106 is welded to these. The unit is attached below an opening in the housing 101 by means of a tab 107 on the pistol grip and a transverse bolt 108 which is passed through a forward protrusion (not shown) on the magazine housing.

The magazine housing 103 contains a wire spring 109 attached to the bottom of the housing by means of rivets 110. Supported on top of the spring 109 is a magazine platform 111 having an upper surface of substantially semi-cylindrical shape. The flat form 111 is hollow and can contain the compressed spring 109 when it is fully pressed into the housing 103.

An opening 112 is arranged in the upper surface of the housing 101 above the magazine housing, and through this, cartridges of the type shown in fig. 8 and 9 are entered. A groove 113 is provided in each side wall of the opening, to contain the flange 75, and the wall portions near the upper edge of the opening 112 form surfaces 114 between which the cylindrical sleeve 74 of a cartridge can pass, but not the flange 75. Below the surfaces 114 the opening is widened to enable the insertion of a flange 75. At the front end of the opening 112, the rear end of the barrel 102 has an upper projecting portion 115 under which the front end of a cartridge can be held, and a lower, chamfered portion 116 which can guide a cartridge downwards and backwards into the magazine housing 103. The rear end of the barrel also has

a sleeve portion 117 which forms a short chamber into which the front end of the sleeve 74 can be inserted before firing.

A loading catch 118 is hinged at 119 in the pressed steel part 103, 104 and is acted upon in a clockwise direction (as shown in Fig. 10) by a spring 120. The loading catch 118 has a pair of branches 121 which project forward into the opening 112, a pair of branches 122 which project backwards, and are equipped with a curved recess 123 in the upper surface.

The rear part of the housing 101 is mainly cylindrical in shape, and a cylindrical part of the adjustable flask 105 can be displaced longitudinally in this, so that the flask length can be easily adjusted to suit the user. The adjustable piston can be locked in the desired position by inserting a locking pin 104 through holes arranged in the housing 101 and the piston 105.

Displaceable in the longitudinal direction in the housing 101 in front of the piston 105 is an end piece 125 of mainly cylindrical shape. Displaceable in the longitudinal direction inside bores 126 and 127

in the end piece 125 is a firing pin 128 and a detent block 129. The firing pin can be driven forward in relation to the end piece by a firing pin spring 130 which has a washer 131 at the front end. The forward movement of the spring 130 is limited by the disc 131, which comes into contact with a shoulder 133 in the bore 126. The spring 130 is held in the bore 126 at the rear end by a transverse pin 132 which is located at the rear end of the breech. A relatively weak return spring 134 for the firing pin acts between a shoulder 135

in the bore 126 and a shoulder 136 on the firing pin 128, to drive the firing pin backwards.

The chin block 129 is driven forward by a spring 137 whose rear end also acts against the transverse pin 132. The hinge on a transverse hinge 138 inside a longitudinal slot in the chin block 129 is a hook 139. The chin has a recess in its upper edge, which engages with a transverse pin 140

which is located in the housing 101. The chin also has a nose that can engage a recess 141 in the firing pin 128. A trigger bolt 142 can be displaced vertically in a bore that projects through the firing pin below the recess for the chin. The bolt 142 is generally cylindrical in shape, but has

a part 143 with a reduced diameter which can be displaced in the longitudinal direction inside a longitudinal slot 144 in the breech piece 125. During assembly, the bolt 142 can be inserted into the slot 144 through an entry hole 145, but cannot move out of this during normal use of the firearm. The bolt can move vertically between limits determined by the length of the reduced diameter portion and the depth of the slot 144.

The hinge of the breech piece 125 at 146 is a first link arm 147. The hinge of the housing 101 at 148 is a second link arm 149. The first and second link arms are hinged to each other at 150, to form a link mechanism which is acted upon in the downward direction by a spring 151 .

A trigger 152 is hinged at 153 to the pistol grip 104, and the hinge connection is secured by a spring clip 154. The upper face of the trigger is shaped like a V, and the lower face of the second link arm rests against the rear arm of this V.

A pin 155 has an enlarged head 156 which holds it locked in a stepped bore 157 in the breech 125, the bore 157 being sloped forward and downward from the bore 126 to the outside of the breech. The pin 155 is prevented from escaping upwards and backwards from the bore 127 due to contact with the underside of the firing pin 128. When the firing pin is in a rearward position relative to the breech piece 125, the head 156 of the pin can be retracted into a groove 158 in the front , lower side of the firing pin, so that the lower end of the pin 155 can be pulled back into the breech. As the firing pin approaches the forward position relative to the breech, a curved portion of the groove 158 pushes the pin 155 downward so that it protrudes from the breech.

As shown in fig. 11, a movable extractor 159 has an open slot 160, with which it is held by means of a transverse pin 161 fixed in the end piece 125. The extractor 159 can be displaced in the longitudinal direction relative to the end piece in a slot 162 in the housing 101 and a slot 163 in side of the breech, and can also pivot on the pin 161 to the extent permitted by the available space between the grooves 162 and 163. The extractor is driven forward by an extractor spring 164 which is guided into a recess 165 in the breech and acts via a piston 166. The piston 166 rests against a flat, rear surface of the extractor, which is inclined in such a way that the front end of the extractor is driven towards a position somewhat inwards from the groove 162. The extractor 159 has an inwards directed hook 167 at the front end and a small, inwards directed projection 168 at the rear end. A short pin 169 fixed in the housing 101 projects into the slot 162 to prevent movement of the extractor forward past the pin.

A pin 170 can be displaced in the transverse direction in a bore in the breech that opens into the bore 126 and the groove 163. When the firing pin takes a forward position in relation to the breech, the inner end of the pin 170 lies against the flank of the firing pin, so that it the outer end of the pin 170 is driven so that it protrudes into the groove 164. When the firing pin takes a rearward position in relation to the breech, the recess 171 in the flank of the firing pin is opposite the pin 170, so that it can be withdrawn from the groove 163.

The firearm is loaded by inserting a cartridge with a flange, of the type shown in fig. 8 and 9, through the opening 112, with the flange guided down through the grooves 113 and the forward end of the cartridge guided behind the projecting portion 115. This presses the magazine platform 111 down and compresses the spring 109, and when the flange 75 is pressed against the branches 121 the charging catch 118 is pressed down about its hinge. When the flange passes the surfaces 114, the cartridge is given a forward movement so that the flange is passed under the surfaces, and the front end of the cartridge is passed under the projecting portion 115. This disconnects the branches 121 from the ounce side of the flange 75, so that the weight arm springs up behind the rear surface 75 on the cartridge to prevent the cartridge from being withdrawn again. The cartridge is thus held locked under the projecting part 115 and the surfaces 114, aligned with the barrel 102. The cartridges can now be fired as described below, or alternatively another cartridge can be introduced in the same way as the first.

It will be seen that when another cartridge is introduced through the opening 112, the flange of this will take a position behind the flange of the first cartridge. For reasons that will become clearer in the following, supply of the cartridge from the magazine and backwards to the firing position in the chamber will be prevented if the cartridges are stored in the magazine with the flange of another inserted cartridge behind the flange of the first. Consequently, it is an important function of the loading lock 118 that it ensures that the first inserted cartridge enters the magazine with the flange behind the flange of the other. This is achieved in the following way. The second cartridge is inserted over the first cartridge with the flange in the grooves 113. When the second cartridge is pushed down, the first cartridge is guided downwards and backwards by the inclined surface 116. At this point, the flange on the second cartridge presses the charging catch 118 against the flange on the first cartridge, and thus enabling the second cartridge to pass past the flange of the first cartridge when it is pushed forward and under the surfaces 114. As the second inserted cartridge moves downward and forward, the loading catch 118 swings up behind it, locking the second cartridge forward in the chamber of same way as the first one. The first cartridge now occupies a position in the magazine housing so that the second cartridge lies above the first and holds it down against the spring 109, the flange of the second cartridge being in front of the flange of the first.

The second cartridge can now be fired as described below, or a third cartridge can be inserted in the same way as the second. If a third cartridge is introduced, the final position will be such that the first and second cartridges are in the magazine, pushed upwards by the spring 109, and the third cartridge lies on top of the second and holds it down. The third cartridge will be in the chamber, and its front end is under the projecting portion 115, the flange is under the surfaces 114, and the branches 121 prevent it from escaping rearward. The flange of the third cartridge will be in front of the flange of the second cartridge.

When the trigger 152 is pressed against the pistol grip 104, it swings backwards around the hinge 153. An upper surface of the trigger presses against the second joint arm 149, drives it upwards and thus straightens the joint mechanism comprising the joint arms 147, 149. When the joint mechanism is straightened, the breech block 125 is pushed forwards, but the firing pin 128 is prevented from moving forward by the engagement with the catch 139. When the breech moves forward, the spring 130 is compressed between the pin 132 and the firing pin 128, and the spring 137 is compressed between the pin 132 and the catch block 129 which lies against the pin 140. If a cartridge is in a position aligned with the barrel, forward movement of the breech will also push the cartridge into the sleeve portion 117, and the flange of the cartridge will slide against the surfaces 117, but this will be counteracted by the force of the spring 109. When the cartridge approaches complete insertion into the sleeve portion 117 , the joint arms 147, 149 come to the straightened position and pass this position somewhat, in order to lock the end piece 125 in a front position. At the same time, the upper surface of the first link arm 147 comes into contact with the release bolt 142 and pushes it upwards to release the catch 139 from the recess 141 in the firing pin 128. The firing pin is thus released to shoot forward at high speed under the action of the spring 130, and to hit the percussion cap 77 on the cartridge to fire it. It will be seen that in the position shown, the spring 130 lies against the shoulder 133 (via the washer 131), but the end of the firing pin is held in the breech. The firing pin thus completes its forward movement by its own inertia, and compresses the light return spring 134. The spring 134 then pulls the firing pin back immediately after firing, so that its end lies inside the breech end of the percussion cap 77, where it does not affect the ejection of the empty sleeve. When the trigger is released after firing, the joint mechanism is pulled back from its position past the straightened position, by spring 151, and the breech is pulled back by spring 137 which is compressed between pin 132 and sear block 127.

The extractor claw 159 only works when a cartridge is in the chamber. Otherwise, the front end of the extractor is directed obliquely inwards under the influence of the spring 164 on the rear surface, so that it always clears the pin 169 and simply moves back and forth together with the breech piece 125. When the extractor 159 thus protrudes obliquely inwards, the protrusion 168 can pass the pin 170 even when the pin 170 protrudes completely due to the contact between its end and the flank of the firing pin 128.

When a cartridge is inserted in front of the breech piece 125, however, the flange of this will come into contact with the extractor behind the chin 167 and push the front end outwards and into the groove 162. In this orientation, the protrusion 168 cannot pass the pin 170 when it protrudes completely on due to its inner end contacting the flank of the firing pin, and forward movement of the extractor is restricted due to contact with the pin 169.

When the trigger is operated with a cartridge in position in front of the breech, the extractor 159 moves forward with the breech until the extractor contacts the pin 169. As the breech moves further forward, the extractor is prevented from doing so, and the pin 161 moves along the slot 160 in the extractor , the rear end of the extractor acting against the piston 166 to compress the spring 164. At this stage of firing, the firing pin 128 is held against the housing 101 by the catch 139, and thus cannot move with the breech. Thus, when the pin 170 comes close to the projection 168, the pin 170 can retract into the recess 171 in the firing pin to clear the projection. When the firing pin is released from the chin, the flank of the firing pin again contacts the inner end of the pin 170 to keep it fully locked, but now the pin 170 is in front of the projection 168.

When the breech block and the firing pin are pushed back by the spring 137 when the trigger is released, the extractor is thus held against the breech block by the pin 170 which is in contact in front of the projection 168. As the flange of the cartridge is blocked behind the catch 167, the empty case is pulled back with the breech block until it passes the surfaces 114 and comes in line with the slits 113. The charging latch 118 is held down to enable this extraction, as explained below.

When the flange passes the surfaces 114, the empty sleeve i is not affected

direction against the force of the spring 109, and the empty case is thus automatically ejected through the opening 112. It will be understood that if the charging catch was not held down during this extraction, the upper and lower cartridge are held in contact with each other by the spring

109. Because it is held down, however, the charging detent 118 holds the lower cartridge down, so that the flange of the upper cartridge can

is shifted backwards and upwards over the upper surfaces of the branches 121, thus clearing the lower flange. The charging lock thus has a very important function. Without this, the empty case would be prevented from being fully retracted due to its flange coming into contact with the flange of the lower cartridge, and thus could not be ejected.

Once the empty case is ejected, the forward end of the extractor is freed to move inwardly under the action of spring 164 and piston 166 on its rear end. The resulting small rotation of the extractor is sufficient to enable the projection 168 to clear the pin 170, so that the extractor immediately moves back (that is, before the next cartridge can be raised into the chamber to prevent forward movement of the extractor ) to the front position in relation to the end piece, as shown in fig. 11.

To enable extraction of the empty case, the charging catch 118 must be held down while the case is moved backwards. This is achieved by means of the pin 155. When the breech moves forward to place the cartridge in the sleeve portion 117, the head 156 of the pin 155 can enter the recess 158 in the firing pin, so that the pin can be withdrawn when the outer end contacts the charging catch 118. When the breech completes its forward movement, the underside of the breech comes into contact with the branches 121, depressing the charging detent 118, but the pin 155 has no effect on this. When, however, the firing pin is freed from the hook 139, the head 156 of the pin is pushed outwards due to the rounded end of the recess 158, so that when the firing pin hits the percussion cap 77, the pin 155 is brought all the way out towards the flank of the firing pin. In this position, but with the breech fully forward, the projecting pin 155 is in contact with a flat upper front surface of the detent 118, to hold the detent pressed down so that the prongs 121 can pass under the flange 75 of the cartridge being withdrawn and hold the flange on the subsequent, new cartridge below. When firing is complete, the breech block and firing pin are pulled back together, with pin 155 still protruding. This movement backwards means that the breech first comes out of contact with the charging catch 118, but the catch cannot be raised again to the position shown in fig. 10 before the breech piece has been pulled back far enough for the pin 155 to enter the curved portion 123, and at this point the blank sleeve has been moved backwards past the branches 121. It will be seen that the described arrangement has the great advantage that it prevents the possibility of that an unfired cartridge is accidentally ejected.

When the empty casing is ejected, the magazine platform, if there are no more cartridges in the magazine, will be raised under the influence of the spring 109 until it is prevented by contact with the projecting part 115. If, however, there is another cartridge, this is driven upwards by the spring 109. When it moves upwards, it is guided forwards by the curved undersides of the branches 121 of the loading stop 118, and with the front ends on the inclined surface 116. The next cartridge thus moves upwards in front of the loading stop 118, so that it is kept blocked by the surfaces 114 and the projecting lot 115. A new firing can then start immediately by using the trigger, or the magazine can alternatively be refilled by introducing one or more cartridges through the opening 112.

Claims (4)

1. A firearm comprising a housing, a chamber and an actuation mechanism, the actuation mechanism comprising a breech block (15; 125) which is longitudinally displaceable according to the housing (3; 101) of the weapon and has a forward end for contacting with and push a cartridge (74) forward in the chamber, a firing pin (20, 128) which can be displaced longitudinally in relation to the housing and the breech, resilient means (22; 130) which can be stressed by forward movement of the breech relative to the firing pin, a hook device (29; 139) which can be connected to the firing pin to prevent longitudinal movement of the firing pin relative to the housing, and a link mechanism comprising a first and second link arm ( 13, 17; 147, 149) and forms at least part of an operative link between a trigger (6; 152) and the end piece, the first joint arm (13; 147) being hinged in a first hinge point (14; 146) with the end piece, and the second joint arm (17; 149) is hinged in another hinge point (12; 148) with the housing, the first hinge point being located in front of the second hinge point, and the first and second joint arms are hinged to each other in a third hinge point (16; 150) and the trigger are operatively connected to the joint mechanism, so that the first movement of the trigger (6, 152) moves the third hinge point into alignment with the first and second hinge points, so that the breech moves forward and the spring funds are claimed, characterized in that with continued movement of the trigger (6; 152), the joint mechanism moves past the straightened position to lock the breech in the forward position and release the catch device (29, 139). 2. Firearm as specified in claim 1, characterized in that the hook device comprises a hook (29; 139) which can be brought into engagement with a recess (33; 141) in the firing pin, and that a mechanical connection (34; 142) is operatively arranged between the joint mechanism and the chin to release the chin from the recess after the joint mechanism has been moved past the fully straightened position. 3. Firearm as stated in claim 2, characterized in that the mechanical connection comprises a trigger bolt (34; 142) for the chin (29; 139), displaceable across the firing pin (20; 128), so that one end of the bolt can contact the chin and the other end of the bolt can contact the joint mechanism, the length of the bolt being such that when the joint mechanism is moved past the straightened position it pushes the bolt against the chin to release the chin from the recess (33; 141) . 4. Firearm as specified in claims 1-3, characterized in that the trigger mechanism is arranged to move the breech piece (20) forward a length which is sufficient to only partially feed a cartridge into the sleeve portion (83) in the barrel (1), as that the cartridge case mainly lacks support during firing.