EP0997700A1 - Non-polluting jacketed bullet and manufacturing method therefor - Google Patents

Abstract

The process involves (i) mixing tungsten powder with a powder-formed grease or ; (ii) pressing the mixture and (iii) inserting the pre-pressed product into the bullet jacket and (vi) pressing to predetermined thickness. In the process for producing a jacketed bullet for a small caliber ammunition, the ammunition has a core comprising a tungsten containing material and a jacket lined with steel or copper.

Description

The present invention relates to a method for the production of a low-emission shell bullet the preamble of the patent claim as well as to an after this Processed bullet.

For centuries, inexpensive lead has been used because of its high density and soft as bullet material or at least used as core material for projectiles. The longtime Use of lead-containing projectiles in practice and Hunting ammunition has led to major toxic problems and especially the surroundings of shooting ranges Heavy metal contaminated. So it was just a matter of Time until the demand for low pollution, in particular lead-free bullets came up. For example, in In some countries, the law already bans grist enacted for hunting across water and marshlands.

From EP -A- 0641836 it is known for the production of Masses of high density, tungsten powder in a plastic matrix store, which in storeys and as fishing weights Find use. In doing so, these are elaborate Manufacturing process at temperatures above 185 ° C all processed into low-emission hunting ammunition.

This method has the disadvantage of being costly thermal process control and is therefore for ordnance ammunition too expensive. Furthermore, the density can be of the projectile only within narrow limits; is also dimensional stability due to temperature fluctuations the high proportion of plastic in the core, insufficient.

It is therefore an object of the invention to provide a method which does not have the disadvantages of the prior art can be implemented with existing operating facilities is, in particular, no thermal processes appropriate facilities required and reflected in the resulting Density can be set easily.

The projectile created according to this procedure should be compared with an existing and so far in large series manufactured bullet (Ordonnance ammunition 5.6 mm GP90) same weight, same outer geometry, an identical indoor and outdoor ballistics and the same Have breakthrough performance. Furthermore, the dimension should of the projectile also in a wide temperature range must be preserved and - of course - must all requirements of the Hague Convention through the substitute product also be fulfilled.

In addition, the projectile should be liquid-tight his; Manufacturing tolerances should be due to the design of the floor can be compensated.

This object is achieved by the features of claim 1 or Claim 2 solved.

The projectile according to the invention can be started by a known gravimetric dosing of the tungsten powder and the lubricant and lubricant in its mass exactly and set reproducibly.

Advantageous further developments are in dependent claims described the subject of the invention.

By a tungsten powder with the specified in claim 3 Grain densities can be achieved, which are a lead core correspond.

Calcium stearate, mixed intimately, has proven particularly useful with tungsten powder, which when pressed at room temperature a one-piece body is created that holds together; the in claim 4 alternatively enumerated substances are also suitable.

The weight percentage specified in claim 5 is optimal, he prevents the pre-compact from breaking apart removal from the press mold and when inserting it into the Bullet jacket.

To enable the pre-compact to be manipulated properly are pressures of a little over 300 MPa advantageous, Claim 6.

The final pressing takes place according to claim 7 with higher Printing, preferably in the range of 400 MPa.

The pressure when pressing the core material must be above 350 MPa, preferably 400 MPa.

The inclusion of a leveling and sealing compound according to claim 9 has the advantage that a liquid-tight rear part arises, and that even small manufacturing tolerances with it are compensable.

Tin, claim 10, has proven itself because it is under pressure flows easily and thus a completely form-fitting Missile body results.

Alternatively, materials according to claim 11 are used, if an absolutely heavy metal-free projectile is required is.

By flanging according to claim 12, the flow of Material optimally used, in which there is a possible Can fill out excess material from the inside.

Figur

ein Kleinkaliber- Mantelgeschoss mit einem schadstoffarmen Kern.

The subject matter of the invention is explained in more detail below with the aid of a drawing. It shows the only one

Figure

a small-caliber shell bullet with a low-pollution core.

In the figure, a floor is denoted by 100, which has a jacket 1 and a flattened tip 2. in the Inside, there is a core 8. The jacket 1 is in his Middle part 3 cylindrical and goes in its rear part 4 sharp-edged into a truncated cone 5. At the upper end of the middle part 3 there is a circumferential gag groove 7, which is used to attach the usual cartridge case.

Following the actual core 8 is a leveling and sealing compound 9 with a material leveling serving concave crowning 6 is provided.

The jacket 1 is in a known manner (according to EP -A- 0106411) made of plated steel. The core 8 consists of a Mixture of tungsten powder and calcium stearate; the balancing and sealing compound 9 made of soft tin.

The projectile 100 is produced in a very simple manner and economical way:

The shell is like the well-known ordnance ammunition usual by deep drawing a bowl from plated Steel creates. After squeezing it onto the provisional one The length of the core 8 is used in the form of a pre-compact and pressed it with 400 MPa. After that the preformed leveling and sealing compound is inserted and shaped and flared the rear part 4. Finally the gag groove 7 is embossed and the projectile is finished calibrated.

An automatic one takes place during the last manufacturing stages Mass balance by adding excess material the crown 6 can come out by a few 1/100 mm, without the center of mass and thus the ballistics negative to influence.

The pre-compact is made by intimately mixing 97% by weight Tungsten powder and 3% by weight calcium stearate and subsequent Molding presses generated at a pressure of 300 MPa. Both components are commercially available, with the tungsten powder one with an average grain size of 5 µm as very useful for setting a lead corresponding Has proven density.

Through the use of notoriously known weighing machines the mass of the core also in large series production reproducible to an accuracy of plus / minus 4/100 g establish.

Alternatively, the mixture of tungsten powder and the powdered Lubricants and lubricants also in the bullet jacket, exactly dosed and pressed there, with pressures of 400 at least in a last pressing MPa can be applied.

The subject of the invention has exactly the same flight dynamic Properties like the previous one to be replaced, leaded ordnance ammunition and causes them, resulting in intensive target practice environmental and Health problems not.

The manufacturing process described can basically with the previous equipment and the same staff take place like conventional bullet production.

Claims (12)

Process for the production of a shell bullet for a small-caliber ammunition with a core of one tungsten-containing material and an adjacent to it Steel or copper alloy sheath, characterized in that in a first process step Tungsten powder with a powder Lubricant and lubricant is mixed that this Mixture is pressed in a second step and the resulting pre-compact in a third Step inserted in the shell and open there the density to be achieved is pressed completely. Process for the production of a shell bullet for a small-caliber ammunition with a core of one tungsten-containing material and an adjacent to it Steel or copper alloy sheath, characterized in that in a first process step Tungsten powder with a powder Lubricant and lubricant is mixed that this Mix in the second step in the shell dosed and at least there a further step on the density to be achieved is finished pressed. A method according to claim 1 or 2, characterized in that that the tungsten powder is a medium grain less than 10 µm, preferably 5 µm. A method according to claim 1 or 2, characterized in that that the lubricant and lubricant calcium stearate or magnesium stearate or aluminum stearate or is sodium stearate or paraffin. A method according to claim 4, characterized in that the weight percentage of the lubricant and lubricant 1 to 10 percent, preferably 3 percent. A method according to claim 1, characterized in that the pre-compact with a pressure of at least 300 MPa is pre-pressed. A method according to claim 6, characterized in that the pre-compact in the projectile jacket with a Prepressed increased pressure compared to the prepress becomes. A method according to claim 2, characterized in that the core with a pressure of at least 350 MPa is finished pressed. Made by the method of claim 1 or 2 Mantle storey with a core of a tungsten-containing Material and one attached to it Sheath, characterized in that the core (8) Tungsten and lubricant and lubricant is shorter than the bullet jacket (1) and that the rear part (4) completed by a leveling and sealing compound (9) is. Mantle bullet according to claim 9, characterized in that the compensating and sealing compound (9) Tin exists. Mantle bullet according to claim 9, characterized in that the compensating and sealing compound (9) Aluminum or an aluminum alloy. Mantle bullet according to one of claims 9 to 11, characterized in that the rear part (4) a Has truncated cone (5) and that by flanging the compensating and sealing compound (9) non-positively is held.

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