METHOD FOR PRODUCING A HIGHLY HEAT-RESISTANT WEAPON BARREL PROVIDED WITH A TWIST PROFILE

Abstract

In order to provide an economical method for producing a weapon barrel, in which a considerable plasticisation of the barrel inner wall and thus of the twist profile is avoided when armour-piercing ammunition is shot, in particular in the case of an intense firing sequence, it is proposed not to introduce the twist profile of the weapon barrel into a barrel blank, the material of which has its end strength already as a result of hardening and tempering, but has a lower strength level (approximately 800-1000 MPa). Only once the twist profile has been formed by extrusion or hammering is the steel hardened and tempered to a predefined strength value >1000 MPa, and is the barrel blank that is provided with the twist profile mechanically processed further.

Claims

1. A method for producing a highly heat-resistant barrel provided with a twist profile, in particular for small-caliber automatic weapons, the method comprising: introducing the desired twist profile into a barrel blank made of heat-resistant steel, the material of which has a yield point 1000 MPa at room temperature; quenching the barrel blank provided with the twist profile and tempering via vacuum tempering to a predefined strength value with a yield point >1000 MPa; and mechanically finishing the quenched and tempered barrel blank.

2. The method as claimed in claim 1, wherein a grade of steel with a yield point in the pre-tempered state 800 MPa is used to produce the barrel.

3. The method as claimed in claim 1, wherein a grade of steel from the CrMoV group is used for the barrel blank.

4. The method as claimed in claim 3, wherein an alloy with the main alloy elements of 0.25-0.35% C, 3-5% Cr, 1-3% Mo, and small fractions V, is used as the material for the barrel blank.

5. The method as claimed in claim 1, wherein the twist profile is applied to the barrel blank by means of extrusion or hammering.

6. The method as claimed in claim 1, wherein the mechanically finished barrel is provided with erosion protection, in particular hard chromium plating.

Description

SUMMARY OF THE INVENTION

[0005] It is therefore an object of the present invention to specify a cost-effective method of producing a barrel in which substantial plasticization of the inner barrel wall, and therefore of the twisting profile, is avoided when hardcore ammunition is being fired, particularly with an intense firing rhythm.

[0006] The invention is substantially based on the basic idea of raising the hot-yield point from 640 MPa (conventional quenched and tempered steel with the designation 32CrMoV12-10), for example, to over 1000 MPa with an increase in temperature of the barrel to 500 C. and thereby achieving sufficient barrel strength, even at high temperatures. The consequence of this is that the material has a substantially higher yield point than 1000 MPa at room temperature.

[0007] However, materials with a high yield point (>1000 MPa) do not allow the use of a cost-effective method for the application of twist, such as hammering over a mandrel or extrusion.

[0008] Despite this, the invention envisages the use of cost-effective hammering or extrusion. This is possible when the production sequence is reversed. The profiling first takes place at a low strength level. The twist profile of the barrel is not introduced into a barrel blank, the material of which is already at its final strength due to quenching and tempering, but into one that has a lower strength level (approx. 800-1000 MPa). Only after the twist profile has been applied by extrusion or hammering does the quenching and tempering (or final quenching and tempering) of the steel to a predefined strength value >1000 MPa and the further mechanical processing of the barrel blank provided with the twist profile take place.

[0009] Because the twist profile can be influenced by the subsequent quenching and tempering process, changes in the barrel blank initially caused by quenching and tempering must be initially determined and then taken into account during the twist profiling (by means of a preliminary working dimension). As is generally known, the material undergoes volume changes during quenching and tempering which results in smaller caliber diameters after quenching and tempering. In the case of extrusion or hammering, the field/groove diameter selected must be less than 1/100 mm larger, in order to comply with the diameter tolerances. Where necessary, the field diameter can also be slightly mechanically reworked.

[0010] The quenching and tempering of the barrel blank which follows the twist profiling preferably takes place in a vacuum, in order to avoid scaling of the inner surface of the barrel. Insofar as required, the quenched and tempered barrel may be provided with an erosion protection layer in the form of hard chromium plating, for example.

[0011] Further details and advantages of the invention result from the following exemplary embodiment.

[0012] In this exemplary embodiment, in order to produce a barrel for an MG3 machine gun, heat-resistant steel with 0.25-0.35% C, 3-5% Cr, and 1-3% Mo is used. This steel is initially rough-machined into a barrel blank.

[0013] The inner barrel surface is then provided with the desired twist profile (in this case a field/groove profile) by extrusion, taking account of the previously determined rough-machining dimension.

[0014] The barrel blank provided with the twist profile is then quenched and tempered to the desired yield point of >1300 MPa by means of vacuum tempering. This initially involved heating the barrel blank to austenitization temperature with subsequent rapid cooling followed by tempering treatment to operational strength.

[0015] Following the quenching and tempering of the barrel blank, the mechanical finishing process finally takes place. An erosion protection layer, e.g. technical hard chromium plating, can be applied where necessary.

[0016] The invention is not of course limited to the exemplary embodiment described above. Hence, for example, another suitable high-alloy steel can be used. Moreover, the quenching and tempering of the barrel blank can take place in multiple sections, so that twist profiling takes place after a first quenching and tempering (preliminary quenching and tempering) with a yield point 1000 MPa and final tempering to a value >1000 MPa only takes place subsequently.

[0017] The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are to be included within the scope of the following claims.