CH627549A5 - METHOD FOR PRODUCING AN ARMORING BULLET. - Google Patents

Description

The invention relates to a method for producing an armor-piercing projectile with a projectile body made of a heavy metal sintered alloy.

Armor-piercing projectiles are known, in which the 3fl projectile body is made of hard metal. A suitable hard metal has, for example, 86% tungsten carbide and 14% cobalt and has a hardness of HRA = 95 and a specific weight y = 14.6 g / cm3. If such a bullet body made of hard metal is used in a sabot projectile, good penetration results are achieved with single targets.

Single targets are targets where the projectile only has to penetrate a single, relatively thick armor plate. However, it has been shown that such a carbide projectile body is not suitable for multiple targets. Multiple 4Q targets are targets in which the projectile has to penetrate several relatively thin armor plates arranged one behind the other. Bullet bodies made of heavy metal are suitable for combating such multiple targets.

Armor-piercing projectiles are also known in which the projectile body is made of heavy metal.

A suitable heavy metal sintered alloy has, for example, 93% tungsten and 7% iron-nickel. As said, such a projectile body is suitable for combating multiple targets. However, it has been shown that such a 5 # bullet body made of a heavy metal sintered alloy is not suitable for single targets, since the penetration rate is significantly lower than that of bullet bodies made of hard metal, because the heavy metal sintered alloy has a relatively low strength and is not particularly hard either. When such a projectile hits a single target, a large part of the kinetic energy is lost through deformation work, since the projectile body deforms strongly before it penetrates the armor plate.

The object which is to be achieved with the present invention is to create a projectile body which is suitable both for combating single targets and for combating multiple targets.

The method for producing such a projectile body is characterized in that the heavy metal sintered alloy is solidified by non-cutting shape change. The heavy metal sintered alloy is preferably solidified by reducing the cross section by at least 20%. The heavy metal sintered alloy can have a hardness of HVm

The breaking stress The allowable elongation The specific weight The hardness HV] 0

oB = 90 kp / mm2 Ô5 = 15% Y = 17 g / cm3 = 300 kp / mm2

55

65

This heavy metal sintered alloy is further deformed after pressing and sintering. Bar stock can e.g. are pressed through a nozzle, the cross section of the rod material being reduced. According to FIG. 2, the cross section has been reduced by 25% and according to FIG. 3 by 40%. The hardness has been increased to HVjo = 420 kp / mm2 or HV10 = 500 kp / mm2.

The deformation of the heavy metal sintered alloy for solidification is only to be understood as the deformation after pressing and sintering.

Non-cutting shape change is not only to be understood as the above-mentioned pressing of a rod through a nozzle, but also stretching, upsetting as well as rolling, forging, hammering, etc., thus any deformation that leads to a solidification of the material. This can involve both cold and hot forming, in which the material is plastically deformed.

In certain cases, only part of the projectile body is solidified. The change in shape is also referred to as “deforming” and “reshaping”:

Forming: Change the shape of a workpiece or material by moving the material particles while maintaining their relationship. Manufacturing processes in metal forming include rolling, forging, pressing, drawing, upsetting, embossing and the like. a. Most of the processes can be carried out both above and below the recrystallization temperature ("warm" and "cold"). Hot forming generally enables higher degrees of forming with smaller forces; disadvantageous are the costs for heating, the greater inaccuracy due to shrinkage and the scale formation. Cold forming brings greater accuracy with a larger surface quality, but requires higher forces and only allows smaller degrees of forming. Solidification occurs to an undesirable extent, which must be removed by intermediate annealing ».

Deformation: «Metallurgy: plastic shape change. The deformability in the solid state is based on the fact that crystallites of metals are able to slide and form twins according to certain laws and thus by rolling, forging, pressing, drawing and the like. a. can be deformed. At

hot deformation, new crystals form in the deformed structure, recrystallization. This enables casting blocks with large cross-sections to the finest sheets and wires

3,627,549

be deformed. Cold forming increases strength, yield strength and hardness, while the elongation drops shortly before breaking. »

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1 sheet of drawings

Claims (6)

627 549 PATENT CLAIMS 1. A method for producing an armor-piercing projectile with a projectile body made of a heavy metal sintered alloy, characterized in that the heavy metal 5 sintered alloy is solidified by non-cutting shape change. 2. The method according to claim 1, characterized in that the heavy metal sintered alloy is solidified by a cross-sectional reduction of at least 20%. 10th 3. The method according to claim 2, characterized in that the heavy metal sintered alloy is solidified by deformation to a hardness HVI0 of at least 420 kp / mm2. 4. The method according to claim 3 for the production of a projectile with a projectile body made of a heavy metal sintered alloy based on tungsten, characterized in that that the globulitic tungsten bodies are formed into elongated bodies. 5. The method according to claim 1, characterized in that at least a part of the projectile body is solidified. 2o 6. The method according to claim 1, characterized in that the solidification is carried out cold. of at least 420 kp / mm2. The globulitic tungsten bodies of the heavy metal sintered alloy can be shaped into elongated bodies. It has been shown that the aforementioned heavy metal sintered alloy can be solidified with, for example, 93% tungsten and 7% iron-nickel by non-cutting shape change. The method according to the invention is to be explained in more detail below with reference to the attached figures, for example. It shows: 1 shows a micrograph of sintered tungsten heavy metal at 100 times magnification; 2 shows a micrograph of the same tungsten heavy metal as in FIG. 1 with tungsten grain deformed in the longitudinal direction, and 3 shows a micrograph of the tungsten heavy metal as in FIG. 1 with the tungsten grain deformed more in the longitudinal direction. This tungsten heavy metal has the following properties after pressing and sintering. 35 45 25th