NO862024L - DEVICE FOR TARGET ARM. - Google Patents

Description

The invention generally relates to improvements to firearms and relates more particularly to a device for a lock case for firearms.

In previously known weapons of this type, the lock box has usually been produced by cutting a blank in the form of a massive piece of material through many operations, which are usually preceded by designing the internal guide for the breech. This work includes several different cutting machining operations, such as drilling, broaching, milling guide grooves for the breech block's guide or breech blocks, etc. and the processing is then completed by shaping the magazine control, ejector opening, connections and fasteners, etc. For functional technical reasons, the breech lugs and the guide grooves for these are usually designed as two diametrically opposed or three dove-tail-shaped or. like organ.

A lock box for firearms of this type is subject to certain disadvantages. The shaping of the lock box by cutting is complicated and expensive, depending on the many necessary work operations. Depending on the cutting process, an uneven surface often results that needs to be polished and which can nevertheless give poor breech movement and the grooves for the breech lugs in the lock box sometimes have sharp edges, which can give a harsh feeling in use. Certain material weakening may occur due to the cutting processing and due to the dovetail shape etc. Eg., the breech lugs can have a certain breaking indication at the inner edge.

The basis for the invention has been the insight that the lock case can be produced by cold hammering, which entails many advantages. Cold hammering refers to the cold working of a workpiece by inserting a mandrel into a tubular workpiece and two or more hammers strike from the outside against the tubular workpiece at height with the mandrel, so that the pipe workpiece is shaped on the inside with the desired profile. The advantages of this are primarily that the shaping of the relatively complicated inside of the lock box is significantly faster than with previously known methods, and that the lock box and the entire weapon are thus cheaper. In addition, one achieves several further significant advantages, including a smoother and smoother surface, the lock box has a better surface inside than it has previously been possible to achieve, namely a smoothness of approx. 0.05 RA. The material gets a denser molecular structure and overall becomes denser and harder and has higher wear resistance. The material gets increased material strength, and thus the outer diameter of the lock box can be reduced and you get a lighter weapon. Cold hammering also achieves approximately the desired outer diameter without additional processing, and significant costs for grinding, polishing and other surface treatment can also be saved. A calculation shows that a significant reduction of the production costs for the lockbox can be achieved.

Cold hammering, however, requires that the inside of the lock case is given a special shape. It is not possible by cold hammering to obtain guide grooves with a dovetail shape or with essentially parallel sides for the locking lugs or the breech lugs, as these should be made pyramid-shaped and between the guide grooves outlets can be conveniently made in certain places for the magazine control, for the trigger and for the ejection opening.

By designing the guide grooves in an appropriate way, it is possible to achieve an advantageous fit of the magazine guide and the ejector opening and at the same time achieve that the lugs of the breech block together have a sufficient locking surface. The conical or pyramid-shaped guide grooves give the locking pawls a safe and yet soft steering and closing action. According to a feature of the invention, the guide tracks in the lock box are designed with a

side slope of between 10 and 19 °, preferably approx. 14-16°.

In certain cases, where the lock case is designed with two preferably diametrically opposite guide grooves, the space for the guide grooves can be found to be somewhat limited with regard to the openings for the magazine guide and the ejector opening, or the total locking surface for the breechblock tabs is too small, for these to be able to withstand the long-term large forces generated by shooting.

In an alternative embodiment of the invention, the lock box is therefore designed with three pyramid-shaped guide tracks, which are preferably distributed at an angle of 120° in relation to each other and where the bottom of the guide tracks lies within a central opening angle of between 55 and 70° with a lateral slip of between 11° - 19°, preferably approx. 14° - 16°.

This brings several additional advantages. The end piece has an opening angle of only approx. 60° towards approx. 85° with two guide grooves, and furthermore the three recoil tabs provide a more even distribution of the recoil forces.

Appropriately, the guide slots are distributed at 0°, 120° and 240° seen in a polar plane, with the magazine guide being placed straight down in the normal way and the cartridge ejection opening at an angle of approx. 60° from the upper edge of the lock box.

Further features and advantages of the invention will be apparent from the following description of a preferred embodiment.

In the drawings, fig. 1 part of a complete weapon seen from the right side. Fig. 2 schematically illustrates the procedure for cold forging the lock case in accordance with the invention. Fig. 3 shows a lock box in accordance with the invention seen from the side and Fig. 4 shows a longitudinal section through a lock box in accordance with the invention, with end piece. Fig. 5 shows a cross-section along the line V-V in fig. 3, and fig. 6 similarly shows a section along the line VI-VI in fig. 3.

Fig. 1 shows an example of the use of the locking box according to the invention in a hunting rifle of the magazine type. It should be added that the invention can be used for many different types of single-shot weapons as well as multi-shot weapons, and that the weapon shown is only an example of one of many different areas of use.

The rifle in the example is designed in the usual way with a lock case 1 which is fixed in a forend 2 and which is connected to a barrel 3 and a trigger generally denoted by reference number 4 and which includes a breech block 5 with a protruding handle 6 and other associated parts.

Lock box 2, which is shown in detail in fig. 2-6, is produced by cold forging a tubular blank. The cold forging takes place in the manner indicated schematically in fig. 2, where a tubular workpiece 7 is clamped between a counter-holder 8 and a driver 9. Inside the workpiece there is a mandrel 10 which is held firmly by a rod 11. The mandrel has the shape that is to be transferred to the inside of the lock box and which in this case is formed by a circular cylinder 12 with, in this particular case, three evenly spaced ribs 13 with a cross-sectional profile converging outwards, designed to form the guide grooves in the finished lock box.

It should be pointed out that the lock case can just as well be designed with two mainly opposing guide tracks and in this case the mandrel is designed accordingly with two ribs. Similarly, the lock box can be designed with more than three guide grooves and the mandrel in a similar way with more than three ribs.

Around the lock box blank, two hammers 14 are arranged in a plane with the mandrel 10. The mandrel with the blank rotates in relation to the hammers 14 at the same time as these knock against the blank so that through material flow it assumes the inner and outer shape that the finished lock box should have. The lock case blank is fed during the mat successively to the left in the direction of arrow 15.

As mentioned above, the cold hammering of the lock box entails several advantages, both in terms of production and wear.

Through the cold hammering, the lock case blank is given the inner shape shown most clearly in fig. 5 and 6 and which form the control for the weapon's breech. The inner shape is formed by a circular cylindrical guide surface 16 and three guide grooves 17 which are spaced at a mutual angle of 120° and which have a cross-section that converges towards the bottom. Each guide track 17 extends radially outwards from the cylindrical guide surface 16, where the guide track 17 with its bottom lies within a central angle at the cylindrical guide surface 16 between approx. 55 and 70°. This angle is partly determined by the requirement that the breech block's guide lugs must have a sufficient contact surface against the lock case, partly also by the requirement that the circular parts between the guide grooves leave sufficient space for magazine guidance and cartridge ejection grooves, and partly by the requirement that the material between the guide grooves must have sufficient thickness and strength to enable the determination of the various parts belonging to the weapon. The height of the steering lab legs can be varied as desired. In a practical embodiment of the invention with a cylinder diameter in the lock box of 18 mm, the guide grooves were given a depth corresponding to a diameter of 24 mm.

The flanks of the guide grooves should have an angle of inclination or "drop angle" between 11 and 19° or preferably 14-16°, which angle is determined with regard to suitable drop in the cold hammering and suitable guidance for the breech lugs. In the usual way, the cylinder part 16 passes into the guide track part over a radius, for example of 1.25m at a cylinder diameter of 18ram and similarly the flanks 18 of the guide tracks pass into the bottom track 19 over radii of e.g. 2.25mm at the same cylinder diameter.

After the cold hammering of the lock case blank, it is further processed in essentially the same way as with corresponding processing of lock cases in accordance with conventional production, by designing the magazine guide 20, cartridge ejector opening 21 and entrance 22 for the breech piece 5, as well as turning and threading the exit end 23 for the barrel or barrel 3.

As mentioned above, the lock box can be designed with two, three or more guide tracks. In the event that it is designed with two guide tracks, these are preferably placed diametrically or less diametrically in relation to each other and at 90 respectively. 270° seen in a polar system, and so that the magazine opening is cut into the material straight down and the ejector opening straight up.

In the event that three guide tracks are arranged, which is shown most clearly in fig. 6, the magazine guide 20 is placed between the 120 and 240° tracks and so that the magazine guide fits up against the outer edges of the track flanks, which face each other, while the ejector opening 21 is placed between the 240 and 0° guides.

By placing the guides so that in the case of two guides they are placed at 90 and 270° and in the case of three guides they are placed at 0, 120 and 240° seen in a polar plane, the lockbox will have ample material at its bottom for fastening of the various parts of the weapon and for mounting the lock box with its mechanics to the weapon stock. Correspondingly as stated above, more than three guide tracks can be arranged in the lock box.

In that the lockbox in a preferred embodiment

provided with three guide grooves, the breech gets an opening angle of only approx. 60°, compared to the previously more common opening angle of approx. 85° and at the same time the breech block has three contact surfaces against the lockbox distributed at 120° angles to each other, which provides a stable connection with evenly distributed recoil forces.

Claims (5)

1. Device for a lock case (1) with a breech piece (5) for firearms, characterized in that the lock case (1) is produced by cold hammering a preferably tubular lock case blank, the blank being shaped with an internally continuous circular cylindrical guide (16) with two or more guide grooves (17) for the lugs (24) of the closing piece (5), as the flanks (18) of the guide grooves (17) have a release angle between 11 and 19°. 2. Device in accordance with claim 1, in particular for a repeater weapon or multi-shot weapon, characterized in that the lock box contains three guide slots (17) arranged with substantially even division for placement of the lock box with the guide slots lying at 0, 120 and 240° seen in a polar degree system, and that a magazine guide (20) is arranged in the lock box between the guide tracks at 120 and 240°, while an ejection opening (21) is arranged between the guide tracks at 240 and 0° or at 0 and 120°. 3. Device in accordance with claim 2, characterized in that the bottom of each guide track lies within an angle from the center of the lock box's circular-cylindrical guide of between 55 and 70°, with the tip at its through axis. 4. Device in accordance with claim 1, characterized in that the lock box is designed with two guide tracks arranged essentially diametrically opposite and mainly at 90 respectively. 270° seen in a polar plane. 5. Device in accordance with one of the claims 1-4, characterized in that the flank in the guide grooves (17) in the locking box and in the lugs (24) of the end pieces has a release angle of approx. 15°.